"Clean Nuclear Fuels" (warm fission)

[See also topically: cold fission; and hot fission potentials]

The atomic-age nuclear power industry started from observed alpha-radiodecay nuclides and neutron-chaining fission, but there are several potential beta- and gamma-chaining nuclei of significant power output up to 10%-hot-per-nucleon (cf 100% for Pu-239+n):--

'Warm fission' is like hot fission but of typically lighter nuclei, near, shy-of, or barely, radioactive.

('Clean fission' has typically stable daughter products, and readily stoppable, non neutronic, charged-particle and photon emissions.)

Warm fission also typically includes radiodecay, particularly the double-emissions, whereas hot-fission typically does-not-include its single emission radiodecays. (N.B. the usual 'old' meaning of fission, was radiodecay to near-halves: because that yielded more energy than small side decay particularly from the 'island' of large 'double-nuclei' ... but here we're looking at smaller 'continental' nuclei.)

And as the Class grows we find also what is neither radiodecay nor fission, but particle-capture rather than emission: the double-EC.

Warm fission and clean nuclear pretty much coincide ... Great for space launch and cruising habitable planets and the solar system... (But note still: Where neutron-chaining spallation is still possible, the fuel must be activated some distance from habitable planets.)

NUCLEAR ENERGY FROM TRANSMUTATION:

The largest classes, two, of warm nuclear energy, are the double-beta and double-EC-gamma 'recessive daughter' nuclides as may be transmuted to their 'dominant-daughter sibling' nuclides and so yield energy ... These are cross-element 'siblings':

BETA-TYPE:

nucleus	iso. %	mode	intermed.	balance	yield/n	notes
Ca-48	0.19%	2 β-	help	+0.28+3.99 = 4.27 MeV	89 KeV/n	low cost; clean; 1018.8yr decay
Se-82	8.73%	2 β-	easy	-0.10+3.09 = 3.00 MeV	37 KeV/n	low cost; clean; 1020.0yr decay
Zr-96	2.80%	2 β-	help	+0.16+3.19 = 3.35 MeV	35 KeV/n	low cost; clean; 1019.6yr decay
Mo-100	9.6%	2 β-	easy	-0.17+3.20 = 3.03 MeV	30 KeV/n
Nd-150	5.6%	2 β-	easy	-0.09+3.45 = 3.37 MeV	22 KeV/n

EC-TYPE:

nucleus	iso. %	mode	intermed.	balance	yield/n	notes
Ni-58	68.1%	2 EC	stiff	-0.38+2.31 = 1.93 MeV	33 KeV/n	low cost; clean
Ru-96	5.52%	2 EC	stiff	-0.25+2.97 = 2.72 MeV	28 KeV/n
Cd-106	1.3%	2 EC	stiff	-0.20+2.97 = 2.77 MeV	26 KeV/n

These have high-sub-mega to mega electron-volt, no neutrons, and, ready electrochemical handleability. Their output electrons exceed their 1s-orbital energies by factors ranging to thousands, ensuring many subatomic incursions, where negative electrons gain additional catalytic MeV's nearing positive nuclei already ripe for triggering, and so possibly self-sustaining, and charge-barrier controllable.

Calcium-48 is refinable, atomically stable, nuclearly clean, powerful and efficient: ideal for habitable-planet shuttling ... Its rapid daughter-product is Titanium already abundant itself; Calcium atomic abundance is 2.5%-silicon in the Earth crust, whence Ca-48 is 500 ppm (cf Boron, Zinc), and already in very high production, and very inexpensive. Its nonusable isotopes are 8% lighter. (Cf the difference between uranium-235:238 isotopes is a sixth that; And the relative abundance of hydrogen-2 isotope a twelfth.)

Ca-48 has the advantage of surplus energy ready-to-go just shy of radioactive (probably due to double-beta symmetry stability): the nucleus overburdened by 19 KeV closed atomic electron orbitals; It can be handled as a safe chemical until nuclear furnaced: Nuclear extraction methods include catalysis by interstitial-incursing deuterons or alphas (as from Pu-238) to warp the inner orbitals, and possibly MeV nuclear-impact electrons. It is probably safe from beta-chaining, by the 43× higher velocity of electrons needing many incursions, evacuating, -as compared to neutron-chaining which builds to a significant fraction before nuclear fragments evaporate the basis metal; Beta-chaining is likelier to evaporate it early, releasing little prompt nuclear energy-... Conversely, nuclear-impinging electrons may simply waste energy creating Beta-pairs. Its tentative hazard may be high energy Beta-decay reacceleration of alphas.

