Under illumination, CB-839 cost the electrons and holes are generated in the SCNT film and the Si substrate. They are collected by the built-in voltage V d at the junction, where holes and electrons are directed to the SCNT film and the n-Si substrate, respectively. Thus, the formation of the charge accumulation layer on both the sides can reduce the built-in potential, and the reduced potential is equal to the V OC. Thereby, the V OC depends on the built-in potential height of the junction V d. Thus, the higher built-in potential height generates the higher V OC under illumination, which can
increase the power conversion efficiency of the cell. Figure 6 Energy band diagram of the SCNT/n-Si heterojunction solar cell. Dashed-dotted red line, hν; blue circle, electron. In order to better understand the effect of Au doping on the carrier Stattic price density and mobility of the SCNT, Hall effect measurements were performed for the SCNT film deposited on a glass substrate at room temperature. The Hall effect measurements revealed that the SCNT networks were all p-types conductivity before and after Au doping. After doping,
an average carrier density for the SCNT film increased from 5.3 × 1018 to 1.4 × 1020 cm−3. This enhanced carrier density is advantageous for SCNT/n-Si SHP099 photovoltaic devices because p doping and the reduced resistivity are in favor of charge collection and preventing carriers from recombination. The gold-hybridization SCNT can provide more charge transport paths, resulting in improved cell PCE PIK-5 more than three folds. Recent studies
showed that doping also decreased the tunneling barrier between SCNT and concluded that this is the major fact in the overall film resistance [45–47]. So the devices series resistance (Rs) dropped from 218 Ω (or 8.72 Ω·cm2) in the SCNT/Si cell to 146 Ω (or 5.84 Ω·cm2) in the gold-hybridization SCNT-Si cell. The effect of the immersion time of SCNT in HAuCl4·H2O solution on the photovoltaic characteristics of the device was investigated. The relative data are shown in the Table 1. It can be seen that with increasing immersion time, the PCE increases. But if the immersion time is too long, the efficiency of the device decreases, although the increasing absorbs of light increases (Figure 5b). Larger particles along with larger surface coverage lead to increased parasitic absorption and reflection, reducing the desired optical absorption in SCNT film layer [48]. In addition, the particles embedded between SCNT and Si substrate will reduce the density of p-n junction and lead to a significantly decrease shunt resistance; therefore, the J SC and P CE decrease. This means that too many Au nanoparticles and very large particles covering on the SCNT will reduce their device PCE.
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