Saturday, June 2, 2007
Wednesday, May 16, 2007
DEMAND THAT GOVERNMENT GIVE US THE TRUTH ON ASTEROID VULNERABILITY
DEMAND THAT GOVERNMENT GIVE US THE TRUTH ON ASTEROID VULNERABILITY
It is common knowledge that if a meteor were to hit your house (one hit a few blocks down from you 10 years ago) it might kill you or your family. (the Peekskill meteor only damaged a parked car). So in the case of a similarly likely disaster, not only did the meteor miss your house, it also missed the house it hit. That's why the statistical unlikeliness of the event would make complaining about your vulnerability a waste of time and effort. Yes, you are vulnerable. No, it's not going to happen.
However, if you harbored an internal grudge against meteors, you might begin to pepper NASA with urgent letters, requesting, no.... demanding to be told the "True Trajectories" of all likely meteor hits, and the hidden truths about the so-called "Apollo Objects" -a lightly veiled secret that LARGE MOUNTAIN SIZED ASTEROIDS could take out North America at any time (including Peekskill). Why does NASA withold the truth from us, we are all stakeholders here, and the proof it is possible is that the Peekskill meteor hit only a few blocks away, even though it injured nobody!
But why.... why you say.... why does NASA search for Apollo Objects IF THEY'RE NOT DANGEROUS? The very fact that NASA thinks they can hit us, proves they can, and therefore NASA is guilty of gross negligence in NOT PROVIDING EITHER ADEQUATE WARNING, ADEQUATE ESCAPE ROUTES, OR BIG THICK CONCRETE ROOFS FOR ALL OUR HOUSES.
Therefore we must have a petition, to gather signatures of ALL VULNERABLE ASTEROID STAKEHOLDERS, and maybe get together for a little fun and games at the Firehouse Restaurant some Saturday, waddya say?
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Now, just for your edification, I've taken a US Government chart off a public US Government website, a chart that shows just what you demanded to see. It also shows what John Hall, Hillary Clinton et al, have been demanding to know. And it was in the damned public domain all along, right where their staffs could have found it. So is it negligence? Or is it a hole in the head? I think its a hole in the head, and so here,.... let's fill that big gaping open "head-hole" for ya-- what say?
It ain't easy though. You have to figure out how to read it. Bummer.... Kinda tough to do with one of those big morning after headaches, eh? Again, let me help. The bottom left corner has two weird numbers. 10-7 and 10. The up and down axis is years. 10-7 denotes ten billion years. The right-left axis denotes dead people. 10 denotes ten dead folks, and 10-2 denotes 100 stiffs. (It's called powers of ten notation).
Now let's read it. left hand panel, bottom left corner, we see nuclear accidents and meteor strikes--- they are statistically very similar. The meteor line says every 10,000 years, you can expect 10 people dead from meteors. Follow it down, and to the right. Its other end says every ten billion years you can expect ten thousand deaths, from a big meteor strike. Horrible? Fearful? Not really..... but possible.
Go to the nuke plant curve. every twenty thousand years you can expect 10 deaths from a nuclear plant accident. (Since 31 people died at Chernobyl, we are ahead of schedule there, but they were stupid incompetent Russians, the people who do everything wrong). That also means Chernobyl "sucked up" all the likelihood of any more plant deaths, so we have a free-and-clear twenty thousand years ahead of us, skating on Chernobyl's contribution. (No, that's actually a lie, but I just thought I'd see if you were following the reasoning--- how did you do on that?).
At the bottom right end of the nuke plant curve we see every ten billion years, we can statistically expect 8000 people to die in "The Big One". I sure hope I'm not there, and if you think Indian Point is old now.,.......just imagine how old its gonna be in ten billion years. All the workers will be mummies, or something.
So there it is. Was all along. Just hard to read. Are you vulnerable? Hell yeah.
Is it gonna happen? Hell yeah. In ten billion years.
One interesting thing is the line for dam collapses, way up on the page. Being way up the page means its far more likely, and far more deadly than nukes'n'meteors. So I guess everybody better move out of Croton, real quick. Valhalla, forget about it, they're dead Spano-meat down there. Better write out their wills by noon today.
TAGS: iNDIAN pOINT aSTEROID vULNERABILITY DEMAND
Sunday, May 6, 2007
Why 67% Have Voted "Yes" on Indian Point
Why the U.S. Needs More Nuclear Power
Your typical city dweller doesn’t know just how much coal and uranium he burns each year. On Lake Shore Drive in Chicago—where the numbers are fairly representative of urban America as a whole—the answer is (roughly): four tons and a few ounces. In round numbers, tons of coal generate about half of the typical city’s electric power; ounces of uranium, about 17 percent; natural gas and hydro take care of the rest. New York is a bit different: an apartment dweller on the Upper West Side substitutes two tons of oil (or the equivalent in natural gas) for Chicago’s four tons of coal. The oil-tons get burned at plants like the huge oil/gas unit in Astoria, Queens. The uranium ounces get split at Indian Point in Westchester, 35 miles north of the city, as well as at the Ginna, Fitzpatrick, and Nine Mile Point units upstate, and at additional plants in Connecticut, New Jersey, and New Hampshire.
That’s the stunning thing about nuclear power: tiny quantities of raw material can do so much. A bundle of enriched-uranium fuel-rods that could fit into a two-bedroom apartment in Hell’s Kitchen would power the city for a year: furnaces, espresso machines, subways, streetlights, stock tickers, Times Square, everything—even our cars and taxis, if we could conveniently plug them into the grid. True, you don’t want to stack fuel rods in midtown Manhattan; you don’t in fact want to stack them casually on top of one another anywhere. But in suitable reactors, situated, say, 50 miles from the city on a few hundred acres of suitably fortified and well-guarded real estate, two rooms’ worth of fuel could electrify it all.
Think of our solitary New Yorker on the Upper West Side as a 1,400-watt bulb that never sleeps—that’s the national per-capita average demand for electric power from homes, factories, businesses, the lot. Our average citizen burns about twice as bright at 4 PM in August, and a lot dimmer at 4 AM in December; grown-ups burn more than kids, the rich more than the poor; but it all averages out: 14 floor lamps per person, lit round the clock. Convert this same number back into a utility’s supply-side jargon, and a million people need roughly 1.4 “gigs” of power—1.4 gigawatts (GW). Running at peak power, Entergy’s two nuclear units at Indian Point generate just under 2 GW. So just four Indian Points could take care of New York City’s 7-GW round-the-clock average. Six could handle its peak load of about 11.5 GW. And if we had all-electric engines, machines, and heaters out at the receiving end, another ten or so could power all the cars, ovens, furnaces—everything else in the city that oil or gas currently fuels.
For such a nuclear-powered future to arrive, however, we’ll need to get beyond our nuclear-power past. In the now-standard histories, the beginning of the end of nuclear power arrived on March 28, 1979, with the meltdown of the uranium core at Three Mile Island in Pennsylvania. The Chernobyl disaster seven years later drove the final nail into the nuclear coffin. It didn’t matter that the Three Mile Island containment vessel had done its job and prevented any significant release of radioactivity, or that Soviet reactors operated within a system that couldn’t build a safe toaster oven. Uranium was finished.
Three Mile Island came on the heels of the first great energy shock to hit America. On October 19, 1973, King Faisal ordered a 25 percent reduction in Saudi Arabia’s oil shipments to the United States, launching the Arab oil embargo. Oil supplies would tighten and prices would rise from then on, experts predicted. It would take some time, but oil was finished, too.
Five months after Three Mile Island, the nation’s first energy secretary summed up our predicament: “The energy future is bleak,” James R. Schlesinger declared, “and is likely to grow bleaker in the decade ahead. We must rapidly adjust our economics to a condition of chronic stringency in traditional energy supplies.” Fortunately, some argued, the U.S. could manage on less—much less. Smaller, more fuel-efficient cars were gaining favor, and rising gas prices would curb demand. The nation certainly didn’t need any new giant electric power plants—efficiency and the development of renewable sources of power would suffice. “The long-run supply curve for electricity is as flat as the Kansas horizon,” noted one right-thinking energy sage.
In the ensuing decades, however, American oil consumption rose 15 percent and electricity use almost doubled. Many people aren’t happy about it. Protecting our oil-supply lines entangles us with feudal theocracies and the fanatical sects that they spawn. The coal that we burn to generate so much of our electricity pollutes the air and may warm the planet. What to do? All sober and thoughtful energy pundits at the New York Times, Greenpeace, and the Harvard Divinity School agree: the answer to both problems is . . . efficiency and the development of renewable sources of power. Nevertheless, the secretary of energy, his boss (now a Texas oilman, not a Georgia peanut farmer), and the rest of the country should look elsewhere.
The U.S. today consumes about 100 quads—100 quadrillion BTUs—of raw thermal energy per year. We do three basic things with it: generate electricity (about 40 percent of the raw energy consumed), move vehicles (30 percent), and produce heat (30 percent). Oil is the fuel of transportation, of course. We principally use natural gas to supply raw heat, though it’s now making steady inroads into electric power generation. Fueling electric power plants are mainly (in descending order) coal, uranium, natural gas, and rainfall, by way of hydroelectricity.
This sharp segmentation emerged relatively recently, and there’s no reason to think it’s permanent. After all, developing economies use trees and pasture as fuel for heat and transportation, and don’t generate much electricity at all. A century ago, coal was the all-purpose fuel of industrial economies: coal furnaces provided heat, and coal-fired steam engines powered trains, factories, and the early electric power plants. From the 1930s until well into the 1970s, oil fueled not just cars but many electric power plants, too. And by 2020, electricity almost certainly will have become the new cross-cutting “fuel” in both stationary and mobile applications.
That shift is already under way. About 60 percent of the fuel we use today isn’t oil but coal, uranium, natural gas, and gravity—all making electricity. Electricity has met almost all of the growth in U.S. energy demand since the 1980s. About 60 percent of our GDP now comes from industries and services that use electricity as their front-end “fuel”—in 1950, the figure was only 20 percent. The fastest growth sectors of the economy—information technology and telecom, notably—depend entirely on electricity for fuel, almost none of it oil-generated. Electrically powered information technology accounts for some 60 percent of new capital spending.
Electricity is taking over ever more of the thermal sector, too. A microwave oven displaces much of what a gas stove once did in a kitchen. So, too, lasers, magnetic fields, microwaves, and other forms of high-intensity photon power provide more precise, calibrated heating than do conventional ovens in manufacturing and the industrial processing of materials. These electric cookers (broadly defined) are now replacing conventional furnaces, ovens, dryers, and welders to heat air, water, foods, and chemicals, to cure paints and glues, to forge steel, and to weld ships. Over the next two decades, such trends will move another 15 percent or so of our energy economy from conventional thermal to electrically powered processes. And that will shift about 15 percent of our oil-and-gas demand to whatever primary fuels we’ll then be using to generate electricity.
Electricity is also taking over the power train in transportation—not the engine itself, but the system that drives power throughout the car. Running in confined tunnels as they do, subways had to be all-electric from the get-go. More recently, diesel-electric locomotives and many of the monster trucks used in mining have made the transition to electric drive trains. Though the oil-fired combustion engine is still there, it’s now just an onboard electric generator that propels only electrons.
Most significantly, the next couple of decades will see us convert to the hybrid gasoline-and-electric car. A steadily rising fraction of the power produced under the hood of a car already is used to generate electricity: electrical modules are replacing components that belts, gears, pulleys, and shafts once drove. Steering, suspension, brakes, fans, pumps, and valves will eventually go electric; in the end, electricity will drive the wheels, too. Gas prices and environmental mandates have little to do with this changeover. The electric drive train simply delivers better performance, lower cost, and less weight.