(Note that alphas may have an advantage over deuterons in that while their available energy of their double charge reaching twice the radius, is the same, alphas retain one charge while one electron is in transit, -and,- alphas linger longer in proximity to a nucleus, being both slower and having proportionally further to exit ... the same is more so for a few heavier nuclei but alphas are also most stable.)

Zirconium-96 is refinable, atomically stable, nuclearly clean, powerful and efficient: ideal for habitable-planet shuttling ... Its rapid daughter-product is Molybdenum deemed "essential" in small quantities and high-use return; Zirconium atomic abundance is 300 ppm-silicon in the Earth crust, whence Zr-96 is 8 ppm (cf Lead, Tin), and already in high production. Its nonusable isotopes are 4% lighter.

Zr-96 has the advantage of surplus energy ready-to-go just shy of radioactive (probably due to double-beta symmetry stability): the nucleus overburdened by 99 KeV closed atomic electron orbitals; It can be handled as a safe chemical until nuclear furnaced: Nuclear extraction methods include catalysis by interstitial-incursing deuterons or alphas (as from Pu-238) to warp the inner orbitals, and possibly MeV nuclear-impact electrons. It is probably safe from beta-chaining, by the 43× higher velocity of electrons needing many incursions, evacuating, -as compared to neutron-chaining which builds to a significant fraction before nuclear fragments evaporate the basis metal; Beta-chaining is likelier to evaporate it early, releasing little prompt nuclear energy-... Conversely, nuclear-impinging electrons may simply waste energy creating Beta-pairs. Its tentative hazard may be high energy Beta-decay reacceleration of alphas.

Nickel-58 is by tunnel-electron-capture probably already involved in the cold-fusion reputation of the early '90's, but may have a gamma-chain; It might be used for additional power from surplus electrons, compounded in alloy.

CO-CHAINING:

The best choices appear to be five Beta-types alone, But blending Beta-type and EC-type may augment their utilization by high-energy electrons 'impinging' electron-capture nuclei and high-energy gamma-rays 'stimulating' electron-emission nuclei.

OTHER, LESS USABLE ELEMENTS: (higher energy intermediate nuclei, lower yields)

