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Beilstein J. Nanotechnol. 2018, 9, 2114–2124, doi:10.3762/bjnano.9.200
Figure 1: Development of Sb2S3 technology. Solar cells with extremely thin absorber architecture [1-6,29] reach the h...
Figure 2: SEM images of Sb2S3 thin films after crystallization at 265 °C. Direct thermal decomposition of the...
Figure 3: Crystallization in the Sb-TU (a–d) and Sb-BDC (e–h) process. AFM measurements of the Sb-TU route sh...
Figure 4: Chemical structure of the applied polymers (a). Sun simulator (b) and external quantum efficiency (...
Figure 5: Limitations of different Sb2S3 technologies (same data and color code as in Figure 1) and other absorber ma...
Beilstein J. Nanotechnol. 2013, 4, 180–188, doi:10.3762/bjnano.4.18
Figure 1: (a) Current–voltage curves of a device with and without charged acceptor-like defects with a total ...
Figure 2: (a) Current–voltage curves of a device with charged acceptor-like defects and a built-in voltage Vbi...
Figure 3: Normalized mobility obtained by fitting the Murgatroyd equation to the simulated current–voltage cu...
Figure 4: Normalized mobility as a function of defect concentration if the built-in voltage in Equation 8 is set to 0. ...
Figure 5: Comparison of the characteristic energy Ech,fit obtained by fitting Equation 10 to simulated current–voltage c...