The policy implications are enormous. Outfitted with a fully electric power train, most of the car—everything but its prime mover—looks like a giant electrical appliance. This appliance won’t run any great distance on batteries alone, given today’s battery technology. But a substantial battery pack on board will provide surges of power when needed. And that makes possible at least some “refueling” of the car from the electricity grid. As cars get more electric, an infrastructure of battery-recharging stations will grow apace, probably in driveways and parking lots, where most cars spend most of their time.
Once you’ve got the wheels themselves running on electricity, the basic economics strongly favor getting that electricity from the grid if you can. Burning $2-a-gallon gasoline, the power generated by current hybrid-car engines costs about 35 cents per kilowatt-hour. Many utilities, though, sell off-peak power for much less: 2 to 4 cents per kilowatt-hour. The nationwide residential price is still only 8.5 cents or so. (Peak rates in Manhattan are higher because of the city’s heavy dependence on oil and gas, but not enough to change the basic arithmetic.) Grid kilowatts are cheaper because cheaper fuels generate them and because utility power plants run a lot more efficiently than car engines.
The gas tank and combustion engine won’t disappear anytime soon, but in the imminent future, grid power will (in effect) begin to top off the tank in between the short trips that account for most driving. All-electric vehicles flopped in the 1990s because batteries can’t store sufficient power for long weekend trips. But plug-in hybrids do have a gasoline tank for the long trips. And the vast majority of the most fuel-hungry trips are under six miles—within the range of the 2 to 5 kWh capacity of the onboard nickel-metal-hydride batteries in hybrids already on the road, and easily within the range of emerging automotive-class lithium batteries. Nationally, some 10 percent of hybrid cars could end up running almost entirely on the grid, as they travel less than six miles per day. Stick an extra 90 pounds—$800 worth—of nickel-metal-hydride batteries in a hybrid, recharge in garages and parking lots, and you can shift roughly 25 percent of a typical driver’s fuel-hungriest miles to the grid. Urban drivers could go long stretches without going near a gas station. The technology for replacing (roughly) one pint of gasoline with one pound of coal or under one ounce of uranium to feed one kilowatt-hour of power to the wheels is now close at hand.
So today we use 40 percent of our fuel to power the plug, and the plug powers 60 percent of GDP. And with the ascent of microwaves, lasers, hybrid wheels, and such, we’re moving to 60 and 80 percent, respectively, soon. And then, in due course, 100/100. We’re turning to electricity as fuel because it can do more, faster, in much less space—indeed, it’s by far the fastest and purest form of power yet tamed for ubiquitous use. Small wonder that demand for it keeps growing.
We’ve been meeting half of that new demand by burning an extra 400 million tons of coal a year, with coal continuing to supply half of our wired power. Natural gas, the fossil fuel grudgingly favored by most environmentalists, has helped meet the new demand, too: it’s back at 16 percent of electricity generated, where it was two decades ago, after dropping sharply for a time. Astonishingly, over this same period, uranium’s share of U.S. electricity has also risen—from 11 percent to its current 20 percent. Part of the explanation is more nuclear power plants. Even though Three Mile Island put an end to the commissioning of new facilities, some already under construction at the time later opened, with the plant count peaking at 112 in 1990. Three Mile Island also impelled plant operators to develop systematic procedures for sharing information and expertise, and plants that used to run seven months per year now run almost eleven. Uranium has thus displaced about eight percentage points of oil, and five points of hydroelectric, in the expanding electricity market.
Renewable fuels, by contrast, made no visible dent in energy supplies, despite the hopes of Greens and the benefits of government-funded research, subsidies, and tax breaks. About a half billion kWh of electricity came from solar power in 2002—roughly 0.013 percent of the U.S. total. Wind power contributed another 0.27 percent. Fossil and nuclear fuels still completely dominate the U.S. energy supply, as in all industrialized economies.
The other great hope of environmentalists, efficiency, did improve over the last couple of decades—very considerably, in fact. Air conditioners, car engines, industrial machines, lightbulbs, refrigerator motors—without exception, all do much more, with much less, than they used to. Yet in aggregate, they burn more fuel, too. Boosting efficiency actually raises consumption, as counterintuitive as that sounds. The more efficient a car, the cheaper the miles; the more efficient a refrigerator, the cheaper the ice; and at the end of the day, we use more efficient technology so much more that total energy consumption goes up, not down.
We’re burning our 40 quads of raw fuel to generate about 3.5 trillion kilowatt-hours of electricity per year; if the automotive plug-and-play future does unfold on schedule, we’ll need as much as 7 trillion kWh per year by 2025. How should we generate the extra trillions of kilowatt-hours?
With hydrogen, the most optimistic Green visionaries reply—produced by solar cells or windmills. But it’s not possible to take such proposals seriously. New York City consumes so much energy that you’d need, at a minimum, to cover two cities with solar cells to power a single city (see “How Cities Green the Planet,” Winter 2000). No conceivable mix of solar and wind could come close to supplying the trillions of additional kilowatt-hours of power we’ll soon need.
Nuclear power could do it—easily. In all key technical respects, it is the antithesis of solar power. A quad’s worth of solar-powered wood is a huge forest—beautiful to behold, but bulky and heavy. Pound for pound, coal stores about twice as much heat. Oil beats coal by about twice as much again. And an ounce of enriched-uranium fuel equals about 4 tons of coal, or 15 barrels of oil. That’s why minuscule quantities contained in relatively tiny reactors can power a metropolis.
What’s more, North America has vast deposits of uranium ore, and scooping it up is no real challenge. Enrichment accounts for about half of the fuel’s cost, and enrichment technologies keep improving. Proponents of solar and wind power maintain—correctly—that the underlying technologies for these energy sources keep getting cheaper, but so do those that squeeze power out of conventional fuels. The lasers coming out of the same semiconductor fabs that build solar cells could enrich uranium a thousand times more efficiently than the gaseous-diffusion processes currently used.
And we also know this: left to its own devices, the market has not pursued thin, low-energy-density fuels, however cheap, but has instead paid steep premiums for fuels that pack more energy into less weight and space, and for power plants that pump greater power out of smaller engines, furnaces, generators, reactors, and turbines. Until the 1970s, engineering and economic imperatives had been pushing the fuel mix inexorably up the power-density curve, from wood to coal to oil to uranium. And the same held true on the demand side, with consumers steadily shifting toward fuels carrying more power, delivered faster, in less space.
Then King Faisal and Three Mile Island shattered our confidence and convinced regulators, secretaries of energy, and even a president that just about everything that the economists and engineers thought they knew about energy was wrong. So wrong that we had to reverse completely the extraordinarily successful power policies of the past.
New York has certainly felt the effects of that reversal. In 1965, the Long Island Lighting Company (LILCO) announced plans to build a $75 million nuclear plant in Suffolk County, to come on line by 1973; soon after, it purchased a 455-acre site between Shoreham and Wading River. A bit later, LILCO decided to increase Shoreham’s size and said it wanted to build several other nuclear plants in the area. Public resistance and federal regulators delayed Shoreham’s completion. Then Three Mile Island happened. In the aftermath, regulators required plant operators to devise evacuation plans in coordination with state and local governments. In early 1983, newly elected governor Mario Cuomo and the Suffolk County legislature both declared that no evacuation plan would ever be feasible and safe. That was that. By the time the state fully decommissioned Shoreham in 1994, its price tag had reached $6 billion—and the plant had never started full-power commercial operation. To pay for it all, Long Island electric rates skyrocketed.
What scared many New Yorkers—and thus many politicians—away from nuclear power was what had originally attracted the engineers and the utility economists to it: nuclear facilities use a unique fuel, burned, in its fashion, in relatively tiny reactors, to generate gargantuan amounts of power. Do it all just right, end to end, and you get cheap, abundant power, and King Faisal can’t do a thing about it. But the raw material itself, packing so much power into so little material, is inherently dangerous. Sufficiently bad engineering can result in a Three Mile Island or a Chernobyl. And these days, there’s the fear that poor security might enable terrorists to pull off something even worse.
How worried should we really be in 2005 that accidents or attacks might release and disperse a nuclear power plant’s radioactive fuel? Not very. Our civilian nuclear industry has dramatically improved its procedures and safety-related hardware since 1979. Several thousand reactor-years of statistics since Three Mile Island clearly show that these power plants are extraordinarily reliable in normal operation.
And uranium’s combination of power and super-density makes the fuel less of a terror risk, not more, at least from an engineering standpoint. It’s easy to “overbuild” the protective walls and containment systems of nuclear facilities, since—like the pyramids—the payload they’re built to shield is so small. Protecting skyscrapers is hard; no builder can afford to erect a hundred times more wall than usable space. Guaranteeing the integrity of a jumbo jet’s fuel tanks is impossible; the tanks have to fly. Shielding a nuclear plant’s tiny payload is easy—just erect more steel, pour more concrete, and build tougher perimeters.
In fact, it’s a safety challenge that we have already met. Today’s plants split atoms behind super-thick layers of steel and concrete; future plants would boast thicker protection still. All the numbers, and the strong consensus in the technical community, reinforce the projections made two decades ago: it is extremely unlikely that there will ever be a serious release of nuclear materials from a U.S. reactor.
What about the economic cost of nuclear power? Wind and sun are free, of course. But if the cost of fuel were all that mattered, the day of too-cheap-to-meter nuclear power would now be here—nearer, certainly, than too-cheap-to-meter solar power. Raw fuel accounts for over half the delivered cost of electricity generated in gas-fired turbines, about one-third of coal-fired power, and just a tenth of nuclear electricity. Factor in the cost of capital equipment, and the cheapest electrons come from uranium and coal, not sun and wind. What we pay for at our electric meter is increasingly like what we pay for at fancy restaurants: not the raw calories, but the fine linen, the service, and the chef’s ineffable artistry. In our overall energy accounts, the sophisticated power-conversion hardware matters more every year, and the cost of raw fuel matters less.
This in itself is great news for America. We’re good at large-scale hardware; we build it ourselves and keep building it cheaper. The average price of U.S. electricity fell throughout the twentieth century, and it has kept falling since, except in egregiously mismanaged markets such as California’s.
The cheap, plentiful power does terrific things for labor productivity and overall employment. As Lewis E. Lehrman notes, rising employment strongly correlates with rising supplies of low-cost energy. It takes energy to get the increasingly mobile worker to the increasingly distant workplace, and energy to process materials and power the increasingly advanced machines that shape and assemble those materials.
Most of the world, Europe aside, now recognizes this point. Workers in Asia and India are swiftly gaining access to the powered machines that steadily boosted the productivity of the American factory worker throughout the twentieth century. And the electricity driving those machines comes from power plants designed—and often built—by U.S. vendors. The power is a lot less expensive than ours, though, since it is generated the old-fashioned forget-the-environment way. There is little bother about protecting the river or scrubbing the smoke. China’s answer to the 2-gigawatt Hoover Dam on the Colorado River is the Three Gorges project, an 18-gigawatt dam on the Yangtze River. Combine cheaper supplies of energy with ready access to heavy industrial machines, and it’s hard to see how foreign laborers cannot close the productivity gap that has historically enabled American workers to remain competitive at considerably higher wages. Unless, that is, the United States keeps on pushing the productivity of its own workforce out ahead of its competitors. That—inevitably—means expanding our power supply and keeping it affordable, and deploying even more advanced technologies of powered production. Nuclear power would help keep the twenty-first-century U.S. economy globally competitive.
Greens don’t want to hear it, but nuclear power makes the most environmental sense, too. Nuclear wastes pose no serious engineering problems. Uranium is such an energy-rich fuel that the actual volume of waste is tiny compared with that of other fuels, and is easily converted from its already-stable ceramic form as a fuel into an even more stable glass-like compound, and just as easily deposited in deep geological formations, themselves stable for tens of millions of years. And what has Green antinuclear activism achieved since the seventies? Not the reduction in demand for energy that it had hoped for but a massive increase in the use of coal, which burns less clean than uranium.
