Dual Bilayer for Improving Contact Quality and Passivation Enables Efficient Organic/Planar-Si Hybrid Solar Cells with a Champion V_OC of over 656 mV

Abstract: The contact quality between Si and the rear electrode and the passivation of Si play crucial roles in efficient organic/Si hybrid solar cells, especially for the open-circuit voltage (V OC ). Herein, we reported a dual bilayer structure to synergistically improve both rear contact quality and passivation of Si to enhance the performance of organic/planar-Si hybrid solar cells. Series resistance (R S ) extracted by the double diode model, contact quality explored by the Cox and Strack (CS) method, and the work … Show more

“…A τ m of 92.8 µs was fitted with a mono‐exponential decay from the decay curve of photovoltage, as shown in Figure 4b. Such a long minority carrier lifetime approaches that of crystalline silicon [ 37 ] and far surpasses that of halide perovskite single crystals. [ 38 ] Meanwhile, the BSATO method can effectively reduce defect density ( n trap ), which can be determined by the trap‐filled limit voltage using the following equation, according to the space‐charge‐limited current model [ 39 ] where ε 0 represents the vacuum permittivity, ε r the relative dielectric constant (ε r = 7.6), V TFL the onset voltage of the trap‐filled limit region, q the elementary charge (1.6 × 10 −19 C), and L (300 µm) the thickness of Cu 2 O.…”

Quasi‐Single Crystalline Cuprous Oxide Wafers via Stress‐Assisted Thermal Oxidation for Optoelectronic Devices

“…A τ m of 92.8 µs was fitted with a mono‐exponential decay from the decay curve of photovoltage, as shown in Figure 4b. Such a long minority carrier lifetime approaches that of crystalline silicon [ 37 ] and far surpasses that of halide perovskite single crystals. [ 38 ] Meanwhile, the BSATO method can effectively reduce defect density ( n trap ), which can be determined by the trap‐filled limit voltage using the following equation, according to the space‐charge‐limited current model [ 39 ] where ε 0 represents the vacuum permittivity, ε r the relative dielectric constant (ε r = 7.6), V TFL the onset voltage of the trap‐filled limit region, q the elementary charge (1.6 × 10 −19 C), and L (300 µm) the thickness of Cu 2 O.…”

Quasi‐Single Crystalline Cuprous Oxide Wafers via Stress‐Assisted Thermal Oxidation for Optoelectronic Devices

Inaccuracies in contact resistivity from the Cox–Strack method: A review