Direct evidence of chemically inhomogeneous, nanostructured, Si-O buried interfaces and their effect on the efficiency of carbon nanotube/Si photovoltaic heterojunctions
Del Gobbo, Silvano
Scarselli, Manuela A.
De Crescenzi, Maurizio
Online Publication Date2013-08-29
Print Publication Date2013-09-12
Permanent link to this recordhttp://hdl.handle.net/10754/577043
MetadataShow full item record
AbstractAn angle resolved X-ray photoemission study of carbon nanotube/silicon hybrid photovoltaic (PV) cells is reported, providing a direct probe of a chemically inhomogeneous, Si-O buried interface between the carbon nanotube (CNT) networked layer and the n-type Si substrate. By changing the photoelectron takeoff angle of the analyzer, a nondestructive in-depth profiling of a CNT/SiOx/SiO2/Si complex interface is achieved. Data are interpreted on the basis of an extensive modeling of the photoemission process from layered structures, which fully accounts for the depth distribution function of the photoemitted electrons. As X-ray photoemission spectroscopy provides direct access to the buried interface, the aging and the effects of chemical etching on the buried interface have been highlighted. This allowed us to show how the thickness and the composition of the buried interface can be related to the efficiency of the PV cell. The results clearly indicate that while SiO2 is related to an increase of the efficiency, acting as a buffer layer, SiOx is detrimental to cell performances, though it can be selectively removed by etching in HF vapors. © 2013 American Chemical Society.
CitationPintossi, C., Salvinelli, G., Drera, G., Pagliara, S., Sangaletti, L., Gobbo, S. D., … Castrucci, P. (2013). Direct Evidence of Chemically Inhomogeneous, Nanostructured, Si–O Buried Interfaces and Their Effect on the Efficiency of Carbon Nanotube/Si Photovoltaic Heterojunctions. The Journal of Physical Chemistry C, 117(36), 18688–18696. doi:10.1021/jp404820k
SponsorsThe Roma Tor Vergata group acknowledges the financial support of the European Office of Aerospace Research and Development (EOARD) through Air Force Office of Scientific Research Material Command, USAF, under Grant No. FA8655-11-1-3036.
PublisherAmerican Chemical Society (ACS)