Many Greens think that they have a good grip on the likely trajectory of the planet’s climate over the next 100 years. If we keep burning fossil fuels at current rates, their climate models tell them, we’ll face a meltdown on a much larger scale than Chernobyl’s, beginning with the polar ice caps. Saving an extra 400 million tons of coal here and there—roughly the amount of carbon that the United States would have to stop burning to comply with the Kyoto Protocol today—would make quite a difference, we’re told.
But serious Greens must face reality. Short of some convulsion that drastically shrinks the economy, demand for electricity will go on rising. Total U.S. electricity consumption will increase another 20 to 30 percent, at least, over the next ten years. Neither Democrats nor Republicans, moreover, will let the grid go cold—not even if that means burning yet another 400 million more tons of coal. Not even if that means melting the ice caps and putting much of Bangladesh under water. No governor or president wants to be the next Gray Davis, recalled from office when the lights go out.
The power has to come from somewhere. Sun and wind will never come close to supplying it. Earnest though they are, the people who argue otherwise are the folks who brought us 400 million extra tons of coal a year. The one practical technology that could decisively shift U.S. carbon emissions in the near term would displace coal with uranium, since uranium burns emission-free. It’s time even for Greens to embrace the atom.
It must surely be clear by now, too, that the political costs of depending so heavily on oil from the Middle East are just too great. We need to find a way to stop funneling $25 billion a year (or so) of our energy dollars into churning cauldrons of hate and violence. By sharply curtailing our dependence on Middle Eastern oil, we would greatly expand the range of feasible political and military options in dealing with the countries that breed the terrorists.
The best thing we can do to decrease the Middle East’s hold on us is to turn off the spigot ourselves. For economic, ecological, and geopolitical reasons, U.S. policymakers ought to promote electrification on the demand side, and nuclear fuel on the supply side, wherever they reasonably can.
Tags Indian Point, American Survival, Global Warming, High Tech Energy
Friday, April 27, 2007
Use ISA Scientifically.. not Politically
The difference between the general public repeatedly being shown acceptable safety conditions by an alarmist press wrongly deeming them possible emergencies, and a truly degraded or dangerous nuclear plant , ...has not been made sufficiently clear.
Even an absolute collapse of local political confidence in NRC and its day-to-day oversight cannot be solved by re-inspecting all 104 nuclear plants whenever a local political figure gains traction for the idea in his/her constituency. Such a development can only result in the squandering of resources, funding, and effort into situations not warranting such activity. Taken to its extrapolated worst case, this strategy would flood all 104 nuclear plants with hordes of intrusive inspectors, impeding plant operations, and possibly inducing the very events they came to inspect against.
One of the first principles espoused in the international IAEA document 75-INSAG-3, "Basic Safety Principles for Nuclear Plants", in its preamble by nobel laureate Mohammed El Baradei, is that effort must be targeted to need. "It is important to avoid concentrating resources on efforts that have only marginal effects"..
With local governmental figures voicing ephemeral concerns brought to their attention from activist, intervenor, and opposer groups, outside of any indication that acceptable safety has truly been compromised, we see a clear need for a high level separation of fact and claim, perhaps by a national or international committee, establishing guidelines, and trip-points for the beneficial use of independent safety assessments, and likewise setting precise indicators barring the frivolous use of ISA as a political panacea.
The basic safety case for each of the 104 American nuclear plants has been set out in their Preliminary Safety Analysis Report and their Final Safety Analysis Report. Deterministic comparison of each plant's adherence to its written safety case is provided in real-time by the presence of resident NRC inspectors, and the NRC Reactor Oversight Program.
Probabilistic analysis of the major US plant types can be done by qualified researchers at any time, setting out the risks versus the probabilities in general, allowing guidelines to stand as required reading for those who would inspect, and re-inspect, frivolously, without knowing anything at all about the limits of mere inspection.
(Inspection as a tactic cannot predict an unforseen event. The very evening an ISA is completed at plant "X", a meteor could strike the containment dome, and breach the reactor core--- the inspection would have been a total waste of time).
Politicians ignorant of Probabilistic Risk Analyses seek an absolute "How Safe Is It?" answer , one that eternal inspection, by its very nature, cannot supply. PRA can provide that overview. Therefore politicians should direct the Congressional Research Service to commission a national PRA report on the 104 reactors, as their own internal legislative guide on how to avoid useless calls for repeat ISA's. In point of fact, politicians have been slyly misguided by intervenor and opposer public relations operatives posing as "technical experts", and given the Maine Yankee ISA & shutdown as the one and only way to find out if your local nuke is dangerous. Actually, the MY ISA found the plant was acceptable for further operation. It was a bereft conglomerate corporate culture that had no further interest in its nuclear asset, and bailed out. So even in the case of Maine Yankee, the public was never told how safe the plant was, or was not.
In the face of this impossibility to get blood from a stone, vis-a-vis the ISA tactic, politicians must be educated where to look for this information. I would challenge Senator Clinton and Congressman Hall to write up legislation empowering NRC or CRS to do a "PRA Constitutional Report" on each of the American reactors, with appropriate funding and a clear legislative charter., and to report the results in a high level national safety assessment.
After this report had scientifically charted the relative safety of all 104, then , and only then, would ISA become a useful tool, targeted at whatever specific need had been scientifically unearthed in the PRA Constitutional. This also has the benefit of closely following the IAEA methodology set out in 75-INSAG-3, the high-level agenda-free international document most trustworthy as an authority in these matters.
Without such a framework, any call for an ISA, without clearly demonstrated need, can rightly be called frivolous misuse of legislative priviledge. Within such a framework, established need can form the basis of any future calls fo an ISA.
Reference Documents may be found at:
http://www-pub.iaea.org/MTCD/publications/PDF/P082_scr.pdf , links to the current international standard for safety at nuclear plants. "75-INSAG-3"
http://www-pub.iaea.org/MTCD/publications/PDF/Pub991e_web.pdf, is the IAEA publication setting the international standard for judging safety in nuclear plants built to earlier standards.
The document is named "INSAG-8"
Thursday, April 26, 2007
ARE YOU KIDDING, FITZ??
Yellow Journalism on the Hudson (?)
In an amazingling brassy and overt display of journalistic delinquency, Gannett Journal News reporter Jorge FitzGibbon manages to read a clearly worded Manhattanville poll, where 47 percent of local residents say they want Indian Point open, having judged it as posing little or no risk, versus 33 percent wanting it closed, and somehow produce the blatantly deceptive banner headline:
"POLL: PUBLIC WORRIED ABOUT INDIAN POINT"
Are you kidding Mr. Fitzgibbon? I have a copy of the Gannett Code of Journalistic Ethics here on my desk, and I can see at a glance , that you have skewed the facts.
Digging deeper than the headline, we see FitzGibbon intentionally blurring the two opposing sides, coming up with an untrue, unscientific description barely mentioning the pro-nuclear landslide, and claiming deceptively "residents still have worries" Oh yeah, Jorge? Maybe the 33 % on the anti side worry, but the wording of the survey question specifically asks if respondents have concerns, and the 47% majority specifically state that do not have any concerns.
What malicious alchemical formula can you use to turn gold back into non-factual lead, as you have done in taking the facts ....47% for, only 33% against, and coming up with this huge blunder of journalistic arrogance:
"Poll: Public worried" ?
Imagine a 47 to 33 landslide in any election. Let's say--- John Kerry 47%, GW Bush 33% in 2004, for instance (or the reverse). Piles of books would be written about the greatest landslide in modern electoral history. Robert F Kennedy would be out of a job---you can't electronically hack a fake 14% discrepancy in Ohio or anywhere else--- the gap is just too large.
And.... add to that 14% gap, the fact that it occurs after seven long years of feverish organizing, letter writing, blogging, and furious emailing, by mock-local groups covertly paid to spread fear by the G.R.A.C.E. foundation, Tamarind foundation, and the antinuke Helene Heilbrunn Lerner foundation, as well as Riverkeeper, Wespac, Ipsec and their duped contributors --- all for naught. Or rather .....all for a very clear minus 14.
Shame, Fitzgibbon.... Shame on you. And shame on Gannett for abetting such malicious unethical "journalism."
Actually journalism is the wrong word. Faux journalism maybe. Agendist Propaganda is coming closer. Maybe it would be more accurate to simply say:
Yellow Journalism.
I expect Mr. FitzGibbon to launch into a huffy retort tomorrow, perhaps telling us how corrupt the good nuns over at Manhattanville have become, shilling for Entergy , and publishing false survey reports. It's no more than I would expect from a Goebbels-on-the-Hudson.
Yes, I kind of like that .....
Goebbels-on-the-Hudson....
has a Gannett-type ring to it!
Kind of FitzGibbon-esqe !!
Monday, April 23, 2007
If not done this way, ISA is blatant harrassment
The difference between the general public repeatedly being shown acceptable safety conditions by an alarmist press wrongly deeming them possible emergencies, and a truly degraded or dangerous nuclear plant , ...has not been made sufficiently clear.
Even an absolute collapse of local political confidence in NRC and its day-to-day oversight cannot be solved by re-inspecting all 104 nuclear plants whenever a local political figure gains traction for the idea in his/her constituency. Such a development can only result in the squandering of resources, funding, and effort into situations not warranting such activity. Taken to its extrapolated worst case, this strategy would flood all 104 nuclear plants with hordes of intrusive inspectors, impeding plant operations, and possibly inducing the very events they came to inspect against.
One of the first principles espoused in the international IAEA document 75-INSAG-3, "Basic Safety Principles for Nuclear Plants", in its preamble by nobel laureate Mohammed El Baradei, is that effort must be targeted to need. "It is important to avoid concentrating resources on efforts that have only marginal effects"..
With local governmental figures voicing ephemeral concerns brought to their attention from activist, intervenor, and opposer groups, outside of any indication that acceptable safety has truly been compromised, we see a clear need for a high level separation of fact and claim, perhaps by a national or international committee, establishing guidelines, and trip-points for the beneficial use of independent safety assessments, and likewise setting precise indicators barring the frivolous use of ISA as a political panacea.
The basic safety case for each of the 104 American nuclear plants has been set out in their Preliminary Safety Analysis Report and their Final Safety Analysis Report. Deterministic comparison of each plant's adherence to its written safety case is provided in real-time by the presence of resident NRC inspectors, and the NRC Reactor Oversight Program.
Probabilistic analysis of the major US plant types can be done by qualified researchers at any time, setting out the risks versus the probabilities in general, allowing guidelines to stand as required reading for those who would inspect, and re-inspect, frivolously, without knowing anything at all about the limits of mere inspection.
(Inspection as a tactic cannot predict an unforseen event. The very evening an ISA is completed at plant "X", a meteor could strike the containment dome, and breach the reactor core--- the inspection would have been a total waste of time).
Politicians ignorant of Probabilistic Risk Analyses seek an absolute "How Safe Is It?" answer , one that eternal inspection, by its very nature, cannot supply. PRA can provide that overview. Therefore politicians should direct the Congressional Research Service to commission a national PRA report on the 104 reactors, as their own internal legislative guide on how to avoid useless calls for repeat ISA's. In point of fact, politicians have been slyly misguided by intervenor and opposer public relations operatives posing as "technical experts", and given the Maine Yankee ISA & shutdown as the one and only way to find out if your local nuke is dangerous. Actually, the MY ISA found the plant was acceptable for further operation. It was a bereft conglomerate corporate culture that had no further interest in its nuclear asset, and bailed out. So even in the case of Maine Yankee, the public was never told how safe the plant was, or was not.
