U235 and Pu239 have extremely long half-lives. This makes them unsuitable for power generation, as they simply won't disintigrate fast enough.

Sr-90 is an acceptable replacement that has been used on Earth bound RTGs. The only problem is that it takes significantly more Sr-90 to produce the same power output as Pu-238. In addition, I'm not sure how much Sr-90 governments keep around. The stuff has properties similar to Calcium and is treated as such by your body. This makes it somewhat dangerous if it gets into the environment.

Still, Sr-90 is nowhere near as bad as Iodine radioisoptopes.

Just a couple of clarifications....

Pu-238 just happens to be farily abundant and it is already a byproduct of fuel reprocessing.

Actually no -- although there is a small percentage (~1.5%) of Pu-238 in the Pu present in spent nuclear fuel (SNF). The majority of Pu in SNF is Pu-239, 240 and 241 (i.e. the heavy Pu isotopes, produced from neutron capture by U-238). To extract the small percentage of Pu-238 (a product of neutron absorbtion by U-235, by way of U-236, Neptunium-237 and 238), you would need to do isotopic enrichment, which is VERY complicated & expensive. Instead, Pu-238 is produced in its isotopically pure form by irradiating highly-enriched Uranium (HEU). Then the separation process is just a chemical one (the enrichment process having been performed at the Uranium stage, instead of Pu, which is much more difficult to handle in an enrichment plant, not least because the mass difference between Pu-238 and 239 is much less than that between U-235 and 238).

Also, the half-life of Pu-238 is 87.8 years, not 14. On a 10-year mission, the energy drop is pretty minimal. But an extended mission to Kuiper Belt objects could take some ten years on top of that, and if you've started out with a bare minimum to begin with, the power drop will then become fairly significant -- particularly as your power REQUIREMENTS actually SHOULD go up, due to the increased distance from earth, and the transmission signal power needed to maintain the same bit-rate.....

 

Though not working in any nuclear-related industry, I had some vague remembrance that RTG plutonium was produced from enriched fissile material:

Actually, RTGs are produced from excess fission waste material. U235 & Pu-239 are the primary materials used in fission reactions. (There are a few others, but they're irrelevant to this discussion.) Pu-238, Pu-242, Cesium-137, Strontium-90, and other by products of U235 and Pu-239 fission tend not to be very useful for continuing the fission process. In some cases, the material is simply too hot to create a stable fission pile, in other cases neutron capture is insufficient to produce fission in the element.

this is why I assumed that excess military U235 could be well recycled for science use

You know what they say about assuming. You need to keep in mind that RTGs function by taking the raditation from a radioisotope and converting it into electricity. (With a thermal conversion step in between.) If you look at the half life of U235, you'll find that half of it will disintigrate in 703,800,000 years. i.e. If you have 1 mole of U235 (6.02214199E23 atoms), you can expect that the U235 will produce about 13,566,415 disintigrations per second. While that may sound like a lot, it isn't. Each disintigration produces 4.679 MeV. Multiplying that by our disintigrations and converting to joules, we find that Uranium-235 produces a whopping 0.00001 watts.

Pu-238, OTOH, has a half-life of 87.74 years and a decay energy of 5.593 MeV. Using the same equation as before, we find that Pu-238 produces 6.529E15 disintigrations per second. Working that out, we find that Pu-238 produces 5.85 kilowatts of power. (Can someone check my figures? This seems a little high.) And that's not counting the spontaneous fission events!

Does that make the choice of radioisotopes a little clearer for you?

here's a bit of an update on the RTG situation....

Idaho laboratory could house $230 million nuclear space-security program
Knight-Ridder Tribune
Thu 18 Nov 2004
Michelle Dunlop, The Times-News, Twin Falls, Idaho

Nov. 18--ARCO, Idaho -- The Idaho National Engineering and Environmental Laboratory might be the new home to a nuclear program that produces materials for national security and space exploration, according to Department of Energy officials.

The DOE announced its intent to consolidate the manufacturing of radioisotope power systems, like those used in NASA's recent Cassini mission to Saturn, to the INEEL site. INEEL's Advanced Test Reactor already is used in the production of the systems, in combination with production at two other DOE sites. Neither of the other two sites has a reactor readily available, thus eliminating the possibility of consolidation at those locations.

