Physical device simulation of partial dopant-free asymmetric silicon heterostructure solar cell (P-DASH) based on hole-selective Molybdenum oxide (MoOx) with Crystalline Silicon (cSi)

“…Thin films of MoO x can be deposited by several simple fabrication methods, at room or low processing temperature (<200°C), such as thermal evaporation, 8,25,26 atomic layer deposition (ALD), 27 sputtering, 28 or solution process technique 29 . Our simulation studies, using Silvaco TCAD tool, have demonstrated that high‐efficiency values of ~22% and ~25% can be achieved by placing MoO x at the rear (back surface field) 30 and front side (emitter), 31 respectively, of SHJ solar cells based on n‐type c‐Si wafers. Moreover, thin films of MoO x have been integrated into the fabrication of dopant‐free asymmetric heterocontacts (DASH) solar cells 6,11 ; 19.42% efficiency was reported for DASH solar cells on n‐type c‐Si wafer with MoO x and lithium fluoride (LiF) as hole and electron‐selective contacts placed at the front and rear side, respectively 11 .…”

On the application of hole‐selective MoO_x as full‐area rear contact for industrial scale p‐type c‐Si solar cells

“…Thin films of MoO x can be deposited by several simple fabrication methods, at room or low processing temperature (<200°C), such as thermal evaporation, 8,25,26 atomic layer deposition (ALD), 27 sputtering, 28 or solution process technique 29 . Our simulation studies, using Silvaco TCAD tool, have demonstrated that high‐efficiency values of ~22% and ~25% can be achieved by placing MoO x at the rear (back surface field) 30 and front side (emitter), 31 respectively, of SHJ solar cells based on n‐type c‐Si wafers. Moreover, thin films of MoO x have been integrated into the fabrication of dopant‐free asymmetric heterocontacts (DASH) solar cells 6,11 ; 19.42% efficiency was reported for DASH solar cells on n‐type c‐Si wafer with MoO x and lithium fluoride (LiF) as hole and electron‐selective contacts placed at the front and rear side, respectively 11 .…”

On the application of hole‐selective MoO_x as full‐area rear contact for industrial scale p‐type c‐Si solar cells

“…In ref. 77 and 78 the authors verified that the simulated and experimental values for the solar cell characteristics are approximately the same. The authors simulated and fabricated SHJ-p-type aSi:H and measured the open circuit voltage, short circuit current, fill factor and efficiency.…”

Fourth-generation solar cells: a review

“…This inversion layer enables the transport of holes from the c-Si layer to the MoO x layer, while hindering the transport of electrons. Such an effect has been demonstrated in simulation results, where tuning the WF from 4.5 eV to 5.7 eV resulted in an increase in efficiency from 1.62% to 23.32% [122]. MoO x is a TMO typically dominated by oxygen vacancy defects, and the WF of the film decreases as the oxygen vacancy concentration increases.…”

Surface Cleaning and Passivation Technologies for the Fabrication of High-Efficiency Silicon Heterojunction Solar Cells