In the face of this impossibility to get blood from a stone, vis-a-vis the ISA tactic, politicians must be educated where to look for this information. I would challenge Senator Clinton and Congressman Hall to write up legislation empowering NRC or CRS to do a "PRA Constitutional Report" on each of the American reactors, with appropriate funding and a clear legislative charter., and to report the results in a high level national safety assessment.
After this report had scientifically charted the relative safety of all 104, then , and only then, would ISA become a useful tool, targeted at whatever specific need had been scientifically unearthed in the PRA Constitutional. This also has the benefit of closely following the IAEA methodology set out in 75-INSAG-3, the high-level agenda-free international document most trustworthy as an authority in these matters.
Without such a framework, any call for an ISA, without clearly demonstrated need, can rightly be called frivolous misuse of legislative priviledge. Within such a framework, established need can form the basis of any future calls for an ISA.
Reference Documents may be found at:
http://www-pub.iaea.org/MTCD/publications/PDF/P082_scr.pdf , links to the current international standard for safety at nuclear plants. "75-INSAG-3"
http://www-pub.iaea.org/MTCD/publications/PDF/Pub991e_web.pdf, is the IAEA publication setting the international standard for judging safety in nuclear plants built to earlier standards.
The document is named "INSAG-8"
Tuesday, April 17, 2007
GOING BACKWARDS IS NOT THE ANSWER
BULIMIA IS NOT THE ANSWER
A note to the backward-looking, anal-obsessive Dr.Helen Caldicott
What we perceive as life, is a thermodynamic process. It has a front end, a reactive gut, and a back end. At the front end it seeks or takes in local energy, in its gut it "uses" the energy, and at the back it releases processed, depleted material. In short it eats, it respirates, and it defecates. Because this is the innate nature of all life, there cannot be any life which leaves no waste. In terms of individual creatures, or individual species, waste can be either innocuous, distasteful, or eventually poisonous, when enough has accumulated. However in planetary terms, there is no place for the concept of waste.The accretion of various processed and/or depleted materials by one species, simply sets the stage for Darwin's evolutionary laws to result in another more parsimonious species that lives on the richly deposited life-resources, once viewed as useless, by the older, obsolete life form making them.
The methane-breathing hordes of the pre-Cambrian left their oxygen "waste" for today's species to savor as the essence of life itself. The guano-producing creatures who gave us our phosphate deposits provided rich fertilizer for our farms. The numberless shelled creatures of long ago have given us our limestone continents, and even more numerous bacteria, our fossil fuels. Coral reefs are an ongoing depositing, visible to our eyes, but typical of the wider pattern of life itself.
In planetary terms, therefore, there can never be an ideal steady state. The planet's essence is not static. Change is paramount. Whatever exists now, is a moment's flicker in an eons-old fire, a fire that consumes the planet eternally, or until the sun burns out and goes cold. A species, like coral, that inhabits, uses, and forever changes the place it inhabits, is not committing a "sin of pollution".The birds or bats who "foul" their islands or their caves with guano are not guilty of malicious "bad housekeeping". Bird species, and bat species need not apologize to Gaia for their guano. In fact it is their gift to Gaia, to make of it a new beginning, which Gaia always has done. By giving back their gift of evolved, changed Gaian essence, these creatures have both embodied Gaia, and done her good work for her. In fact it is their planetary duty to process what they find, and leave it changed. If it were not Gaia's wish that these species exist, they would not have arisen. The evolutionary path trod by their ancestor and precursor species led to their existence, by the self same process they engage in now, it has never changed, and if we think it has been "good" in the past, we are forced to accept the long vision that it is also "good" now, as it happens before our eyes.
So then why do many among us view the "man-guano" we produce as evil? Why, uniquely among all creatures that ever existed, or ever could exist, why must homo sapiens sapiens leave exactly zero evidence of ever having lived as a Gaian creation, breathing in, but not breathing out, eating but never defecating, living, but never leaving any gift behind for future species? As a nest-builder, mankind leaves his version of a coral reef in his infrastructure, his cities, his dams, his huge garbage middens, sources of great archaeological richness. Is the coral itself now to dismantle each reef, at the end of each creature's tiny life, to leave the ocean "just as they found it"? ( What might be an efficient policy for a public hiking trail can be a monstrous crime, when applied to humanity as a whole).
It is a delusion. It is a futile wish, a desire for false one-ended perfection, an effort to assuage a self-invented guilt by penitent abstention, self-denial, species-denial, history-denial, and finally life-denial. It is born in an ignorance of just what living species are, and thus what they are constrained to do. It is an imaginary delusion that mankind is a god, and therefore not subject to the eternal scientific, thermodynamic , and Gaian rules that determine planetary evolution. At its lowest and most embarrassing level, it is a simple wish to not have any anus. Were mankind changeable into the "perfected" creature many greenists propose as our ethical next step, it would be a creature that would simply never leave any waste. We would breathe in oxygen, but never breathe out CO2.... We might eat food (Vegan, as they would advise us).... but we would use it entirely, and thus never emit any urine, feces, buildings, or other lasting evidence of having processed the Gaian surround. It's a crock.
In a sustainability framework, this new anus-free human race would be ideal. Free of the guilt of "fouling" our planet, we could simply grow less in numbers on a continual basis, until we were rightly seen once again as food for other species, who would then eat us, and deposit us as THEIR waste, in the end.
So-- sustainability,... far from being a high moral concept, a way to successfully find our "true station" on the planet, is none of these things, but in fact is an ill-conceived self-mutilation. Stasis is not only an impossibility in a living thermodynamic surround, to seek it eventually stunts the expansive impulse describing the host creature as vital, current, and processing on behalf of the planet, and twists current existence into a refusal to process on behalf of Gaia, a delinquent posture of false altruism, never giving back, and thus interrupting evolution itself, in a megalomanic desire to preserve humankind's flickering instant as an eternal "susainable" set- piece, and the races to come after be damned.....
Sustainability is therefore a monstrous hubris, born of self-deification, and over-mentalization. In point of fact there is a single sustainable condition, well known to all. That condition is death. By pathological mentalization, some young women imagine their bodies to need constant reduction, and so they abstain from food, or purge when they do eat, in an effort to achieve an unreachable, delusive "perfect" state, a state that in the end, untreated, will very certainly turn out to be their own death. In exactly analogous fashion, "Sustainability" is preached as an end to the very techniques that have led to mankind's current flourishing condition, a state of great health and vitality the world over, overrunning new habitats at every turn , an obviously successful adaptive episode, processing the planet's heritage fully and joyously, urging us instead to take up new, less fruitful, less expansive, less responsive, more isolating strategies---- for what purpose? That the planet may be denied our existence as who we truly are, as who the planet itself has evolved us to be, and be given a wan, mentalized, mutilated, bulimic ideal in its stead?
It stems from the bipolar nature of human thinking. In ancient languages, the words for up, & down, or for hot & cold are the same word. Only their use denotes which of the paired concepts is meant each time it is spoken. Thus we dream in opposites, always opposing. Since we seem successful, and happiness is reachable now for billions, unhappiness must also exist, in exactly equal measure. Maybe it does, or maybe it does not. Reality is not the issue. Perception of "balance" in the human mind is the great quest, and in this mentalization, greenists seek what is unfindable. They seek balance in an unbalanced , dynamic, evolving reality, and it is not to be found. In fact, the only true "balanced" condition vis-a-vis life, is the absence of life, either non-existence, or death. That a mentalization seeks balance and finds death, is a great human conundrum, dealt with in differing ways by Buddha, Christ, and the pagans. Buddha urges each to seek his own mental death, Christ invites us to worship his proxy death, and the pagans simply kill each other for the honor and the blood thrill.
Thus sustainability, as a philosophy, mines the same human quirk as Buddhism, much in vogue in the West, and infects media with invitations to mass bulimic purgings on all sides. The West, rejecting its worn-out Christianity, heartily embraces its new crypto-buddhist task, and purges en-masse, still forced to attain great individual freedom & wealth, but guilt-ridden about it unless it is bought off by some visible self-mutilation, be it a piercing, declasse clothes, or the refusal to eat meat. These mutilations must occur under the gaze of the less fortunate, to have best emotional effect. As an internal reactive mentalization, it can be viewed as a superstition, or a comforting delusion. Since it works against the very success tactics used by 99% of the human race, it is false, and if pursued relentlessly, it is evil. Muslims correctly regard it as an end-stage pathology, a sin, and thus a need for conversion to Islam.
Thus those who tell us coal use emits CO2, and nuclear power results in spent fuel are spouting a banality, as if it were big news, simply for the way it makes them feel. Forgetting to look forward, where our destiny lies, they turn back, to decry our own back-end, our waste-depositing apparatus, and, focused tightly on the anus-of-mankind to the exclusion of all else, they catalog the droppings, with great and obsessive fascination, urging the entire species to fear their own leavings, never realizing that the race, and the planet, are done with it, and need to move on, despite it.
This article proposes no new strategy to move forward, except that full acceptance of all aspects of human endeavor will be required, barring nothing, in order to fully process our Gaian surround,
and that looking back has been taught to us from ancient times as a mistake, one that turned Lot's wife to a pillar of salt.
tags: Indian Point, nuclear, helen caldicott, bulimia is not the answer
Monday, April 9, 2007
INDIAN POINT TRANSFORMER FIRE
Note: The picture above is NOT the Indian Point transformer fire.
It is another of the thousands of such fires that happen each year.
I have a point of comparison to apply, to judge the significance of any incident at Indian Point, even ones that have not happened yet. You see, I had 20 years' experience working in a conventional fossil power plant, planning the repair work it needed on a daily basis. When I went to work there, I thought mechanical things were all like automobiles. An automobile is designed to work perfectly, without any care at all, for 3 years or 35,000 miles, and then basically get thrown into the crushing machine, to come out as next year's model.
in this 3-year perfection honeymoon, the automobile is unique, totally unlike every large mechanical thing on the planet. It has been streamlined into a commodity. You just sign on the line, and never change the oil, and 3 years later you lease another one. This is not typical. Most stuff needs a lot more attention than a car requires.
In large installations, like factories, or fossil power plants, about 150-250 items are broken, failed, worn out or needing attention every day. A townhouse complex I lived in years ago was much the same. The maintenance crew there was about 15 men, augmented by contract gardeners. The complex would not have hired 15 people on a full time basis, if there was nothing for them to do. That simple enclave of a dozen brick buildings had maybe 50 to 100 unfixed problems being worked on at any time.
Now just imagine yourself being in the real estate market for a townhouse, and being handed a sheaf of papers as you approach the place, listing stuck toilets, failed radiators, uncollected garbage, windows that failed to open, cable TV hookups that didn't work, seamy stories of the personal problems of some of the maintenance mechanics, contagious sicknesses in certain children living there, and a hysterical pre-cooked agenda, telling you to never rent there, because of the great danger, and urging you to call your congressman, to have the place torn down.
Would you become afraid of the Townhouses? Would you join up, get agitated, and march around the place holding placards? (admittedly,.... some poor souls would...... its just that most people would not). In point of fact, I thought the maintenance there was lousy, and I moved out. However, the place is still there, and the townhouses are selling for about $450,000 dollars, so the broken toilets didn't seem to affect the realities of the marketplace.
