Effects of Copper Substitution in Methylammonium-Based Perovskite Solar Cells †

: Addition of copper bromide to the perovskite precursor solutions increased the conversion efficiencies of the devices. On the other hand, the short-circuit current densities decreased with increasing the added amounts of copper (Cu). From first-principles calculations, partial substitution of lead with Cu resulted in the formation of a Cu d orbital energy level in the forbidden band, which worked as a recombination center, causing the generated carriers to disappear. Experiments and calculations show the effects of Cu substitution on the electronic structures and the ability of the addition of Cu compounds to further improve the device performance.

In this study, the effects of the addition of Cu compounds to the perovskite precursor solution and the substitution of Pb with Cu on the device properties and electronic structure were investigated [39].The amount of Cu added was varied in the range of 0, 1, 2, 3 and 12.5%, and current-voltage characterization and X-ray diffraction measurements were performed.In addition, first-principles calculations were performed to determine the effect of Cu substitution in methylammonium-based perovskite crystals from the band structure and partial density of states.

Device Fabrication and Computational Conditions
The structure of the fabricated perovskite solar cell is fluorine doped tin oxide glass/compact TiO2/mesoporous TiO2/CH3NH3PbI3/spiro-OMeTAD/Au.CuBr2 was used as the Cu compound to be added to the perovskite precursor solution, with 0% Cu as the standard device and different Cu additions in the range of 1, 2, 3 and 12.5%.The details of the experimental methods are described in the previous papers [35].A 2 × 2 × 2 supercell was built and one of the eight B-sites was substituted with Cu to produce a structural model of MAPb0.875Cu0.125I3.The energy gap and carrier effective mass were calculated from the band structure, and information on orbitals was obtained from the partial density of states (pDOS).The details of the calculation method are described in the previous papers [39].

Results and Discussion
Figure 1 shows the cell parameters as a function of the amount of Cu compound added to the perovskite precursor solution.Table 1 shows the values of the cell parameters obtained from the current-voltage characterization.The highest open circuit voltage (VOC) and fill factor (FF) were obtained when 2% Cu was added, and the conversion efficiency was higher than standard devices.The short-circuit current density (JSC) tended to decrease with increasing Cu addition, and the conversion efficiency decreased compared to the standard device when the Cu content exceeded 2%.Table 2 shows the results of the X-ray diffraction pattern analysis.The crystallite size increased with the addition of Cu to the precursor solution, with 2% Cu showing the highest conversion efficiency and the highest perovskite (100) plane orientation.The increase in the lattice parameter with the addition of small amounts of Cu was attributed to lattice distortion due to Cu substitution.For 12.5% Cu, the ionic radius of Cu is smaller than that of Pb, so the lattice shrank as more Cu was incorporated into the perovskite crystals.First-principles calculations were performed to investigate the cause of the decrease in JSC with increasing Cu addition.Figure 2 shows the calculated band structure and density of partial states.Table 3 shows the values of the parameters obtained from the firstprinciples calculations.From Figure 2c, the valence and conduction bands are composed of I p and Pb p orbitals, respectively.When Pb is partially substituted by Cu, the band gap decreases due to the lower energy of the Pb p orbital.Furthermore, an energy level of the Cu d orbital was formed in the forbidden band.Considering the experimental results, the energy level of the Cu d orbital worked as a defect level, causing the loss of the generated carriers and the reduction of the JSC.In the absence of Cu, electrons are excited from the I p orbital to the Pb p orbital.In the presence of Cu, electrons can be excited from the I p orbital to the Cu d or Pb p orbital, resulting in two patterns of excitation processes.Despite the increase in the excitation probability, the decrease in device properties with increasing Cu addition means that it is difficult to extract electrons excited from the I p orbital and trapped in the Cu d orbital as charge carriers.Experimental and computational results indicate that Cu substitution has a negative effect on the electronic structure and that the defect levels formed in the forbidden bands reduce the JSC.Therefore, the enhancement of device properties by the addition of Cu compounds to the precursor solution is attributed to improvements in the microstructure of the perovskite film, such as an increase in crystallite size and perovskite crystal (100) plane orientation.

Conclusions
The addition of 2% Cu to the perovskite precursor solution improved the VOC and FF and enhanced the conversion efficiency of the device.The calculated band structure and density of partial states indicate that the substitution of Pb for Cu has a negative effect on the electronic structure, with the formation of Cu d-orbital energy levels in the forbidden band causing carrier recombination and lowering the JSC.Therefore, it is difficult to adopt Cu as a replacement element for Pb, but the addition of small amounts of Cu compounds to the perovskite precursor solution was shown to contribute to further enhancement of device properties.

Figure 1 .
Figure 1.Cell parameters as a function of the amount of Cu compound added to the perovskite precursor solution.

Table 1 .
Device properties of perovskite solar cells.

Table 2 .
Parameters obtained from X-ray diffraction measurements.

Table 3 .
Parameters obtained from first-principles calculations.