Plasmonics for improved photovoltaic devices HA Atwater, A Polman Nature materials 9 (3), 205-213, 2010 | 10236 | 2010 |
Photovoltaic materials: Present efficiencies and future challenges A Polman, M Knight, EC Garnett, B Ehrler, WC Sinke Science 352 (6283), aad4424, 2016 | 2017 | 2016 |
Plasmonic solar cells KR Catchpole, A Polman Optics express 16 (26), 21793-21800, 2008 | 2003 | 2008 |
Erbium implanted thin film photonic materials A Polman Journal of applied physics 82 (1), 1-39, 1997 | 1520 | 1997 |
Plasmon slot waveguides: Towards chip-scale propagation with subwavelength-scale localization JA Dionne, LA Sweatlock, HA Atwater, A Polman Physical Review B—Condensed Matter and Materials Physics 73 (3), 035407, 2006 | 1394 | 2006 |
Photonic design principles for ultrahigh-efficiency photovoltaics A Polman, HA Atwater Nature materials 11 (3), 174-177, 2012 | 1105 | 2012 |
Design principles for particle plasmon enhanced solar cells KR Catchpole, A Polman Applied Physics Letters 93 (19), 2008 | 1074 | 2008 |
Broadband omnidirectional antireflection coating based on subwavelength surface Mie resonators P Spinelli, MA Verschuuren, A Polman Nature communications 3 (1), 692, 2012 | 984 | 2012 |
Light trapping in ultrathin plasmonic solar cells VE Ferry, MA Verschuuren, HBT Li, E Verhagen, RJ Walters, REI Schropp, ... Optics express 18 (102), A237-A245, 2010 | 800 | 2010 |
Tunable light trapping for solar cells using localized surface plasmons FJ Beck, A Polman, KR Catchpole Journal of Applied Physics 105 (11), 2009 | 689 | 2009 |
Nanophotonics: shrinking light-based technology AF Koenderink, A Alù, A Polman Science 348 (6234), 516-521, 2015 | 676 | 2015 |
Transparent conducting silver nanowire networks J Van De Groep, P Spinelli, A Polman Nano letters 12 (6), 3138-3144, 2012 | 647 | 2012 |
Experimental realization of an epsilon-near-zero metamaterial at visible wavelengths R Maas, J Parsons, N Engheta, A Polman Nature Photonics 7 (11), 907-912, 2013 | 577 | 2013 |
Planar metal plasmon waveguides: frequency-dependent dispersion, propagation, localization, and loss beyond the free electron model JA Dionne, LA Sweatlock, HA Atwater, A Polman Physical Review B—Condensed Matter and Materials Physics 72 (7), 075405, 2005 | 568 | 2005 |
Defect‐related versus excitonic visible light emission from ion beam synthesized Si nanocrystals in SiO2 KS Min, KV Shcheglov, CM Yang, HA Atwater, ML Brongersma, A Polman Applied Physics Letters 69 (14), 2033-2035, 1996 | 528 | 1996 |
Evolution of light-induced vapor generation at a liquid-immersed metallic nanoparticle Z Fang, YR Zhen, O Neumann, A Polman, FJ García de Abajo, ... Nano letters 13 (4), 1736-1742, 2013 | 517 | 2013 |
Understanding individual defects in CdTe thin-film solar cells via STEM: from atomic structure to electrical activity A Polman, M Knight, EC Garnett, B Ehrler, WC Sinke Science (80-.). 352 (6283), aad4424, 2016 | 506 | 2016 |
Room‐temperature electroluminescence from Er‐doped crystalline Si G Franzo, F Priolo, S Coffa, A Polman, A Carnera Applied physics letters 64 (17), 2235-2237, 1994 | 493 | 1994 |
Rare-earth doped polymers for planar optical amplifiers LH Slooff, A Van Blaaderen, A Polman, GA Hebbink, SI Klink, ... Journal of applied physics 91 (7), 3955-3980, 2002 | 461 | 2002 |
Plasmonic light trapping in thin-film Si solar cells P Spinelli, VE Ferry, J Van de Groep, M Van Lare, MA Verschuuren, ... Journal of Optics 14 (2), 024002, 2012 | 460 | 2012 |