Kylie Catchpole
Cited by
Cited by
Surface plasmon enhanced silicon solar cells
S Pillai, KR Catchpole, T Trupke, MA Green
Journal of applied physics 101 (9), 2007
Plasmonic solar cells
KR Catchpole, A Polman
Optics express 16 (26), 21793-21800, 2008
Design principles for particle plasmon enhanced solar cells
KR Catchpole, A Polman
Applied Physics Letters 93 (19), 2008
Tunable light trapping for solar cells using localized surface plasmons
FJ Beck, A Polman, KR Catchpole
Journal of Applied Physics 105 (11), 2009
Rubidium multication perovskite with optimized bandgap for perovskite‐silicon tandem with over 26% efficiency
T Duong, YL Wu, H Shen, J Peng, X Fu, D Jacobs, EC Wang, TC Kho, ...
Advanced Energy Materials 7 (14), 1700228, 2017
Interface passivation using ultrathin polymer–fullerene films for high-efficiency perovskite solar cells with negligible hysteresis
J Peng, Y Wu, W Ye, DA Jacobs, H Shen, X Fu, Y Wan, N Wu, C Barugkin, ...
Energy & Environmental Science 10 (8), 1792-1800, 2017
A universal double‐side passivation for high open‐circuit voltage in perovskite solar cells: role of carbonyl groups in poly (methyl methacrylate)
J Peng, JI Khan, W Liu, E Ugur, T Duong, Y Wu, H Shen, K Wang, H Dang, ...
Advanced Energy Materials 8 (30), 1801208, 2018
The 2020 photovoltaic technologies roadmap
GM Wilson, M Al-Jassim, WK Metzger, SW Glunz, P Verlinden, G Xiong, ...
Journal of Physics D: Applied Physics 53 (49), 493001, 2020
Nanophotonic light trapping in solar cells
S Mokkapati, KR Catchpole
Journal of applied physics 112 (10), 2012
Enhanced emission from Si-based light-emitting diodes using surface plasmons
S Pillai, KR Catchpole, T Trupke, G Zhang, J Zhao, MA Green
Applied Physics Letters 88 (16), 2006
Designing periodic arrays of metal nanoparticles for light-trapping applications in solar cells
S Mokkapati, FJ Beck, A Polman, KR Catchpole
Applied Physics Letters 95 (5), 2009
Plasmon-enhanced internal photoemission for photovoltaics: theoretical efficiency limits
TP White, KR Catchpole
Applied Physics Letters 101 (7), 2012
Nanoscale localized contacts for high fill factors in polymer-passivated perovskite solar cells
J Peng, D Walter, Y Ren, M Tebyetekerwa, Y Wu, T Duong, Q Lin, J Li, ...
Science 371 (6527), 390-395, 2021
Mechanically-stacked perovskite/CIGS tandem solar cells with efficiency of 23.9% and reduced oxygen sensitivity
H Shen, J Peng, D Jacobs, N Wu, J Gong, Y Wu, SK Karuturi, X Fu, ...
Energy & Environmental Science 11 (2), 394-406, 2018
Asymmetry in photocurrent enhancement by plasmonic nanoparticle arrays located on the front or on the rear of solar cells
FJ Beck, S Mokkapati, A Polman, KR Catchpole
Applied Physics Letters 96 (3), 2010
Tandem solar cells based on high-efficiency c-Si bottom cells: top cell requirements for> 30% efficiency
TP White, NN Lal, KR Catchpole
IEEE Journal of Photovoltaics 4 (1), 208-214, 2013
Device performance of emerging photovoltaic materials (Version 3)
O Almora, D Baran, GC Bazan, CI Cabrera, S Erten‐Ela, K Forberich, ...
Advanced energy materials 13 (1), 2203313, 2023
Monolithic perovskite/silicon-homojunction tandem solar cell with over 22% efficiency
YL Wu, D Yan, J Peng, Y Wan, SP Phang, H Shen, N Wu, C Barugkin, ...
Energy & Environmental Science 10 (11), 2472-2479, 2017
Hysteresis phenomena in perovskite solar cells: the many and varied effects of ionic accumulation
DA Jacobs, Y Wu, H Shen, C Barugkin, FJ Beck, TP White, K Weber, ...
Physical Chemistry Chemical Physics 19 (4), 3094-3103, 2017
Efficient Indium‐Doped TiOx Electron Transport Layers for High‐Performance Perovskite Solar Cells and Perovskite‐Silicon Tandems
J Peng, T Duong, X Zhou, H Shen, Y Wu, HK Mulmudi, Y Wan, D Zhong, ...
Advanced Energy Materials 7 (4), 1601768, 2017
The system can't perform the operation now. Try again later.
Articles 1–20