Inertial confinement fusion (ICF) power, in either pure fusion or fission-fusion hybrid reactors,
is a possible solution for future world's energy demands. Formation of uniform layers of a …

Inertial confinement fusion requires very smooth and uniform solid deuterium-tritium (DT)
fuel layers. The National Ignition Facility (NIF) point design calls for a 65-to 75-μ m-thick DT …

In inertial fusion energy (IFE) research, a considerable attention has recently been focused
on the issue of large target fabrication for MJ-class laser facilities. The ignition and high-gain …

Currently, research fields related to the elaboration of efficient layering methods for ICF/IFE
applications are rapidly expanding. Significant progress has been made in the technology …

We report results of crystal growth, layering of the deuterium–deuterium (D 2) layers in
cylindrical cryogenic targets. For the first time, we realized the global coverage of the D 2 …

Realization of fusion energy imposes considerable challenges in the areas of producing
cryogenic targets with an isotropic fuel structure and developing noncontact target delivery …

We identify vapor-etched grain boundary grooves on the solid-vapor interface as the main
source of surface roughness in the deuterium-tritium (D–T) fuel layers, which are solidified …

Inertial fusion energy (IFE) research indicates that the energy generation by means of
cryogenic fuel target compression requires that targets must be injected to the target …

利用自主设计的冷冻靶微管充气系统, 通过在常温环境下向靶盒注入氘气,
研究了充气管两端压强差与充气管长度, 充气速率及充气时间之间的相互关系. 研究表明 …

Lebedev Physical Institute conducts a wide research and development program to supply
targets for inertial fusion energy (IFE) research. Current essential results in that area include …