Title :
High efficiency quadruple junction, four-terminal solar cells and modules by transfer printing
Author :
Xing Sheng ; Bower, Christopher A. ; Bonafede, Salvatore ; Wilson, John W. ; Fisher, Brent ; Meitl, Matthew ; Yuen, Homan ; Shuodao Wang ; Ling Shen ; Banks, Anthony R. ; Corcoran, Christopher J. ; Nuzzo, Ralph G. ; Burroughs, Scott ; Rogers, John A.
Author_Institution :
Dept. of Mater. Sci. & Eng., Univ. of Illinois at Urbana-Champaign, Urbana, IL, USA
Abstract :
Conventional multi-junction (MJ) cells are limited by requirements in epitaxial growth and current-matching. Mechanically stacked MJ cells circumvent these disadvantages, but existing approaches lack scalable manufacturing processes and suitable interfaces between the stacked cells. Here we present materials and strategies designed to bypass these limitations. The schemes involve (1) printing of microscale solar cells, (2) advanced optical/electrical/thermal interface materials and (3) packaging techniques, electrical matching networks, and compact ultrahigh concentration optics. We demonstrate quadruple junction, four-terminal solar cells with measured efficiencies of 43.9% at concentrations exceeding 1000 suns, and modules with efficiencies of 36.5%.
Keywords :
epitaxial growth; manufacturing processes; packaging; printing; solar cells; MJ cells circumvent; advanced optical-electrical-thermal interface materials; compact ultrahigh concentration optics; electrical matching networks; epitaxial growth; manufacturing processes; multijunction cells; packaging techniques; quadruple junction four-terminal solar modules; quadruple junction, four-terminal solar cells; transfer printing; Educational institutions; Gallium arsenide; Junctions; Photovoltaic cells; Printing; Sun; mechanical stack; multijunction; photovoltaic cells; transfer printing;
Conference_Titel :
Photovoltaic Specialist Conference (PVSC), 2014 IEEE 40th
Conference_Location :
Denver, CO
DOI :
10.1109/PVSC.2014.6924886
