Using density-functional theory-based molecular-dynamics simulations, we have investigated the equation of state for silicon in a wide range of plasma density and temperature conditions of ρ=0.001-500g/cm^{3} and T=2000-10^{8}K. With these calculations, we have established a first-principles equation-of-state (FPEOS) table of silicon for high-energy-density (HED) plasma simulations. When compared with the widely used SESAME-EOS model (Table 3810), we find that the FPEOS-predicted Hugoniot is ∼20% softer; for off-Hugoniot plasma conditions, the pressure and internal energy in FPEOS are lower than those of SESAME EOS for temperatures above T ≈ 1-10 eV (depending on density), while the former becomes higher in the low-T regime. The pressure difference between FPEOS and SESAME 3810 can reach to ∼50%, especially in the warm-dense-matter regime. Implementing the FPEOS table of silicon into our hydrocodes, we have studied its effects on Si-target implosions. When compared with the one-dimensional radiation-hydrodynamics simulation using the SESAME 3810 EOS model, the FPEOS simulation showed that (1) the shock speed in silicon is ∼10% slower; (2) the peak density of an in-flight Si shell during implosion is ∼20% higher than the SESAME 3810 simulation; (3) the maximum density reached in the FPEOS simulation is ∼40% higher at the peak compression; and (4) the final areal density and neutron yield are, respectively, ∼30% and ∼70% higher predicted by FPEOS versus the traditional simulation using SESAME 3810. All of these features can be attributed to the larger compressibility of silicon predicted by FPEOS. These results indicate that an accurate EOS table, like the FPEOS presented here, could be essential for the precise design of targets for HED experiments.
Photoredox/transition-metal dual catalysis could efficiently construct C‒N bond by cross-coupling reaction. The limitations of low recovery, low utilization rate and high cost have hindered the application and development of low-cost...
In Ni/Pd catalysed electrophilic Ullmann coupling reaction, Zn powder presents the bifunctionality of heterogeneous reducing agent and organic zinc promoting transmetalation. The metal halides MXn as additives are indispensable to...
3-Oxazolin-5-ones are precursors of nitrile ylides and
represent
valuable 1,3-dipoles for constructing cyclic imines or pyrrole compounds.
Harnessing the power of photocatalysis, we accomplished a straightforward
synthesis of 3-oxazolin-5-ones from redox-active esters and secondary
nitro compounds. Visible light-induced nondecarboxylative coupling
of a redox-active ester, nitro aldol condensation, and subsequent
visible light-induced N-oxide deoxygenation were
accomplished within 2 h. The reaction mechanism was supported by experimental
data and DFT calculations.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.