N8. Thermonuclear Reactions On Earth

Fusion reactions in the Sun and other stars are examples of thermonuclear reactions—that is, nuclear reactions brought about by high temperature. Thermonuclear reactions are, quite literally, nuclear burning. They are completely analogous to ordinary chemical combustion. In chemical (or atomic) burning, high temperature initiates the reaction, and energy released by the reaction keeps the temperature high and spreads the fire. The chemical reaction may proceed in several steps; its net result is a combination of atoms into more tightly bound molecules. All of these features characterize nuclear burning as well. More tightly bound nuclei are produced by a reaction or series of reactions initiated and propagated by high temperature. Apart from the nature of the reacting particles, the difference is one of scale. At a temperature of ten million degrees or more, the thermonuclear flame is at least 10⁴ times hotter and at least 10⁶ times more potent as an energy source than a typical chemical flame. For the design of thermonuclear weapons, one more feature that nuclear and atomic combustion have in common is important—-the harmlessness of cold reactants. The concept of critical mass, important for fissionable material, is not applicable to thermonuclear fuel. Just as there is no limit to the size of a lumber yard or an oil storage depot, there is no theoretical limit to the size of a thermonuclear weapon. Any amount of nuclear fuel can be stored with safety—until it is ignited. Although a match is sufficient to set ablaze the lumber yard or the oil depot, nothing less than a fission bomb can ignite a thermonuclear reaction.

The Sun is forced, as it were, to make do with protons as its nuclear fuel. On Earth, we have available a variety of other nuclei, some of which react with higher probability and at lower temperatures than do protons. Actually, the Sun’s proton-proton cycle proceeds at a very leisurely pace. There is no possibility to use the same reaction as an energy source on earth.¹ More reactive are the heavier isotopes of hydrogen, deuterium and tritium. Especially favorable is the reaction between a deuteron and a triton, known as the DT reaction. It can proceed explosively at a temperature of about 60 million degrees:

₁H¹ +₁H³ →₂He⁴ +n ,

or, in simpler notation,

d + t → α + n .

This reaction releases 17.6 MeV, or about 3.5 MeV per nucleon. Most of this energy—14 MeV—appears as kinetic energy of the neutron. The DT reaction is one of the key reactions in thermonuclear weapons.

Except for trace amounts produced by cosmic rays, tritium does not occur in nature. It must be manufactured at great expense in nuclear reactors,² and once manufactured, it decays into He³ with a half life of 12.3 years. If fusion is to be practical as a controlled power source in the future, it must rely on plentiful deuterium for fuel. The DD reaction proceeds with approximately equal probability in two ways:

(1) d +d →He³ +n (energy release = 3.3 MeV)

(2) d +d →t +p (energy release = 4.0 MeV)

In conditions that can be visualized on Earth (even in a thermonuclear explosion), the helium-3 produced does not significantly react further. The tritium, however, is consumed by the DT reaction, adding a large increment of energy. The net reaction in the burning of pure deuterium is approximately,

5d → He³ + He⁴ + 2n + p (energy release = 25 MeV).

The high-temperature requirement for thermonuclear reactions can be understood quite simply in terms of the small size of nuclei and the electrical repulsive force between them. In order for a pair of deuterons, or a deuteron and a triton, to “touch”—that is, to be close enough together so that their wave amplitudes overlap significantly—their centers must be separated by not more than about 10^–14 m. At this separation, the electric potential energy associated with their relative position can readily be calculated (P. E. = ke²/d). It turns out to be 144 keV.

Although small compared with energies available even in the puniest accelerators, this energy is enormous compared with ordinary thermal energy. Normally the electric repulsion between hydrogen nuclei, or any other nuclei, very effectively keeps them apart, even if their atomic electrons are stripped away. Even at a temperature of 10,000 K, capable of vaporizing all matter, the mean kinetic energy of thermal motion is only 1.3 eV per particle, more than 100,000 times smaller than the potential barrier of 144 keV cited above. What temperature would be required in order that an average pair of deuterons, in a head-on collision, could climb the potential barrier and come within 10^–14 m of each other? To answer this question, let us suppose that each deuteron has an energy 1⁄2kT equal to half of the total required, or

1⁄2kT = 72 KeV = 1.15 × 10^–14 J .

Using k = 1.38 × 10^–23 J/K, we find

T = 560 million K .

In energy units, kT = 48 keV. The actual temperature requirement to ignite deuterium is not this extreme, for two reasons. First, some nuclei have considerably more kinetic energy than the average. They can more easily overcome the force of electric repulsion. Second, barrier penetration can be significant. The nuclei need not all surmount the potential-energy barrier in order to react. In practice, thermonuclear explosions proceed at temperatures of about 60 million K (kT = 5 keV). A fission bomb can provide ignition at this temperature.

Deuterium is a satisfactory thermonuclear fuel in principle, and is the only fuel contemplated for possible future fusion power reactors. But as a major component of a bomb, it has a serious disadvantage. In order to be stored compactly at high density, it must be cooled to its liquefaction temperature of 20 K (– 253 °C). This requires elaborate refrigeration techniques. A common fusion fuel actually used in the “H bomb” is a particular isotopic form of lithium hydride, called lithium 6 deuteride (₃Li⁶ ₁H²), which is a solid at normal temperature. The lithium plays two important roles as a constituent of the thermonuclear fuel. First, through its chemical combination with deuterium, it holds the deuterons close together, thereby helping to make possible the DD reactions. Second, the lithium itself participates in a key reaction that “manufactures” tritium to stoke the DT reaction.

The significant nuclear reactions in lithium 6 deuteride are these:

(1) ₁H² + ₁H² → ₂He³ + n (energy release = 3.3 MeV),

(2) ₁H² + ₁H² → ₁H³ + p (energy release = 4.0 MeV),

(3) ₁H² + ₁H³ → ₂He⁴ + n (energy release = 17.6 MeV),

(4) ₃Li⁶ + n → ₁H³ + ₂He⁴ (energy release = 4.9 MeV).

The first two are the branches of the DD reaction. The third is the DT reaction. The fourth reaction, like the second branch of the DD reaction, is a supplier of tritium for the DT reaction. This neutron-induced reaction is not itself a thermonuclear reaction, since the neutron has no energy barrier to overcome to reach the Li⁶ nucleus. It is in fact a fission reaction (although the word “fission” is usually reserved to describe the splitting of heavy nuclei). The Li⁶ nucleus absorbs a neutron to become temporarily a Li⁷ nucleus that splits into a triton and an alpha particle. Note that in these four interlocked reactions both tritons and neutrons play important roles, although neither is initially present in the fuel. Reactions 1 and 3 produce neutrons to stimulate the Li⁶ reaction; reactions 2 and 4 produce tritium to burn in the DT reaction.

One way to increase both the rate of burning and the energy release of a thermonuclear weapon is to encase its lithium 6 deuteride fuel in U²³⁸. The 14-MeV neutrons produced by the DT reaction, many of which escape from the combustion zone, are energetic enough to induce fission in U²³⁸. From the fission event emerge several lower energy neutrons that can stimulate the tritium-producing reaction in Li⁶. Through this sequence of fission-fusion-fission-fusion, the energy of the atomic bomb trigger can be multiplied a thousand-fold,³ using only cheap and readily available materials—lithium 6, deuterium, and uranium 238. In such a uranium-encased weapon, about half of the energy and almost all of the hazardous fallout result from uranium fission. In so-called “clean” bombs (if such exist), most of the energy comes from fusion.

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