Abstract
In inertial confinement fusion experiments, fuel quality is determined mainly by the thermal environment of the capsule in the layering procedure. Owing to the absence of a radial thermal gradient, formed deuterium–deuterium (DD) ice shells in the capsule are thermally instable. To obtain a solid DD layer with good quality and long lifetime, stringent demands must be placed on the thermal performance of cryogenic targets. In DD cryogenic target preparation, two issues arise, even after the capsule’s temperature uniformity has been improved by the use of thick aluminized films. The first is the inconsistent ice shape, which is related to the capsule’s thermal field. In this article, some typical fabrication details are investigated, including adhesive penetration during assembly, the presence of the fill tube, the optical properties of the hohlraum and film surfaces, the jacket–hohlraum connection, deviations in capsule location, and asymmetrical contact at the arm–jacket interfaces. Detailed comparisons of the thermal effects of these factors provide guidance for target optimization. The second issue is the instability of seeding crystals in the fill tube due to unsteadiness of the direction of the thermal gradient in the fill tube assembly. An additional thermal controller is proposed, analyzed, and optimized to provide robust controllability of tube temperature. The analysis results and optimization methods presented in this article should not only help in dealing with thermal issues associated with DD cryogenic targets, but also provide important references for engineering design of other cryogenic targets.
Highlights
Deuterium–deuterium (DD) is nonradioactive and easy to obtain compared with other, tritium-containing, hydrogen isotope compositions
The analysis results and optimization methods presented in this article should help in dealing with thermal issues associated with DD cryogenic targets, and provide important references for engineering design of other cryogenic targets
The fractional connections between one half of the jacket and the corresponding hohlraum torus are defined as four typical thermal contact points (TCPs), which are right at the centers of the four quadrants in the horizontal section [Fig. 11(a)]
Summary
Deuterium–deuterium (DD) is nonradioactive and easy to obtain compared with other, tritium-containing, hydrogen isotope compositions. All of the simulations have focused on the macroscopic variables in target design They have provided great support for the design of indirect-drive cryogenic targets, as well as two main engineering approaches to improve the uniformity of capsule temperature. In one of these approaches, the effect of the relatively cold equator of the capsule is mitigated by having two heater rings assembled symmetrically on the top and bottom of the cylindrical jacket. The other approach is to reduce the transmissivity of the laser entrance hole (LEH) films by coating them with aluminum This has been tested and has been found to lead to good improvements in the thermal uniformity and stability of the capsule, provided that the aluminum thickness is at least ∼35 nm.
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