In that fossil power plant where I planned and staged the repair work for 50 mechanics and 30 technicians, we had about 1500 outstanding unfixed problems at any time, and incidents happened constantly. Once a mugger, pursued by the police, ran in the front gate, climbed a transformer tower, and got fried to a crisp by the 345KV electricity. That kept us down for about 8 hours. Once a 48 inch high pressure steam line ruptured, and two workers and a fire lieutenant were scalded to death before it was brought under control. That caused a 2 month outage. Once a supervisor led his men to the wrong compartment, and set them to work dismantling the wrong 13KV breaker. They were both incinerated, the lucky man dying in 2 days, the unlucky one taking 3 weeks to die. The entire plant staff of 400 people was bussed to both the funerals. It sucked. Once a worker was careless and cut the wrong cable with a power saw. He lost his sight. He was 45 years old , and lives today as a blind man. A worker made a slip up while pouring powdered caustic into a vat, and got covered with harsh caustic solution, removing the skin from 80% of his body. He lives on disability now, and looks quite a bit less attractive than he did before the incident. Once the entire office complex burned completely overnight, causing 2 million dollars' damage, and resulting in the place being run from rented construction trailers for a year.
There was never a week's period, where something did not break, or fail, or explode, or hurt someone. The rythm of steady disaster was constant. It was a high risk, high energy business, and nobody was dismayed by it. Those working on oil rigs will tell you the same. That's how it is, for those of us who work reality jobs. There's nothing wrong because of it. Its regrettable, should be avoided if possible, but its also perfectly normal, expected, even, in its own way.This kind of real-world enterprise cannot be run without it.
But kindly note, dear reader, that none of you ever heard anything about it. Not a single word. You see, people are generally oblivious to the agonies of those who serve them. Who cares if the chef scalds his finger? Just serve my steak, and be quick about it. I only heard about it, because I had to write the work orders to fix the stuff. My predecessor had quit, because he couldn't keep up the pace. I was young, wanted to show the world, so I dug in for all it was worth, and fixed disaster, after disaster, after disaster, after disaster, for 20 years. Therefore, when I see all the alarmist ranting about Indian Point, I have a point of comparison.
The number of incidents at Indian Point is orders of magnitude less than at the fossil power plant where I worked. The number of failures, is likewise way, way lower than at a typical factory or plant of any kind. The safety regimes preventing the life threatening stuff (for the workers) are so much better at Indian Point, that nothing like that happens there, most of the time. The inherent overdesign built into the plant is so robust, that no danger ever exists for people outside the fence ...AND... a specific watchdog agency is built in to the woodwork in the nuclear industry (NRC) , to make sure this is true, on a 24 hour, seven day, 52 week basis, forever, by law.
So, if a transformer burns , its not a point of worry to me, because Entergy is so good, none of our toasters or TV sets even stopped working because of it.(In case you hadn't noticed). Entergy didn't even need the fire department. Looking at pictures of Entergy's fire brigade, I thought it WAS the fire department. But it wasn't. It was just Entergy's capable, professional well trained, well equipped employees, as good as any fire department, stopping a nasty fire in minutes.
Oh, and yes, as the newspapers have relished in saying "There was no release of radiation" . They love saying that, overtly acting as if trying to calm you, while at the same time covertly trying to worry you. Journalistic duplicity, I'd call it. Reporters love the wild, the garish, the worrisome, and want to jiggle your emotions if they can. They get promotions when they succeed at this. For those not wishing to be manipulated in this way, its best to shrug it off. It's THEIR thing, not ours.
So then why am I hearing all these things about Indian Point? Simple. Indian Point is famous. They would like you to believe its notorious, but its not. AND something next is gonna break there soon, we can count on it. But we shouldn't worry about it.
That's life.
Sunday, April 1, 2007
THE LIVING EARTH IS NUCLEAR
Is Indian Point simply a local use of the most natural of all nature's gifts?
Is the core of the earth simply another Indian point, 5000 miles below our feet?
If we worship the earth as "Gaia", is the living heart of Gaia a natural uranium reactor?
http://www.etherzone.com/2002/jud071202.shtml
GOD IS A NUCLEAR REACTOR ENVIRONMENTALIST EARTH WORSHIPERS
By: William Jud
Brad Lemley writes, on pages 35 - 42 in the August 2002 issue of Discover Magazine, about geophysicists' discovery that the exact center of the earth is a ball of molten uranium five miles in diameter which is a natural nuclear fission reactor.
A natural nuclear reactor at the earth's core provides energy that drives volcanic activity and continental drift, and generates earth's magnetic field which deflects charged particles from the sun which otherwise would long ago have stripped off earth's atmosphere and killed all life on earth. Natural fluctuations in reactor output due to build-up and dissipation of reactor waste explain observed variations in polarity and intensity of earth's magnetic field, Herndon theorizes.
Evidence so far is supportive, the writer observes. Earth produces about four terawatts of energy, which computer models calculate is what a natural reactor of white-hot uranium five miles in diameter at the earth's exact core center should produce. Other planets such as Jupiter, Saturn and Neptune are known to radiate about twice as much energy into space as they receive from the sun, so perhaps a planetary uranium core reactor is the norm rather than the exception. Heat from earth's core reactor would power volcanic eruptions, and studies of volcanoes in Hawaii find the Helium 3 isotope mixed with the common Helium 4 isotope in gas and volcanic basalt rock coming from Hawaiian volcanic eruptions. Helium 3 is a fission byproduct produced in uranium-powered nuclear reactors.
Minerals exploration geologists know that uranium deposits are found in areas of recent volcanic activity such as New Mexico, often associated with volcanic ash in sedimentary rocks. But volcanic ash, although in many places deficient in uranium due to leaching which could be a mechanism of transporting uranium out of the volcanic ash and into uranium mineral deposits, probably is insufficient to be the entire source of uranium for large uranium deposits. So another factor must have operated, such as uranium introduced into sedimentary host rocks by steam and hot water from volcanic eruptions and associated hot springs. It has not been proven that volcanic activity creates uranium deposits, but spatial correlation has long been observed. Herndon's theory suggests that uranium deposits in sedimentary rock may originate partly as uranium leakage from earth's core reactor, brought to the surface in erupting magma.
Herndon's discovery ought to interest environmentalist Earth Worshipers who proclaim that Gaia, Mother Earth, is God, and that Gaia is the source of life and well-being for humans and all other life on Earth.
Environmentalists oppose nuclear reactors used to generate power for ships and electricity for domestic use. Environmentalists complain that nuclear power reactors are evil and dangerous and must not be allowed anywhere. If Herndon is right, and Gaia, Mother Earth, lives on energy produced by a giant nuclear reactor at the very heart and core of her being, then Gaia must have a heart and core of Uranium. Gaia and all Earth's creatures may owe their existence to a uranium-fired nuclear reactor at earth's core.
If geophysicist Herndon's findings are correct, Gaia's environmentalist true believers worship a nuclear reactor.
http://www.rense.com/general25/vore.htm
Giant Nuclear Reactor Runs
Earth's Magnetic Field
By Phil Berardelli
UPI Deputy Science and Technology Editor
6-11-2
Thousands of miles beneath our feet, a giant nuclear reactor seems to be at work deep within Earth's core, and preliminary research suggests it may be the mysterious power source behind the planet's magnetic field and thermal energy, upon which all life on the planet depends for its survival, scientists told United Press International.
New data analyzed by J. Marvin Herndon, geoscientist and president of Transdyne Corporation, of San Diego, Calif., and Daniel F. Hollenback, a nuclear engineer and criticality expert at Oak Ridge National Laboratory, in Oak Ridge, Tenn., show the reactor -- a ball of uranium about five miles in diameter and located at the center of the core -- may have been operating nearly since the formation of the planet.
Herndon told UPI he has been searching for evidence of the deep-Earth reactor for more than a decade. In 1992, he published a series of papers on planet-sized nuclear reactors based on the discovery, 20 years earlier, of the remnants of a large, natural reactor located at the Oklo uranium mine in the Republic of Gabon in western Africa.
French scientists had discovered the Oklo reactor and determined it had operated for tens of thousands of years some two billion years ago, Herndon said, "but at the time of its discovery there were too many pieces missing to know what that really meant."
Nuclear reactors operating inside planetary cores might explain some mysteries that have puzzled scientists for years, Herndon said. For example, since the 1960s, astronomers have known Jupiter radiates nearly twice the energy it receives from the Sun. But up to now, they have not been able to explain the phenomenon in a way that makes sense, he said.
Earth's magnetic field is an even bigger mystery. Some mechanism obviously generates the field, and many scientists think the field is formed from fluid iron in Earth's main outer core acting like a giant electric dynamo, or motor. The geomagnetic field, as it is called, shuts down periodically and sometimes reverses its polarity -- with the North and South poles exchanging their magnetic charges.
The energy sources previously thought to power the dynamo are unable to decrease and then increase again, Herndon explained, so scientists have had to resort to assuming the dynamo mechanism is inherently unstable. But a nuclear reactor can decrease power output -- and even shut itself down -- and come back to life again, increasing to its full operating power, he said.
Current knowledge of the structure of Earth's interior is derived mainly from seismic data and chemical analyses of common meteorites, Herndon continued. Based on that data, scientists estimate about 30 percent of Earth's mass comprises an outer core, he said, which is thought to consist of iron and maybe one or more lighter elements such as sulfur.
The solid inner core is much smaller -- less than 2 percent of Earth's mass.
Still, current popular geophysical models cannot explain, from an energy standpoint, a planet-sized magnetic field that operates like Earth's -- with its varying power levels and periodic shutdowns, Herndon said.
Herndon said he received a major insight when he studied a different type of meteorite. Enstatite chondrite meteorites, as they are called, have chemical compositions similar to Earth's interior. Unlike more common meteorites, enstatite chondrite meteorites contain most of their uranium in the part of the meteorite that corresponds to Earth's core.
It was one of the clues Herndon needed, he said. Uranium is the heaviest natural element. It makes sense that, over time, solid uranium particles would rain out from Earth's fluid core at high temperatures. Because of their high density, they could collect at the very center of the Earth. After enough uranium collected together, a nuclear reaction would begin, and that appears to be what happened very soon after the formation of the planet.
In 1997, Herndon teamed up with Hollenbach at Oak Ridge. The laboratory has unique computer programs that can analyze the performance of different types of nuclear reactors.
"Dan showed me those numerical simulation programs could be applied to a nuclear reactor at the center of the Earth," Herndon said. "We used data about the uranium content from the meteorite discoveries to generate simulations at varying power levels."
A highly persuasive clue arrived in the form of physical evidence of a nuclear reactor at Earth's core. Recently analyzed samples of lava rock from deep-source volcanic "hot spots" in Hawaii and Iceland contained tiny amounts of the isotopes helium-3 and helium-4.
Although scientists have known about the helium-3 for some time, they have thought it was left over from Earth's formation some four-and-a-half billion years ago. But no known physical process could produce helium-3 except for nuclear fission, Herndon said, and the proportion of the two helium isotopes matches the prediction of the Oak Ridge simulation. This is strong evidence that the geo-reactor is at work, he said.
Based on the simulations, and the helium evidence, Herndon and Hollenbach theorize a five-mile-wide ball of uranium has been operating as a nuclear reactor for about 4.5 billion years. Its output is an awesome 4 million megawatts. Much of the energy it produces is heat, and that might be what powers the mechanism that produces the geomagnetic field, Herndon said.
Perhaps more interesting, the Oak Ridge programs suggest the reactor is a breeder -- that is, it actually produces more nuclear fuel than it consumes, which is why it has been able to operate over a time frame that spans nearly the entire existence of the planet. In addition, the reactor's power level varies in intensity over time and it shuts down periodically.
A nuclear reactor continuously produces lighter elements, such as strontium or barium, as the uranium fuel fissions -- or splits apart. Those fission fragments would begin to absorb neutrons -- the subatomic particles naturally emitted by the fissioning uranium and responsible for the chain reaction -- thereby preventing them from splitting other atoms.
