| Microwave Loss in the High-Performance Dielectric at 4.2 K L Liu, M Flores, N Newman Physical Review Letters 109 (25), 257601, 2012 | 41 | 2012 |
| The dominance of paramagnetic loss in microwave dielectric ceramics at cryogenic temperatures L Liu, A Matusevich, C Garg, N Newman Applied Physics Letters 101 (25), 252901, 2012 | 23* | 2012 |
| Interesting Features of n2 D Rydberg Series Fine-Structure Splittings along the Sodium-Like Isoelectronic Sequence W Xiao-Lu, L Ling-Tao, G Xiang, S Chun, L Jia-Ming Chinese Physics Letters 25 (12), 4244, 2008 | 11 | 2008 |
| Resonator techniques to characterize material and device properties at microwave frequencies in the quantum design PPMS measurement system N Newman, L Liu, R Hanley, C Garg Application note 40, 1084-750, 2013 | 10 | 2013 |
| Growth and characterization of Ba (Cd1/3Ta2/3) O3 thin films LT Liu, C Kopas, RK Singh, RM Hanley, N Newman Thin Solid Films 520 (19), 6153-6157, 2012 | 8 | 2012 |
| Mechanisms of microwave loss tangent in high performance dielectric materials L Liu Arizona State University, 2013 | 7 | 2013 |
| Simulation of Ionic Populations in Hot Dense Plasmas via a New Method beyond the Average Atom Model W Min-Sheng, L Ling-Tao, L Jia-Ming Chinese Physics Letters 22 (7), 1576, 2005 | 5 | 2005 |
| Simulation of hot dense plasma's ionic population: beyond the average atom model W Minsheng, L Lingtao, L Jiaming, H Xiaoying Acta Physica Sinica 55, 2006 | 2 | 2006 |
| Heating of Thermo-Optic Device MN Sakib, S Fathololoumi, H Frish, L Liu, W Qian, et al US Patent App. 17/358,256, 2021 | 1 | 2021 |
| High performance microwave dielectric systems and methods N Newman, L Liu US Patent App. 15/921,102, 2018 | 1 | 2018 |
| Effective heat conduction from hotspot to heat spreader through package substrate C Xu, Z Wan, L Liu, Y Deng, J Zhao, CM Jha, K Lee US Patent 11,502,017, 2022 | | 2022 |
Chirag GargIBM Almaden Research CenterVerified email at ibm.com
