1% at 0.4798 cm 2 , and 14.0% at 1.045 cm 2 , respectively, while the corresponding module efficiencies are 25.1% at 866.45 cm 2 , 24.4% at 13 177 cm 2 , 19.2% at 841 cm 2 , 19.0% at 23 573 cm 2 , and 12.3% at 14.322 cm 2 , respectively. [2-4] Silicon modules account for over 90% of the solar cell market share. [5] Although thin-film solar modules compete with silicon solar cells, the efficiency of the former is lower by ≈5 percentage points (%p). [2-4] Recently, a perovskite solar cell was reported, which used an organic metalhalide hybrid material with an ABX 3 perovskite crystal structure as the lightabsorbing layer. [6-8] This type of perovskite solar cell has attracted much attention as a next-generation solar cell. Kojima et al. first reported a perovskite solar cell with an efficiency of 3.8% in 2009. [9] Initially, perovskite solar cells did not receive much attention because of their poor stability and efficiency. However, research has increased since Park and co-workers reported an efficiency exceeding 9% with stability over 500 h in ambient conditions. [10,11] In the last six years, the efficiency of perovskite solar cells increased from 14.1% to 25.2%, which is the thirdhighest single-junction efficiency reported thus far. [2-4] However, perovskite solar cells are facing commercialization issues. For their successful application to the industry, the following problems must first be addressed: [12,13]-Upscaling (high-efficiency, large-area module demonstration)-Stability (performance degradation over times)-Toxicity (lead (Pb) and cesium (Cs) issues). Stability and toxicity problems were introduced relatively early in the literature. [10,11] Immense efforts were devoted to finding the origin of and solution to the degradation of perovskite solar cells. Owing to the dedicated efforts of countless researchers, the degradation factors were identified as the humidity, light, [14,15] heat, [16,17] and electric fields. [12,18] Degradation issues have been addressed with the development of stable perovskite compositions, electron-transfer layers (ETLs) and hole-transfer layers (HTLs), and encapsulations. Several groups have reported perovskite solar cells that passed the International Electrotechnical Commission (IEC) stability test, while Grätzel and co-workers reported a cell that remained stable for one year. [19-22] Thus, stability has been significantly improved. The status and problems of upscaling research on perovskite solar cells, which must be addressed for commercialization efforts to be successful, are investigated. An 804 cm 2 perovskite solar module has been reported with 17.9% efficiency, which is significantly lower than the champion perovskite solar cell efficiency of 25.2% reported for a 0.09 cm 2 aperture area. For the realization of upscaling high-quality perovskite solar cells, the upscaling and development history of conventional silicon, copper indium gallium sulfur/ selenide and CdTe solar cells, which are already commercialized with modules of sizes up to ≈25 000 cm 2 , are reviewed. ...