"One might imagine instances in which the rate of production of fission products exceeds their rate of removal by gravitationally driven diffusion," Herndon wrote in a recent paper on the subject. If so, he explained, "the power output of the geo-reactor would decrease and the reactor might eventually shut down, thereby diminishing and ultimately shutting down the Earth's magnetic field."
Over time, as the lighter elements moved away from the uranium core, the reactor would restart.
The research is "certainly going to be a major contribution to geophysics," Hatten S. Yoder, Jr., director emeritus of the Geophysical Laboratory of the Carnegie Institution of Washington, D.C., told UPI. "They have developed an explanation for (Earth's) magnetic field and the fact that you can turn it on and off."
One of the most remarkable aspects of the planetary core reactor, Yoder said, is "it only takes a (five-mile) ball of uranium. That's only 65 percent of all the uranium on Earth."
The reactor's existence, if proven, solves the problem of delayed geothermal cooling and explains the observed heat flow, Yoder said. Without a continuing power source, he said, the heat dissipation would have ended long ago. But "if you have a ball of uranium at the center, it would continue to put out heat."
Herndon said he next plans to search lava samples for traces of radioactive elements that might have been produced by the geo-reactor and be light enough to have escaped the core and reach Earth's surface. Lithium, beryllium, boron and neon are possibilities, he said.
"It's not an easy task because both rock data and nuclear data are needed, but it certainly is important," Herndon said.
Yoder agreed. "High-temperature and high-pressure experiments are needed to test the composition and melting characteristics of the core," he said.
Copyright 2002 by United Press International.
http://www.technologyreview.com/offthewire/3001_662002_6.asp
Note - South African author-researcher Jan Lamprecht proposed the same concept several years ago during an interview with Jeff. You can read more about his revolutionary theories at www.HollowPlanets.com.
Note from Jan regarding the above story:
Jeff -
Dr Herndon and I communicated a lot, and he's a great guy. That man can turn physics on its head (ditto for the other nuclear scientists who agree with him). All this nonsense about "convection currents in the core" - phooey.... Planets run on nuclear reactors... which is the first of several revelations to come...
Regards, Jan
http://www.ebtx.com/theory/core.htm
Rotational Velocity
of the earth's core
Recently, news from sci-sites reported that the core of the earth is rotating faster than the crust by about a degree per year. In 1400 years or so it will have "lapped" the surface. The scientific cause of this phenomenon has possibly to do with the earth's magnetic field waxing and waning (or so they say). I think it is more likely due to simple thermal expansion and contraction and corresponding angular momentum conservation.
The Nuclear Furnace
There is some excitement that the core's center is occupied by a 5 kilometer diameter uranium furnace which augments the heat generated by the contraction of the earth and all the comets and asteroids that have delivered energy to it in the past. Because the rocky crust is a reasonable insulator we are still alive, i.e. no heat = no swirling molten iron = no magnetic field = no protection from solar radiation = hasta la vista ocean and atmosphere and ola! Mars clone.
My guess is that this is so. Heat is then continuously transmitted through the radius of the earth to vent into space via vulcanism. The entire train of vulcanism must run like this then.
• Core is heated by uranium.
• Heat is transferred through the core to the mantle mainly by rising convective cells (which also cause the magnetic fields)
• The heat is taken up by secondary convective cells at the core-mantle boundary
• These cells rise to the surface exactly like a lava lamp
• They break through the surface as volcanos where the heat gets vented
This doesn't seem too radical to me. Some think that the origin of magma is the upper mantle, meaning that this opinion favors "contact" heat transfer through the "plastic" mantle, i.e. convective cells are here impossible because they require a more fluid flow. Hmmmmmm ... I politely disagree but acknowledge fallibility because I can't see down there. But those who think they can, say the core-mantle interface is very "lumpy". I interpret this in the light of the lava lamp model.
Lava Lamp Bubbles as the cause of Plate Techtonics
All the motions of the crust's plates have been mapped and they show a more or less random pattern of movement. Some plates are colliding, others are separating and still others are scraping by one another ... and all combinations of the above. To me, this means that the plates are being pushed obliquely by "something". The heat transfer can't be going smoothly like light radiating from a lamp in all directions. If the lava lamp bubbles came straight up to the crust, they would not be able to push the plates sideways. Hence, the bubbles have non-perpendicular momentum relative to the crust.
There are two methods of acquiring such oblique vectors. These are by Coriolis forces operating on the bubbles as they rise through the mantle and from the moon tugging on the crust ... pulling it westbound. If this is true, there should be significantly less volcanos at the poles than near the equator (though it certainly is not impossible to have a polar volcano ... it's just unlikely that a bubble would rise straight up from the pole ... rather, most bubbles in this area would drift away from the poles as they rose and come out at lower latitudes). A notable problem with this conjecture is that the older Hawaiian Islands are to the west of Hawaii (the big island) ... meaning that Mauna Loa sits on the current "hot spot" which is drifting east under the crust. Well, this is a problem because I would expect the opposite to be the case if the east-west differential between the crust and mantle were caused by an oblique hit from underneath, i.e. the hot spot should be drifting in the other direction.
Angular Momentum Conservation
Observe that nature tends not to do things smoothly but rather chaotically which flattens out to smooth over long time periods. For instance, a flag in a constant breeze develops ripples which are more or less identical from one time period to the other. The air can't pass over the flag without turbulence which turns into a fairly orderly pattern of waves in the flag fabric. The same is undoubtedly true of convection in the core and mantle. We get chaotic bubbles which are orderly over long time periods.
As heat is taken from the core, the core alternately heats and cools in the aforementioned chaotic manner. The core is in a cooling phase right now. Thus, the core has shrunk somewhat because it has cooled. Hence, it speeds up to conserve angular momentum. On the other hand, the mantle is in its heating phase and has expanded. Hence, it slows down a little. The situation should change over time and the core-mantle interface should flip relative directions.
The Effect of the Moon
The moon's gravitational tug on all of this muddies the theoretical waters. How much does it pull on the crust? Is it enough to override the oblique push in the opposite direction in the case of Hawaii? Or does it pull everything uniformly so that we can "x" it out of the problem? I don't know.
washingtonpost.com
Earth's Core Is a Nuclear Fission Reactor.
By Guy Gugliotta Washington Post Staff Writer Monday, March 24, 2003; Page A06
Jules Verne thought you could get to the center of the Earth through the chimney of an extinct Icelandic volcano. At the bottom, he envisioned a vast inland sea -- really inland, as in 4,000 miles down -- and a bunch of dinosaurs.
This, it turned out, was science fiction.
These days we know more, and this week Paramount Pictures will release "The Core," in which a team of intrepid "terranauts" try to reverse the collapse of the Earth's magnetic field by traveling to the metal center of the planet and setting off a nuclear bomb.
This is somewhat closer to reality, since it reflects the prevailing view that the Earth's core is made of partially crystallized iron and nickel, and makes use of the idea that heat from the cooling core contributes to the magnetic field that repels solar radiation and keeps it from frying the Earth to a crisp.
Still, no one knows exactly what's down there and, despite "The Core," there are no terranauts getting ready to find out.
The question is still open, and maverick geophysicists have made a discovery in many ways as radical as Verne's was 150 years ago: The center of the Earth, they have found, is a nuclear fission reactor.
And in the Proceedings of the National Academies of Science earlier this month, it was argued that the mix of helium isotopes rising in lavas to the Earth's surface suggested that the "demise of the georeactor" is approaching. The reaction could cease anytime from 100 years to 1 billion years from now, collapsing the Earth's magnetic field with monumental consequences.
Nevertheless, "I'm not a bit worried," one researcher said in an interview. "I don't know how long it will take when it starts -- maybe hundreds of years. In this paper, we say that we have perhaps the first warning."
The American Academy of Science and Paramount have forged a publicity partnership of sorts. Although the Academy says they have not received any money from the film company, they are unabashedly lauding "The Core" in hopes of raising the "curtain of silence" that has stymied debate on this subject since its discovery 12 years ago.
"I like the way he does his science, but I can't say the same about the people who review his work," said Hatten S. Yoder Jr., former director of the geophysical lab at the Carnegie Institution of Washington and one of the Academy's most influential boosters. "The geophysical community has been doing this for years. We've had a terrible time, and I hope this latest paper will generate some civilized discussion."
It does not appear to have done so. "It's a very controversial topic," said Don L. Anderson, a geophysicist at the California Institute of Technology. "I'm a little more open-minded than many of my colleagues," he added, noting that georeactors explain many anomalies in the Earth's crust and mantle. But it is "ridiculous" to suggest that the Earth's geomagnetic field is threatened, he said.
Most scientists agree that the Earth was formed about 41/2 billion years ago from an amalgam of fiery material that contained all of the elements found in nature. Disagreement begins over what happened next.
The view held by most Earth scientists is that iron and nickel migrated downward, taking with them all the trace elements that readily combine with these metals. The rest of the trace elements, including uranium, combined with oxygen to form oxides that remained in the Earth's mantle and crust.
These scientists use common meteorites as their model, but the Academy used a rare meteorite with a small amount of oxygen as his example, arguing that the uranium would remain metallic and, as the heaviest element in nature, would migrate to the Earth's core, forming a sphere about five miles in diameter -- a natural nuclear fission reactor.
"It's a self-sustaining critical reaction," said nuclear engineer Daniel F. Hollenbach of Oak Ridge National Laboratory, a longtime collaborator until the two parted ways last year. "Depending on how much it fissions, that's the power."
Hollenbach explained that the core would be composed primarily of two uranium isotopes. Atoms of the isotope U235 would split, giving up neutrons, which would be absorbed by the isotope U238, transforming it into an isotope of plutonium -- Pu239. The numbers signify the number of protons and neutrons in the atomic nucleus, known as the atomic weight.
This reaction, the same produced in some nuclear power plants, eventually creates radioactive waste isotopes much lighter than uranium. These migrate upward and outward from the core, "like fizz from a soft drink," Hollenbach said. The heat from the reaction is what drives the Earth's magnetic field.
Hollenbach said it is important to regard the core not as one large, controlled nuclear reaction, but as billions of smaller reactions that "shut down and resume" as waste products are created and expelled. Hollenbach and Herndon theorize that the aggregate fluctuations in the reaction's intensity are what cause the Earth's magnetic field to weaken every 200,000 years and change direction when it starts up again.
Further evidence of the georeactor comes from Hawaii and Iceland, Hollenbach said, where young lava basalts have been recovered that contain the helium isotopes He3 and He4. While He4 is a byproduct of the decay of natural uranium, He3 can only be produced deep within the Earth in a nuclear reaction.
The Academy's latest paper went even further, suggesting that the ratios of He3 to He4 indicated that the georeactor is reaching the end of its life -- albeit in perhaps a billion years. Hollenbach said he agrees with that conclusion.
Anderson noted that French scientists showed in 1972 that a georeactor did exist for millions of years in a uranium deposit in Gabon. Most geophysicists believe that the He3 found in lava is "primordial" -- already there when the Earth congealed.
Also, Anderson noted, scientists have managed to flip the Earth's magnetic field in lab simulations that envision a cooling core. Finally, he said, many experiments use mathematical models based on data gathered from controlled nuclear reactions. "But there's no reason to put the uranium in the core," he said. "It does interesting things even if it's in the crust or upper mantle."
http://www.uic.com.au/nip78.htm
The primary source of energy driving the convection in the mantle is the radioactive decay of uranium, thorium and potassium. In the present Earth, most of the energy generated is from the decay of U-238 (c 10-4 watt/kg). At the time of the Earth's formation, however, decay of both U-235 and K-40 would have been subequal in importance and both would have exceeded the heat production of U-238.
