TY - JOUR
T1 - Corrugation Architecture Enabled Ultraflexible Wafer-Scale High-Efficiency Monocrystalline Silicon Solar Cell
AU - Bahabry, Rabab R.
AU - Kutbee, Arwa T.
AU - Khan, Sherjeel M.
AU - Sepulveda, Adrian C.
AU - Wicaksono, Irmandy
AU - Nour, Maha A.
AU - Wehbe, Nimer
AU - Almislem, Amani Saleh Saad
AU - Ghoneim, Mohamed T.
AU - Sevilla, Galo T.
AU - Syed, Ahad
AU - Shaikh, Sohail F.
AU - Hussain, Muhammad Mustafa
N1 - KAUST Repository Item: Exported on 2020-10-01
PY - 2018/1/2
Y1 - 2018/1/2
N2 - Advanced classes of modern application require new generation of versatile solar cells showcasing extreme mechanical resilience, large-scale, low cost, and excellent power conversion efficiency. Conventional crystalline silicon-based solar cells offer one of the most highly efficient power sources, but a key challenge remains to attain mechanical resilience while preserving electrical performance. A complementary metal oxide semiconductor-based integration strategy where corrugation architecture enables ultraflexible and low-cost solar cell modules from bulk monocrystalline large-scale (127 × 127 cm) silicon solar wafers with a 17% power conversion efficiency. This periodic corrugated array benefits from an interchangeable solar cell segmentation scheme which preserves the active silicon thickness of 240 μm and achieves flexibility via interdigitated back contacts. These cells can reversibly withstand high mechanical stress and can be deformed to zigzag and bifacial modules. These corrugation silicon-based solar cells offer ultraflexibility with high stability over 1000 bending cycles including convex and concave bending to broaden the application spectrum. Finally, the smallest bending radius of curvature lower than 140 μm of the back contacts is shown that carries the solar cells segments.
AB - Advanced classes of modern application require new generation of versatile solar cells showcasing extreme mechanical resilience, large-scale, low cost, and excellent power conversion efficiency. Conventional crystalline silicon-based solar cells offer one of the most highly efficient power sources, but a key challenge remains to attain mechanical resilience while preserving electrical performance. A complementary metal oxide semiconductor-based integration strategy where corrugation architecture enables ultraflexible and low-cost solar cell modules from bulk monocrystalline large-scale (127 × 127 cm) silicon solar wafers with a 17% power conversion efficiency. This periodic corrugated array benefits from an interchangeable solar cell segmentation scheme which preserves the active silicon thickness of 240 μm and achieves flexibility via interdigitated back contacts. These cells can reversibly withstand high mechanical stress and can be deformed to zigzag and bifacial modules. These corrugation silicon-based solar cells offer ultraflexibility with high stability over 1000 bending cycles including convex and concave bending to broaden the application spectrum. Finally, the smallest bending radius of curvature lower than 140 μm of the back contacts is shown that carries the solar cells segments.
UR - http://hdl.handle.net/10754/626892
UR - http://onlinelibrary.wiley.com/doi/10.1002/aenm.201702221/full
UR - http://www.scopus.com/inward/record.url?scp=85039766000&partnerID=8YFLogxK
U2 - 10.1002/aenm.201702221
DO - 10.1002/aenm.201702221
M3 - Article
SN - 1614-6832
VL - 8
SP - 1702221
JO - Advanced Energy Materials
JF - Advanced Energy Materials
IS - 12
ER -