The department is asking for public comment on environmental impacts and other issues the DOE needs to consider in its initial assessment of consolidation.

"As part of this process, we're asking the public to identify what other things we should consider," said Timothy A. Frazier, program director of radioisotope power systems for the DOE. "We'll review the comments that we receive and revise the environmental impact statement with the comments. And then we'll make it final." If the process goes smoothly, the DOE expects to begin construction for the radioisotope power system facility at INEEL in October of 2007. The entire project is projected to cost $230 million, Frazier said. The facility would be operational by late 2010.

Coincidentally, the United States currently has an agreement with Russia through 2010 to purchase the plutonium-238 needed to make radioisotope power systems. A 2003 audit report on plutonium-238 released by the DOE concluded the following: "Unless the Department accelerates its program to re-establish a plutonium-238 production capability, it risks being unable to meet future national security and NASA requirements." Brad Bugger, communications director for the DOE, elaborated on the report's findings.

"We cannot use the plutonium we purchase from Russia for national defense," Bugger said. "We would like to establish a domestic source." The United States relies on the plutonium-238 it has in inventory for national defense purposes, while procuring more from Russia for space-related projects. Frazier could not comment on which national security applications the systems are used in.

"They are helping safeguard the U.S.," he said.

However, he said, a large portion of the systems produced will go to NASA.

During the manufacturing of radioisotope power systems, DOE workers must first process plutonium-238 and secondly purify and encapsulate the material. These two steps generate some nuclear waste, Frazier said.

"We're going to take great pains to reuse the waste," he said. "There will likely be some remote-handled transuranic waste." According to a recent publication by the state of Idaho's INEEL Oversight Program, INEEL currently houses 63,000 cubic meters of transuranic waste. Some of the waste is in storage, the rest buried.

The transuranic waste generated during the production of radioisotope power systems at INEEL will be shipped to the Waste Isolation Pilot Plant near Carlsbad, New Mexico.

"We're expecting that to be minimum," Frazier said.

Transuranic waste includes plutonium and neptunium Ñ both used in the production of radioisotope power systems Ñ as well as americium. This classification of waste does not contain a high level of radioactivity, but remains radioactive for a long time. The Environmental Protection Agency lists the half-life of plutonium-238 at 87.7 years. Both the EPA and DOE maintain that plutonium-238 is not useful for nuclear weapons proliferation.

"Plutonium-238 is not weapons grade material," Frazier said.

Although Frazier expects moderate increases in security once the facility is complete, he does not anticipate a large build up.

"That is one of the really great things about locating at INEEL," Frazier said. "The Idaho site does have a high degree of security." Specifics on the economic impacts of the program's consolidation will be available when the draft assessment is ready, Bugger said. The DOE does not anticipate a significant increase in permanent jobs related to the project. However, the construction phase may provide work for contractors in the state.

"Our hope is that it would produce some trickle-down effects in Idaho," Frazier said.

Since the DOE will be involved in the design of the new facility, the department will be able to take into consideration environmental factors that have long been a concern to Idahoans Ñ such as waste polluting the aquifer, worker health and safety and air quality issues.

"We have the unique ability to design the facility from the ground up," Frazier said.

On Wednesday, at least one member of the Idaho delegation expressed his satisfaction over the DOE proposal.

"Senator Craig is pleased about the consolidation," said Mike Tracy, a spokesman for the senator. "NASA has been very pleased with what Idaho's DOE site has done."

 

TIMELINE FOR CONSOLIDATION PROCESS:

--December 2004 -- The DOE will conduct informational meetings.

--Jan. 31, 2005 -- End of initial public comment on the process for the DOE's environmental impact assessment.

--Spring 2005 -- A draft of the environmental impact statement will be released for additional public comment.

--Summer 2005 -- The DOE will finalize its assessment.

--September 2005 -- The Department anticipates the signing of the record of decision.

--October 2007 -- Construction will commence on a radioisotope power system facility at INEEL.

--Late 2010 -- The radioisotope power system facility should be operational.

Yep. They keep waiting and the plutonium keeps decaying....

If we don't go soon, then Pluto will not be visited for perhaps another thirty years or more. RTG's are the only plausible power source for such a mission that will operate for years at cryogenic temperatures. I don't understand what the problem is--why don't we just buy some more Pu-238 from the Russians, or are we not on speaking terms with them anymore?