Charge photo-carrier transport from silicon nanocrystals embedded in SiO2-based multilayer structures

Abstract: Structural and optoelectronical characterization of Si -SiO 2 / SiO 2 multilayers with applications in all Si tandem solar cells J. Appl. Phys. 107, 064321 (2010) Experimental investigation of photoconductivity in Si-rich silicon oxide (SRSO)/SiO 2 multilayer (ML) structures prepared by magnetron reactive sputtering is reported. Photocurrent (PC) measurements show that the PC threshold increases with decreasing the thickness of SRSO layer. Photo-conduction processes in our samples are shown to be dominated by … Show more

“…Further, the role of Si inclusions in the observed features may be ruled out, as their expected response should come in the red region of the spectrum. 27 To elaborate further, if we consider the band gap of quantum confined Si (from Park et al 28 ), a sharp response is expected in the UV-blue region for a-Si inclusions having narrow size distribution of $1.5 nm. However, the films in the present case are partially phase separated with large variation of the sizes (2 to 10 nm) of the a-Si inclusions.…”

Narrow band photocurrent response from partially phase separated a-SiNx:H thin films

“…Further, the role of Si inclusions in the observed features may be ruled out, as their expected response should come in the red region of the spectrum. 27 To elaborate further, if we consider the band gap of quantum confined Si (from Park et al 28 ), a sharp response is expected in the UV-blue region for a-Si inclusions having narrow size distribution of $1.5 nm. However, the films in the present case are partially phase separated with large variation of the sizes (2 to 10 nm) of the a-Si inclusions.…”

Narrow band photocurrent response from partially phase separated a-SiNx:H thin films

“…However, photoexcited carrier transport and the number of generated Si QDs in this structure is restricted by the adjacent SiO 2 layer, which has a crucial impact on the efficiency of Si QD based photovoltaic cells. [8,13] Recently, we have fabricated Si QD heterojunction solar cells with 14.8% efficiency from a boron-doped single SiO x layer (SiO x :B) [14]. In addition, we have studied the importance of the B doping concentration for effective electronic band engineering of the absorption layer in Si QD heterojunction solar cells [15].…”

High efficiency Si quantum dot heterojunction solar cells using a single SiO_X:B layer

Progress on solution processed Si-nanoparticle solar cells towards new generation photovoltaics