A simple way of viewing the process of plate tectonics - the formation and disposal of oceanic lithosphere - is that this is the mechanism by which the mantle sheds heat. Conversely, 'mantle plumes/hot spots' are the way the core sheds heat. In terms of total heat loss from the Earth at present, plate activity constitutes about 74%, hot spots account for approximately 9% and radiogenic heat lost directly from the continental crust is some 17%. The Earth is well insulated thermally and the heat loss from the surface now can reflect heat generation a considerable time in the past.
Measurements of heat have led to estimates that the Earth is generating between 30 and 44 terawatts of heat, much of it from radioactive decay. Measurements of antineutrinos have provisionally suggested that about 24 TW arises from radioactive decay. Professor Bob White provides the more recent figure of 17 TW from radioactive decay in the mantle. This compares with 42-44 TW heat loss at the Earth's surface from the deep Earth. The balance comes from changes in the core. (There is very much greater heat loss arising from incident solar radiation, which is quite distinct.)
Natural nuclear reactors in the Earth's crust
At Oklo in Gabon, West Africa, about 2 billion years ago, at least 17 natural nuclear reactors commenced operation in a rich deposit of uranium ore. Each operated at about 20 kW thermal. At that time the concentration of U-235 in all natural uranium was 3.7 percent instead of 0.7 percent as at present*.
* U-235 decays much faster than U-238, whose half-life is about the same as the age of this planet.
These natural chain reactions, started spontaneously by the presence of water acting as a moderator, continued for about two million years before finally dying away. During this long reaction period about 5.4 tonnes of fission products as well as 1.5 tonnes of plutonium together with other transuranic elements were generated in the orebody. The initial radioactive products have long since decayed into stable elements but study of the amount and location of these has shown that there was little movement of radioactive wastes during and after the nuclear reactions. Plutonium and the other transuranics remained immobile.
Georeactor effect
A quite different view of the role of uranium in the Earth is the discovery that much of the uranium in the primordial planet sunk to the core and has formed a core there, some 8 km across, which has been fissioning ever since. The depletion of U-235 over geological time has not terminated the reaction because this core is a fast reactor (not requiring any moderator) which breeds plutonium-239 from the U-238.
tags: indian point entergy nuclear green natural
PLANET EARTH, A NATURAL NUCLEAR REACTOR
Here's a few links, attesting to the recent activity in this field.
Enjoy!
http://www.physlink.com/News/121103PotassiumCore.cfm
Radioactive material may be primary heat source in Earth's core
Radioactive potassium, common enough on Earth to make potassium-rich bananas one of the "hottest" foods around, appears also to be a substantial source of heat in the Earth's core, according to recent experiments by University of California, Berkeley, geophysicists.
Radioactive potassium, uranium and thorium are thought to be the three main sources of heat in the Earth's interior, aside from that generated by the formation of the planet. Together, the heat keeps the mantle actively churning and the core generating a protective magnetic field.
But geophysicists have found much less potassium in the Earth's crust and mantle than would be expected based on the composition of rocky meteors that supposedly formed the Earth. If, as some have proposed, the missing potassium resides in the Earth's iron core, how did an element as light as potassium get there, especially since iron and potassium don't mix?
Kanani Lee, who recently earned her Ph.D. from UC Berkeley, and UC Berkeley professor of earth and planetary science Raymond Jeanloz have discovered a possible answer. They've shown that at the high pressures and temperatures in the Earth's interior, potassium can form an alloy with iron never before observed. During the planet's formation, this potassium-iron alloy could have sunk to the core, depleting potassium in the overlying mantle and crust and providing a radioactive potassium heat source in addition to that supplied by uranium and thorium in the core.
Lee created the new alloy by squeezing iron and potassium between the tips of two diamonds to temperatures and pressures characteristic of 600-700 kilometers below the surface - 2,500 degrees Celsius and nearly 4 million pounds per square inch, or a quarter of a million times atmospheric pressure.
"Our new findings indicate that the core may contain as much as 1,200 parts per million potassium -just over one tenth of one percent," Lee said. "This amount may seem small, and is comparable to the concentration of radioactive potassium naturally present in bananas. Combined over the entire mass of the Earth's core, however, it can be enough to provide one-fifth of the heat given off by the Earth."
Lee and Jeanloz will report their findings on Dec. 10, at the American Geophysical Union meeting in San Francisco, and in an article accepted for publication in Geophysical Research Letters.
"With one experiment, Lee and Jeanloz demonstrated that potassium may be an important heat source for the geodynamo, provided a way out of some troublesome aspects of the core's thermal evolution, and further demonstrated that modern computational mineral physics not only complements experimental work, but that it can provide guidance to fruitful experimental explorations," said Mark Bukowinski, professor of earth and planetary science at UC Berkeley, who predicted the unusual alloy in the mid-1970s.
Geophysicist Bruce Buffett of the University of Chicago cautions that more experiments need to be done to show that iron can actually pull potassium away from the silicate rocks that dominate in the Earth's mantle.
"They proved it would be possible to dissolve potassium into liquid iron," Buffet said. "Modelers need heat, so this is one source, because the radiogenic isotope of potassium can produce heat and that can help power convection in the core and drive the magnetic field. They proved it could go in. What's important is how much is pulled out of the silicate. There's still work to be done "
If a significant amount of potassium does reside in the Earth's core, this would clear up a lingering question - why the ratio of potassium to uranium in stony meteorites (chondrites), which presumably coalesced to form the Earth, is eight times greater than the observed ratio in the Earth's crust. Though some geologists have asserted that the missing potassium resides in the core, there was no mechanism by which it could have reached the core. Other elements like oxygen and carbon form compounds or alloys with iron and presumably were dragged down by iron as it sank to the core. But at normal temperature and pressure, potassium does not associate with iron.
Others have argued that the missing potassium boiled away during the early, molten stage of Earth's evolution.
The demonstration by Lee and Jeanloz that potassium can dissolve in iron to form an alloy provides an explanation for the missing potassium.
"Early in Earth's history, the interior temperature and pressure would not have been high enough to make this alloy," Lee said. "But as more and more meteorites piled on, the pressure and temperature would have increased to the point where this alloy could form."
The existence of this high-pressure alloy was predicted by Bukowinski in the mid-1970s. Using quantum mechanical arguments, he suggested that high pressure would squeeze potassium's lone outer electron into a lower shell, making the atom resemble iron and thus more likely to alloy with iron.
More recent quantum mechanical calculations using improved techniques, conducted with Gerd Steinle-Neumann at the Universität Bayreuth's Bayerisches Geoinstitüt, confirmed the new experimental measurements.
"This really replicates and verifies the earlier calculations 26 years ago and provides a physical explanation for our experimental results," Jeanloz said.
The Earth is thought to have formed from the collision of many rocky asteroids, perhaps hundreds of kilometers in diameter, in the early solar system. As the proto-Earth gradually bulked up, continuing asteroid collisions and gravitational collapse kept the planet molten. Heavier elements – in particular iron - would have sunk to the core in 10 to 100 million years' time, carrying with it other elements that bind to iron.
Gradually, however, the Earth would have cooled off and become a dead rocky globe with a cold iron ball at the core if not for the continued release of heat by the decay of radioactive elements like potassium-40, uranium-238 and thorium-232, which have half-lives of 1.25 billion, 4 billion and 14 billion years, respectively. About one in every thousand potassium atoms is radioactive.
The heat generated in the core turns the iron into a convecting dynamo that maintains a magnetic field strong enough to shield the planet from the solar wind. This heat leaks out into the mantle, causing convection in the rock that moves crustal plates and fuels volcanoes.
Balancing the heat generated in the core with the known concentrations of radiogenic isotopes has been difficult, however, and the missing potassium has been a big part of the problem. One researcher proposed earlier this year that sulfur could help potassium associate with iron and provide a means by which potassium could reach the core.
The experiment by Lee and Jeanloz shows that sulfur is not necessary. Lee combined pure iron and pure potassium in a diamond anvil cell and squeezed the small sample to 26 gigapascals of pressure while heating the sample with a laser above 2,500 Kelvin (4,000 degrees Fahrenheit), which is above the melting points of both potassium and iron. She conducted this experiment six times in the high-intensity X-ray beams of two different accelerators - Lawrence Berkeley National Laboratory's Advanced Light Source and the Stanford Synchrotron Radiation Laboratory - to obtain X-ray diffraction images of the samples' internal structure. The images confirmed that potassium and iron had mixed evenly to form an alloy, much as iron and carbon mix to form steel alloy.
In the theoretical magma ocean of a proto-Earth, the pressure at a depth of 400-1,000 kilometers (270-670 miles) would be between 15 and 35 gigapascals and the temperature would be 2,200-3,000 Kelvin, Jeanloz said.
"At these temperatures and pressures, the underlying physics changes and the electron density shifts, making potassium look more like iron," Jeanloz said. "At high pressure, the periodic table looks totally different."
"The work by Lee and Jeanloz provides the first proof that potassium is indeed miscible in iron at high pressures and, perhaps as significantly, it further vindicates the computational physics that underlies the original prediction," Bukowinski said. "If it can be further demonstrated that potassium would enter iron in significant amounts in the presence of silicate minerals, conditions representative of likely core formation processes, then potassium could provide the extra heat needed to explain why the Earth's inner core hasn't frozen to as large a size as the thermal history of the core suggests it should."
Jeanloz is excited by the fact that theoretical calculations are now not only explaining experimental findings at high pressure, but also predicting structures.
"We need theorists to identify interesting problems, not only check our results after the experiment," he said. "That's happening now. In the past half a dozen years, theorists have been making predictions that experimentalists are willing to spend a few years to demonstrate."
The work was funded by the National Science Foundation and the Department of Energy.
http://athene.as.arizona.edu/~lclose/teaching/images/lect8.html
Lecture 8
History of the Earth
Chapter 3
The dynamic Earth (Introduction to Geophysics)
Most geophysical processes stem from the transfer of heat from the Earth's core to its surface.
Why is the Earth's core hot?
1. The radio active decay of Uranium (U), Thorium (Th) and Potassium (K). Each radio active decay (the loss of some neutrons and protons) releases very little energy. However, all the countless events acting together release a large sustained amount of energy overtime. In the core of the Earth this energy is trapped and so the Earth's core is heated up.
2. As the solid inner grows latent heat is released as the molten outer core freezes to solid rock. Eventually the whole Earth will be solid and there will be no magnetic field.
3. Residual formation heat. Some of the kinetic energy (1/2mv2) of the impacting planetesimals would have been converted to heat. This residual formation heat helped melt the core initially.
4. Another early heat source was the heat produced as the heavy elements (like Iron (Fe) and Nickel (Ni)) "falling" into the core. This process also generated heat from friction.
The exchange of heat from the hot core to the cool surface is called convection (heat rises, cold sinks). In this manner the whole Earth has a series of big convective cells in its mantel. The result is a complex series of movements of the crust of the Earth as it "rides" on top of the convective cells below.
Plate Tectonics
In the 1950s and 60s geophysicists started to develop the concept of Plate Tectonics. Plate tectonics is the theory that describes the motion of the continental plates "riding" the tops of these massive convective cells in the Earth (like a conveyor belt).
Here is a movie showing how the plates have moved the continents
Today these plates move by about 10 cm/yr
• when these plates stick, and then suddenly slip, an Earthquake occurs
• when the heavier ocean crust sinks below the lighter (granite) continental crust (at subjection zones) there will be Earthquakes and Volcanos -the ring of fire around the Pacific is built this way. The Continental crust will also be crumpled, and as a result it is typical to see mountain ranges along the edges of these faults (for example the rocky mountains and the Andes).
