Microplasmas for nanomaterials synthesis D Mariotti, RM Sankaran Journal of Physics D: Applied Physics 43 (32), 323001, 2010 | 670 | 2010 |
Contact electrification of insulating materials DJ Lacks, RM Sankaran Journal of Physics D: Applied Physics 44 (45), 453001, 2011 | 558 | 2011 |
Linking catalyst composition to chirality distributions of as-grown single-walled carbon nanotubes by tuning NixFe1−x nanoparticles WH Chiang, R Mohan Sankaran Nature materials 8 (11), 882-886, 2009 | 501 | 2009 |
Plasma-liquid electrochemistry: Rapid synthesis of colloidal metal nanoparticles by microplasma reduction of aqueous cations C Richmonds, RM Sankaran Applied Physics Letters 93 (13), 2008 | 440 | 2008 |
Nonthermal plasma synthesis of nanocrystals: fundamental principles, materials, and applications UR Kortshagen, RM Sankaran, RN Pereira, SL Girshick, JJ Wu, ES Aydil Chemical reviews 116 (18), 11061-11127, 2016 | 418 | 2016 |
The solvation of electrons by an atmospheric-pressure plasma P Rumbach, DM Bartels, RM Sankaran, DB Go Nature communications 6 (1), 7248, 2015 | 320 | 2015 |
Synthesis of blue luminescent Si nanoparticles using atmospheric-pressure microdischarges RM Sankaran, D Holunga, RC Flagan, KP Giapis Nano letters 5 (3), 537-541, 2005 | 289 | 2005 |
Catalyst-free, highly selective synthesis of ammonia from nitrogen and water by a plasma electrolytic system R Hawtof, S Ghosh, E Guarr, C Xu, R Mohan Sankaran, JN Renner Science advances 5 (1), eaat5778, 2019 | 252 | 2019 |
Charge segregation depends on particle size in triboelectrically charged granular materials KM Forward, DJ Lacks, RM Sankaran Physical review letters 102 (2), 028001, 2009 | 224 | 2009 |
The 2022 Plasma Roadmap: low temperature plasma science and technology I Adamovich, S Agarwal, E Ahedo, LL Alves, S Baalrud, N Babaeva, ... Journal of Physics D: Applied Physics 55 (37), 373001, 2022 | 219 | 2022 |
Formation of nanodiamonds at near-ambient conditions via microplasma dissociation of ethanol vapour A Kumar, P Ann Lin, A Xue, B Hao, Y Khin Yap, RM Sankaran Nature communications 4 (1), 2618, 2013 | 192 | 2013 |
Continuous-flow, atmospheric-pressure microplasmas: a versatile source for metal nanoparticle synthesis in the gas or liquid phase WH Chiang, C Richmonds, RM Sankaran Plasma Sources Science and Technology 19 (3), 034011, 2010 | 191 | 2010 |
Perspectives on atmospheric-pressure plasmas for nanofabrication D Mariotti, RM Sankaran Journal of Physics D: Applied Physics 44 (17), 174023, 2011 | 184 | 2011 |
Electron-transfer reactions at the plasma–liquid interface C Richmonds, M Witzke, B Bartling, SW Lee, J Wainright, CC Liu, ... Journal of the American Chemical Society 133 (44), 17582-17585, 2011 | 177 | 2011 |
Hollow cathode sustained plasma microjets: Characterization and application to diamond deposition RM Sankaran, KP Giapis Journal of Applied Physics 92 (5), 2406-2411, 2002 | 173 | 2002 |
Microplasmas for advanced materials and devices WH Chiang, D Mariotti, RM Sankaran, JG Eden, K Ostrikov Advanced Materials 32 (18), 1905508, 2020 | 171 | 2020 |
Plasma-assisted reduction of graphene oxide at low temperature and atmospheric pressure for flexible conductor applications SW Lee, C Mattevi, M Chhowalla, RM Sankaran The journal of physical chemistry letters 3 (6), 772-777, 2012 | 159 | 2012 |
Synergistic effects in bimetallic nanoparticles for low temperature carbon nanotube growth WH Chiang, RM Sankaran Advanced Materials 20 (24), 4857-4861, 2008 | 137 | 2008 |
Decoupling interfacial reactions between plasmas and liquids: Charge transfer vs plasma neutral reactions P Rumbach, M Witzke, RM Sankaran, DB Go Journal of the American Chemical Society 135 (44), 16264-16267, 2013 | 133 | 2013 |
Microplasma synthesis of metal nanoparticles for gas-phase studies of catalyzed carbon nanotube growth WH Chiang, RM Sankaran Applied Physics Letters 91 (12), 2007 | 128 | 2007 |