Engineering Aspects of Cryogenic Laser-Fusion Targets

“…Thus, a frozen lump of tritium self-heats and its temperature elevates. This self-heating drives mass redistribution in a target interior according to a model by Martin et al [3]. Simply, the tritium or a 50/50 deuterium/tritium mixture (D-T) sublimes from the thicker, warmer layers and refreezes on colder, thinner layers.…”

“…Simply, the tritium or a 50/50 deuterium/tritium mixture (D-T) sublimes from the thicker, warmer layers and refreezes on colder, thinner layers. The process is predicted to take place with a time constant given by r = H s / q where H s is the enthalpy of sublimation and q is the heat generated by the beta decay per unit volume [1,3]. For T 2 , the predicted time constant is r = 14.4 min at 19.6 K and it would be about 1.85 times as long for D-T. Work by Hoffer and Foreman [ 1 ] demonstrated that the process does indeed take place and at rates that are not inconsistent with the model [3].…”

“…The process is predicted to take place with a time constant given by r = H s / q where H s is the enthalpy of sublimation and q is the heat generated by the beta decay per unit volume [1,3]. For T 2 , the predicted time constant is r = 14.4 min at 19.6 K and it would be about 1.85 times as long for D-T. Work by Hoffer and Foreman [ 1 ] demonstrated that the process does indeed take place and at rates that are not inconsistent with the model [3]. Cryogenic, high gain targets for ICF power reactors based on this concept would offer substantial fabrication advantages.…”

“…The heat from the beta decay will drive sublimation of the D-T from regions of the interior where the D-T is thick to regions where the frozen D-T is thin. The layer should approach uniformity exponentially, with a time constant that depends on the 3 He content of the fuel. As a noncondensable gas, 3 He impedes the mass transfer of D-T inside the target.…”

“…The layer should approach uniformity exponentially, with a time constant that depends on the 3 He content of the fuel. As a noncondensable gas, 3 He impedes the mass transfer of D-T inside the target. The 3 He is swept to the colder surfaces by the D-T flow and there forms a diffusion barrier for the freezing D-T.…”

Solid fuel targets for the ICF reactor

“…Thus, a frozen lump of tritium self-heats and its temperature elevates. This self-heating drives mass redistribution in a target interior according to a model by Martin et al [3]. Simply, the tritium or a 50/50 deuterium/tritium mixture (D-T) sublimes from the thicker, warmer layers and refreezes on colder, thinner layers.…”

“…Simply, the tritium or a 50/50 deuterium/tritium mixture (D-T) sublimes from the thicker, warmer layers and refreezes on colder, thinner layers. The process is predicted to take place with a time constant given by r = H s / q where H s is the enthalpy of sublimation and q is the heat generated by the beta decay per unit volume [1,3]. For T 2 , the predicted time constant is r = 14.4 min at 19.6 K and it would be about 1.85 times as long for D-T. Work by Hoffer and Foreman [ 1 ] demonstrated that the process does indeed take place and at rates that are not inconsistent with the model [3].…”

“…The process is predicted to take place with a time constant given by r = H s / q where H s is the enthalpy of sublimation and q is the heat generated by the beta decay per unit volume [1,3]. For T 2 , the predicted time constant is r = 14.4 min at 19.6 K and it would be about 1.85 times as long for D-T. Work by Hoffer and Foreman [ 1 ] demonstrated that the process does indeed take place and at rates that are not inconsistent with the model [3]. Cryogenic, high gain targets for ICF power reactors based on this concept would offer substantial fabrication advantages.…”

“…The heat from the beta decay will drive sublimation of the D-T from regions of the interior where the D-T is thick to regions where the frozen D-T is thin. The layer should approach uniformity exponentially, with a time constant that depends on the 3 He content of the fuel. As a noncondensable gas, 3 He impedes the mass transfer of D-T inside the target.…”

“…The layer should approach uniformity exponentially, with a time constant that depends on the 3 He content of the fuel. As a noncondensable gas, 3 He impedes the mass transfer of D-T inside the target. The 3 He is swept to the colder surfaces by the D-T flow and there forms a diffusion barrier for the freezing D-T.…”

Solid fuel targets for the ICF reactor

Laser compression and stability in inertial confinement fusion