• Seamount Island Chains -like the Hawaiian Islands- are made when one hot spot in the Earths mantle leads to continuous eruptions in the same spot. But as the crust moves along the ocean floor a chain of new islands appear.Sometimes (but not often) two continental plates collide. In this case neither plate is heavier and so they both "crumple". This is occurring today as the Indian plate collides with the Asian plate. The result of this collision is the Himalayas which are the highest mountains on Earth.Why is a hot core important for life on Earth?
1. the surface temperature is higher
2. active volcanism can out gas the atmosphere and oceans
3. volcanism is required to form land masses above the ocean
4. hot spots in the sea floor can be "safe" habitats for life
5. hot springs and even hot water deep in the Earth can harbor life
6. volcanoes play a role in the Earth's carbon cycle
Basin and Range
Tucson is located in a unique part of the world. The area where we live is called "Basin & Range" geography. This denotes that in Eastern California, Arizona, and New Mexico the terrain is dominated by short (often parallel) mountain ranges with large dry basins between them. This is a highly unusual land form caused by a unique event in the Earth's history.
• About 20 million years ago the continental plate of the Southwest became "attached" somehow to the pacific coast plate which was moving northwest at the time.
• Added to this was intense heat from magma close to the surface.
• The end result was the unique "Basin & Range disturbance" where the coast of California was pulled away from Arizona by some 38% of its original size.
• The hard cold rock on the top splintered into dozens of parallel ranges, while huge basins over 1 km deep were opened up between the rangeThe whole stretching event took a few million years. Then due to erosion the valleys filled in and the ranges wore down --further filling the valleys.
The reason Tucson exists today is because of the "fossil ground water" trapped in the huge 1 km deep valley basin exists below the city.
Radioactivity in Earth's core up for a look
vast uranium field serves as natural reactor
Keay Davidson, Chronicle Science Writer
Monday, November 29, 2004
Researchers are preparing to prove the discoveries of San Diego geologist, J. Marvin Herndon, who has found a huge, natural nuclear reactor or "georeactor" -- a vast deposit of uranium several miles wide -- at Earth's core, thousands of miles beneath our feet. Herndon and many others believe it explains otherwise puzzling phenomena of planetary science, such as fluctuations in the intensity of Earth's magnetic field. "Herndon's idea about (a reactor) located at the center of the Earth, has opened a new era in planetary physics," said four Russian scientists at Moscow's Institute for Nuclear Research and Kurchatov Institute in a Jan. 28 paper published online.
It might sound bizarre, the very idea of a "natural" nuclear reactor -- a geological version of commercial nuclear power plants such as Pacific Gas and Electric Co.'s Diablo Canyon plant near San Luis Obispo. The reactor at the Earth's core is just a much bigger and deeper version of an extinct natural nuclear reactor that scientists discovered in a uranium mine in Gabon, Africa, in 1972.
The Gabon reactor consists of geological deposits of uranium that, being radioactive, naturally emit subatomic particles called neutrons. These neutrons split the nuclei in adjacent uranium atoms, causing them to emit more neutrons and, thus, to split even more uranium atoms -- in effect, it's a slow-speed chain reaction. Research in the 1970s revealed that the Gabon reactor operated intermittently for a few million years about 2 billion years ago.
Scientists have long known the planet's core is divided into a solid and liquid part composed largely of iron, the liquid circulation of which powers Earth's magnetic field. They have not thought of the core as a repository for uranium, because uranium was not understood until 1945. Although the inevitability of uranium in the core was proposed in 1939 by scientist Walter Elsasser, on the basis that it is the heaviest naturally occurring element, so it would migrate to the core via gravity.
Herndon has demonstrated how a uranium georeactor in Earth's core explains reality better than older scientific ideas, by providing more convincing ways to:
-- Explain the ratios of helium isotopes emitted from volcanoes in Iceland and Hawaii. Those ratios are consistent with the ratios of helium isotopes emitted by a nuclear reactor.
-- Explain why planets such as Jupiter emit far more heat than they absorb from the sun. Herndon thinks they, too, have natural nuclear reactors at their cores. (Because heat is continually generated by the decay of radioactive elements in Earth's crust and mantle -- the regions above the core -- scientists are uncertain whether Earth emits more heat than it receives from the sun.)
-- Explain variations in the intensity of Earth's magnetic field, which fluctuates over time. Herndon has shown that in the core, the georeactor drives the motions of the liquid iron that creates the magnetic field. But the georeactor varies in activity levels over time. Those activity variations, he believes, might explain intensity variations in Earth's magnetic field.
Now, Rob de Meijer and associates at the Nuclear Physics Institute in Groningen, the Netherlands, are planning to demonstrate Herndon's proposals. They're drawing blueprints for a large device that could detect ghostly particles called antineutrinos that have escaped from Earth's core. When put into operation, it will capture antineutrinos that would fly through the roughly 4,000 miles of solid rock and emerge at the Earth's surface.
The European scientists have proposed drilling a shaft more than 1,000 feet deep into the island of Curacao in the Caribbean. They hope to lower into the shaft devices called photomultipliers, which could detect particles from the hypothetical deep-Earth georeactor.
The estimated cost: $80 million. In an e-mail to The Chronicle, de Meijer said he is seeking funding from the Dutch government and industrial consortiums. He and his team plan to visit Curacao in January to take the geological samples needed to design the subterranean antineutrino "antenna," as they call it.
Curacao is a good location for the antineutrino detector because "the island's rocks have relatively few natural radionuclides that could mask the (antineutrino) signal from the Earth's core," the journal Physics World noted in September. The detector could be confused by antineutrinos emitted by commercial nuclear reactors, but Curacao is far enough from the southeastern United States that reactors in Florida won't affect it.
"Dr. Herndon is a brilliant and original thinker. I agree with his proposal" said geoscientist David Deming of the University of Oklahoma.
"The problem with most scientists working today is that they have no knowledge of the history of science," Deming adds. "As late as 1955, continental drift was regarded as the equivalent of alien abductions, Bigfoot and the Loch Ness monster. By 1970, continental drift was an accepted part of the new theory of plate tectonics."
Richard Muller, a noted physicist and author at Lawrence Berkeley National Laboratory in Berkeley. Since the 1970s, Muller has done pioneering research in diverse fields, including cosmology and planetary sciences.
"Herndon's discovery is a very positive contribution to deep Earth science. He raises issues that are worth exploring at some length. " Muller adds. "I consider his work to be 'out of the box' thinking, and as such, it is valuable as a step forward in our understanding of reality."
On a side note, in case you're wondering: Unlike the planet-busting reactor of Superman lore, neither the Gabon reactor nor Herndon's hypothetical deep-Earth reactors could explode like atomic bombs. A-bombs require highly concentrated amounts of fissionable materials that are explosively compressed together in a fraction of a second -- far faster than the snail's-pace processes that would be characteristic of the natural reactors.
Herndon received his bachelor's degree in physics at UC San Diego in 1970. He studied nuclear chemistry and meteorites in graduate school at Texas A&M, where he received his doctoral degree for a thesis on meteorites. Operating as an independent scientist, over the years, he has published papers in prestigious journals, including the Proceedings of the National Academy of Sciences and the Proceedings of the Royal Society of London. His main allies are non-Americans, like the de Meijer team. On Dec. 16, Herndon is scheduled to deliver the prestigious annual "Christmas Lecture" at the European Commission's Institute for Transuranium Elements in Karlsruhe, Germany. It is felt that the huge antinuclear bias in American society is preventing other U.S. academics from getting on board, as they might lose tenure positions or funding by bucking the strong academic antinuke culture on this issue. Had his two sons -- now physicians -- planned to become scientists, he says, "I would have steered them away from it because you can't make a living and do legitimate science; you have to 'howl with the wolves' or you don't survive. This is a sad testament to our times. There's something very wrong in American science."
Herndon’s proposal
According to traditional theory, the core of Earth consists of iron. The SanDiego scientist J. Marvin Herndon has argued that a large deposit of uranium also exists in the core, where it powers a natural nuclear reactor or “georeactor.” Herndon believes the nuclear process is responsible for variations in the intensity of Earth’s magnetic field.
During the radioactive decays, the georeactor releases ghostly particles called antineutrinos, which fly through thousands of miles of solid rock to Earth’s surface. Scientists will test Herndon’s georeactor by using special instruments to detect the antineutrinos as they pass through the outer crust.
Sources: nuclearplanet.com; www.ansto.gov.au/edu/about/about_neutron.htm;
Other scientists have expanded Herndon's proposal to include Thorium and Potassium.
nasa
http://sfgate.com/cgi-bin/article.cgi?f=/c/a/2004/11/29/MNGPIA17BL45.DTL
http://www.sciam.com/print_version.cfm?articleID=000B2C71-BCF0-1C71-9EB7809EC588F2D7
Why is the earth's core so hot? And how do scientists measure its temperature?
Jeff Atwell
Mount Vernon, Ohio
Quentin Williams, associate professor of earth sciences at the University of California at Santa Cruz offers this explanation:
There are three main sources of heat in the deep earth: (1) heat from when the planet formed and accreted, which has not yet been lost; (2) frictional heating, caused by denser core material sinking to the center of the planet; and (3) heat from the decay of radioactive elements.
It takes a rather long time for heat to move out of the earth. This occurs through both "convective" transport of heat within the earth's liquid outer core and solid mantle and slower "conductive" transport of heat through nonconvecting boundary layers, such as the earth's plates at the surface. As a result, much of the planet's primordial heat, from when the earth first accreted and developed its core, has been retained.
The amount of heat that can arise through simple accretionary processes, bringing small bodies together to form the proto-earth, is large: on the order of 10,000 kelvins (about 18,000 degrees Farhenheit). The crucial issue is how much of that energy was deposited into the growing earth and how much was reradiated into space. Indeed, the currently accepted idea for how the moon was formed involves the impact or accretion of a Mars-size object with or by the proto-earth. When two objects of this size collide, large amounts of heat are generated, of which quite a lot is retained. This single episode could have largely melted the outermost several thousand kilometers of the planet.
Additionally, descent of the dense iron-rich material that makes up the core of the planet to the center would produce heating on the order of 2,000 kelvins (about 3,000 degrees F). The magnitude of the third main source of heat--radioactive heating--is large, but quantitatively uncertain. The precise abundances of radioactive elements (primarily potassium, uranium and thorium) are is poorly known in the deep earth.
In sum, there was no shortage of heat in the early earth, and the planet's inability to cool off quickly results in the continued high temperatures of the Earth's interior. In effect, not only do the earth's plates act as a blanket on the interior, but not even convective heat transport in the solid mantle provides a particularly efficient mechanism for heat loss. The planet does lose some heat through the processes that drive plate tectonics, especially at mid-ocean ridges. For comparison, smaller bodies such as Mars and the Moon show little evidence for recent tectonic activity or volcanism.
We derive our primary estimate of the temperature of the deep earth from the melting behavior of iron at ultrahigh pressures. We know that the earth's core depths from 2,886 kilometers to the center at 6,371 kilometers (1,794 to 3,960 miles), is predominantly iron, with some contaminants. How? The speed of sound through the core (as measured from the velocity at which seismic waves travel across it) and the density of the core are quite similar to those seen in of iron at high pressures and temperatures, as measured in the laboratory. Iron is the only element that closely matches the seismic properties of the earth's core and is also sufficiently abundant present in sufficient abundance in the universe to make up the approximately 35 percent of the mass of the planet present in the core.
The earth's core is divided into two separate regions: the liquid outer core and the solid inner core, with the transition between the two lying at a depth of 5,156 kilometers (3,204 miles). Therefore, If we can measure the melting temperature of iron at the extreme pressure of the boundary between the inner and outer cores, then this lab temperature should reasonably closely approximate the real temperature at this liquid-solid interface. Scientists in mineral physics laboratories use lasers and high-pressure devices called diamond-anvil cells to re-create these hellish pressures and temperatures as closely as possible.
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