Fundamentals of Solar Cell Design. Rajender Boddula

Fundamentals of Solar Cell Design - Rajender Boddula


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href="#ulink_77f11440-d779-5e3b-9e56-c02e12038b10">Figure 3.4 Fabricated 3-TGaAsP on SiGe/Si device. (Reprinted with the permission from reference [37].)

Schematic illustration of the GaAs nanowire-on-Si tandem solar cell.

      Colin D. Bailie et al. established semi-transparent cell onto CIGS and poor class multicrystalline Si to attain solid-state polycrystalline TSC efficiency above 25% [47]. Miguel Anaya and coauthors proposed a new tandem structural design in which both top and bottom cells are made of absorbers and devices shows the efficiencies at 35% [48]. Jiadong Qian et al. reported different degradation rates of perovskite cells and silicon cells in a tandem solar module degradation. PCE of 28.7% and 27.6% enable the economic viability of two- and four-terminal modules [49]. Alexander J. Bett et al. developed semi-transparent PSE in the regular n-i-p structure, which is presented with ITO directly sputtered on the hole conducting material Spiro-OMeTAD and showed efficiency of 14.8% [50].

Schematic illustration of (a) Absorption of thin films. (b) Normalized absorbance with respect of time.

      Figure 3.9 Schematic arrangement of the cell and its I-V characterstics. (Reprinted with the permission from reference in CC licenses [50].)

Schematic illustration of the J-V characteristics (a) J-V of CIGSe single-junction. (b) Perovskite single junction reference cell with different HTLs.

      Jialong Duan et al. fabricated FAPbX3 perovskite nanocrystals, high-melting-point ligands to modify the perovskite/carbon interface in allinorganic CsPbBr3 PSC, which are efficient PV device, and elevated PCE up to 8.55% is achieved [59]. Shichong et al. reported ICO transparent electrode with high mobility of 51.6 cm2/Vs, a low resistivity of 5.74 × 10−4 Ωcm and transmittance of 83.5%. The SHJ two-terminal TSC gets 8.06% step up in PCE from 18.85% to 20.37% [60]. Jian Liu et al. reported a two-terminal perovskite (PVSK)–organic HTSC and PFN/doped MoO3/MoO3 structure as interconnection layer (ICL). The HTSC attains VOC of 1.58V and FF of 0.68 [61].

Schematic illustration of the structure of CH3 NH3 SnxPb(1 − x)I3 PSC.

      Figure 3.12 I-V curves for CH3NH3SnxPb(1 − x)I3 PSC. (Reprinted with the permission from reference [58].)

Schematic illustration of the IPCE curves for CH3 NH3 SnxPb(1 − x)I3.
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