nucleus	iso. %	mode	intermed.	balance	yield/n	notes
Ca-40	97%	2 EC	severe	-1.31+1.51 = 0.20 MeV	5 KeV/n	low 11% branching ratio
Ar-36	0.4%	2 EC	severe	-0.71+1.14 = 0.43 Mev	12 KeV/n
Ca-46	0.004%	2 EC	severe	-1.38+2.37 = 0.99 MeV	22 KeV/n	may appear in Ca-48 enrichment
Cr-50	4.3%	2 EC	severe	-1.04+2.21 = 1.17 MeV	23 KeV/n
Fe-54	5.8%	2 EC	severe	-0.70+1.38 = 0.68 MeV	12 KeV/n
Zn-64	49%	2 EC	stiff	-0.58+1.68 = 1.10 MeV	17 KeV/n
Zn-70	0.6%	2 β	severe	-0.66+1.66 = 1.00 MeV	14 KeV/n
Se-74	0.9%	2 EC	severe	-1.35+2.56 = 1.21 MeV	16 KeV/n
Ge-76	7%	2 β	severe	-0.92+2.96 = 2.04 MeV	27 KeV/n
Se-80	50%	2 β	severe	0.13 MeV	2 KeV/n
Sr-84	0.6%	2 EC	severe	-0.89+2.68 = 1.79 MeV	21 KeV/n
Kr-86	17%	2 β	stiff	1.26 MeV	15 KeV/n
Mo-92	15%	2 EC	stiff	1.65 MeV	18 KeV/n
Zr-94	17%	2 β	severe	-0.91+2.05 = 1.14 MeV	12 KeV/n	may appear in Zr-96 enrichment
Mo-98	24%	2 β	severe	-1.68+1.80 = 0.11 Mev	1 KeV/n	may appear in Mo-100 enrichment
Pd-102	1%	2 EC	severe	-1.15+2.32 = 1.17 MeV	11 KeV/n	(see 'mock cold fusion')
Ru-104	19%	2 β	severe	-1.14+2.44 = 1.30 MeV	13 KeV/n
Cd-108	1%	2 EC	severe	0.27 MeV	3 KeV/n	tiny 3% branching ratio
Pd-110	12%	2 β	severe	2.00 MeV	18 KeV/n
Sn-112	1%	2 EC	stiff	-0.66+2.59 = 1.92 MeV	17 KeV/n
Cd-113	12%	β-	-none-	0.32 MeV	3 KeV/n
Cd-114	29%	2 β	severe	0.54 MeV	5 KeV/n
Cd-116	7%	2 β	stiff	2.8 MeV	24 KeV/n
Te-120	0.1%	2 EC	severe	1.70 MeV	14 KeV/n
Sn-122	5%	2 β	severe	0.36 MeV	3 KeV/n
Sn-124	6%	2 β	severe	2.29 MeV	18 KeV/n
Xe-126	0.1%	2 EC	severe	0.90 MeV	7 KeV/n
Te-128	32%	2 β	severe	0.87 MeV	7 KeV/n
Te-130	34%	2 β	stiff	-0.42+2.95 = 2.53 MeV	19 KeV/n
Ba-130	0.1%	2 EC	stiff	2.61 MeV	20 KeV/n
Ba-132	0.1%	2 EC	severe	0.84 MeV	6 KeV/n
Xe-134	10%	2 β	severe	0.83 MeV	6 KeV/n
Ce-136	0.2%	2 EC	stiff	-0.47+2.87 = 2.40 MeV	18 KeV/n
Ce-138	0.3%	2 EC	severe	0.69 MeV	5 KeV/n	intermediate is longterm
Ce-142	11%	2 EC	severe	1.42 MeV	10 KeV/n
Sm-144	3%	2 EC	severe	1.78 MeV	12 KeV/n	daughter has slow secondary alpha
Nd-148	6%	2 β	severe	1.93 MeV	13 KeV/n	may appear in Nd-150 enrichment; daughter has slow secondary alpha
Gd-152	0.2%	2 EC	severe	0.06 MeV	. KeV/n	primary has slow alpha
Sm-154	23%	2 β	severe	1.25 MeV	8 KeV/n
Dy-156	0.06%	2 EC	stiff	2.01 MeV	13 KeV/n
Dy-158	0.1%	2 EC	severe	0.28 MeV	2 KeV/n
Gd-160	22%	2 β	easy	-0.11+1.84 = 1.73 MeV	11 KeV/n
Er-162	0.1%	2 EC	stiff	1.84 MeV	11 KeV/n
Er-164	2%	2 β	severe	0.025 MeV	. KeV/n
Yb-168	0.1%	2 EC	stiff	1.42 MeV	8 KeV/n
Er-170	15%	2 β	stiff	0.65 MeV	. KeV/n
Hf-174	0.2%	2 EC	stiff	1.10 MeV	6 KeV/n	primary has alpha
Yb-176	13%	2 β	stiff	1.09 MeV	6 KeV/n	intermediate is longterm
W-180	0.1%	2 EC	severe	0.15 MeV	1 KeV/n
Os-184	0.02%	2 EC	easy	-0.03+1.48 = 1.45 MeV	8 KeV/n	daughter has slow secondary alpha
W-186	28%	2 β	stiff	0.49 MeV	3 KeV/n	daughter has slow secondary alpha
Pt-190	0.01%	2 EC	severe	1.38 MeV	7 KeV/n	primary has slow alpha
Os-192	41%	2 β	severe	0.41 MeV	2 KeV/n
Hg-196	0.2%	2 EC	severe	0.82 MeV	4 KeV/n
Pt-198	7%	2 β	severe	1.05 MeV	5 KeV/n

OTHER NOTES:

Beryllium-10 though nuclear-reactor-made, might be of interest: Be-10 is a ten-thousandth as radioactive as Tritium H-3 but nine-times more efficient toward possibly beta-chaining; low weight, 56 KeV/n; clean; but high decay 10^6.2yr; high cost.

[under further research]

This article was developed in part for project Sesquatercet movie-stories.

A premise discovery under the title,