41 |
Cold shock proteins improve E. coli cell-free synthesis in terms of soluble yields of aggregation-prone proteins Higuchi K, Yabuki T, Ito M, Kigawa T Biotechnology and Bioengineering, 117(6), 1628, 2020 |
42 |
Ethanol shock enhances the recovery of anthocyanin from lowbush blueberry Maimaiti N, Aili N, Khan MK, Tang ZG, Jiang GQ, Liu Z Chinese Journal of Chemical Engineering, 28(12), 3096, 2020 |
43 |
Numerical investigations on detonations in a condensed-phase explosive and oblique shock waves in surrounding fluids Sugiyama Y, Homae T, Matsumura T, Wakabayashi K Combustion and Flame, 211, 133, 2020 |
44 |
Effect of volumetric expansion on shock-induced ignition of H-2-NO2/N2O4 mixtures He YZ, Liu YC, Mevel R Combustion and Flame, 215, 425, 2020 |
45 |
DMMP pyrolysis and oxidation studies at high temperature inside a shock tube using laser absorption measurements of CO Neupane S, Rahman RK, Baker J, Arafin F, Ninnemann E, Thurmond K, Wang CH, Masunov AE, Vasu SS Combustion and Flame, 214, 14, 2020 |
46 |
Simultaneous lateral and endwall high-speed visualization of ignition in a circular shock tube Figueroa-Labastida M, Farooq A Combustion and Flame, 214, 263, 2020 |
47 |
A pressure- or velocity-dependent acceleration rate law for the shock-to-detonation transition process in PBX 9502 high explosive Jackson SI Combustion and Flame, 213, 98, 2020 |
48 |
Sensitive and interference-immune formaldehyde diagnostic for high-temperature reacting gases using two-color laser absorption near 5.6 mu m Ding YM, Wang SK, Hanson RK Combustion and Flame, 213, 194, 2020 |
49 |
OH* chemiluminescence in the H-2-NO2 and H-2-N2O systems Mulvihill CR, Petersen EL Combustion and Flame, 213, 291, 2020 |
50 |
An experimental and modeling study on the reactivity of extremely fuel-rich methane/dimethyl ether mixtures Porras S, Kaczmarek D, Herzler J, Drost S, Werler M, Kasper T, Fikri M, Schiessl R, Atakan B, Schulz C, Maas U Combustion and Flame, 212, 107, 2020 |