Uranium-235

Uranium-235 is an isotope of uranium making up about 0.72% of natural uranium. Unlike the predominant isotope uranium-238, it is fissile, i.e., it can sustain a chain reaction">Decay chain">chain reaction. It is the only fissile isotope that exists in nature as a primordial nuclide.
Uranium-235 has a half-life of 704 million years. It was discovered in 1935 by Arthur Jeffrey Dempster. Its fission cross section for slow thermal neutrons is about barns. For fast neutrons it is on the order of 1 barn.
Most neutron absorptions induce fission, though a minority result in the formation of uranium-236.

Fission properties

The fission of one atom of uranium-235 releases inside the reactor. That corresponds to 19.54 TJ/mol, or 83.14 TJ/kg. Another 8.8 MeV escapes the reactor as anti-neutrinos. When nuclei are bombarded with neutrons, one of the many fission reactions that it can undergo is the following :
Heavy water reactors and some moderated reactor">neutron moderator">moderated reactors can use natural uranium, but light water reactors must use low enriched uranium because of the higher neutron absorption of light water. Uranium enrichment removes some of the uranium-238 and increases the proportion of uranium-235. Highly enriched uranium, which contains an even greater proportion of uranium-235, is sometimes used in the reactors of nuclear submarines, research reactors and nuclear weapons.
If at least one neutron from uranium-235 fission strikes another nucleus and causes it to fission, then the chain reaction will continue. If the reaction continues to sustain itself, it is said to be critical, and the mass of ²³⁵U required to produce the critical condition is said to be a critical mass. A critical chain reaction can be achieved at low concentrations of ²³⁵U if the neutrons from fission are moderated to lower their speed, since the probability for fission with slow neutrons is greater. A fission chain reaction produces intermediate mass fragments which are highly radioactive and produce further energy by their radioactive decay. Some of them produce neutrons, called delayed neutrons, which contribute to the fission chain reaction. The power output of nuclear reactors is adjusted by the location of control rods containing elements that strongly absorb neutrons, e.g., boron, cadmium, or hafnium, in the reactor core. In nuclear bombs, the reaction is uncontrolled and the large amount of energy released creates a nuclear explosion.

Nuclear weapons

The Little Boy gun-type atomic bomb dropped on Hiroshima on August 6, 1945, was made of highly enriched uranium with a large tamper. The nominal spherical critical mass for an untampered ²³⁵U nuclear weapon is, which would form a sphere in diameter. The material must be 85% or more of ²³⁵U and is known as weapons grade uranium, though for a crude and inefficient weapon 20% enrichment is sufficient. Even lower enrichment can be used, but this results in the required critical mass rapidly increasing. Use of a large tamper, implosion geometries, trigger tubes, polonium triggers, tritium enhancement, and neutron reflectors can enable a more compact, economical weapon using one-fourth or less of the nominal critical mass, though this would likely only be possible in a country that already had extensive experience in engineering nuclear weapons. Most modern nuclear weapon designs use plutonium-239 as the fissile component of the primary stage; however, HEU is frequently used in the secondary stage as an ignitor for the fusion fuel.

Decay

Uranium-235 is an alpha emitter, producing thorium-231. Uranium-235 is the main progenitor of the actinium series, one of the principal actinide decay chains, as it is the longest-lived and sole primordial nuclide. Beginning with naturally occurring uranium-235, this series includes isotopes of astatine, bismuth, francium, lead, polonium, protactinium, radium, radon, thallium, and thorium, all of which are present in natural uranium sources. The decay proceeds as :
Or in tabular form, including minor branches:

Nuclide	Decay mode	Half-life	Energy released MeV	Decay product
²³⁵U	α	7.04×10⁸ a	4.678	²³¹Th
²³¹Th	β⁻	25.52 h	0.391	²³¹Pa
²³¹Pa	α	3.27×10⁴ a	5.150	²²⁷Ac
²²⁷Ac	β⁻ 98.62% α 1.38%	21.772 a	0.045 5.042	²²⁷Th ²²³Fr
²²⁷Th	α	18.693 d	6.147	²²³Ra
²²³Fr	β⁻ 99.994% α 0.006%	22.00 min	1.149 5.561	²²³Ra ²¹⁹At
²²³Ra	α	11.435 d	5.979	²¹⁹Rn
²¹⁹At	α 93.6% β⁻ 6.4%	56 s	6.342 1.567	²¹⁵Bi ²¹⁹Rn
²¹⁹Rn	α	3.96 s	6.946	²¹⁵Po
²¹⁵Bi	β⁻	7.6 min	2.171	²¹⁵Po
²¹⁵Po	α β⁻ 2.3×10⁻⁴%	1.781 ms	7.526 0.715	²¹¹Pb ²¹⁵At
²¹⁵At	α	37 μs	8.177	²¹¹Bi
²¹¹Pb	β⁻	36.16 min	1.366	²¹¹Bi
²¹¹Bi	α 99.724% β⁻ 0.276%	2.14 min	6.750 0.573	²⁰⁷Tl ²¹¹Po
²¹¹Po	α	516 ms	7.595	²⁰⁷Pb
²⁰⁷Tl	β⁻	4.77 min	1.418	²⁰⁷Pb
²⁰⁷Pb	stable

Astrophysical dating

Knowledge of current and theoretical production ratios of uranium-235 to uranium-238 allows radiometric dating, the time since modern uranium nuclei were formed in stellar nucleosynthesis.
The 1957 B2FH landmark paper in astrophysics explained the r-process by which both nuclei form. The authors predicted their relative abundances, and those of their rapidly alpha-chain decaying parent nuclides. Thus they predicted 1.64 as the ²³⁵U/²³⁸U ratio contributed to the interstellar medium by r-process events. This takes billions of years to diminish to their present value of 0.0072. They investigate scenarios for historical contribution to the solar nebula, before contribution is cut off at the Sun's formation 4.5 billion years ago. The scenarios are: a single supernova, a finite continuous uniform series of supernovae representing the lifetime of the Milky Way, and an infinite series representing the steady-state universe. From the second scenario, they estimated an age of the Milky Way at around 10 billion years, compared to a modern value of 13.61 billion years. Significantly, at this point the oldest known objects were stellar clusters at 6.5 billion years old.