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- Title
A Cost Analysis of Fully Solution‐Processed ITO‐Free Organic Solar Modules.
- Authors
Guo, Jie; Min, Jie
- Abstract
Organic photovoltaics (OPVs) have become a potential candidate for clean and renewable photovoltaic productions. This work examines the current cost drivers and potential avenues to reduce costs for organic solar modules by constructing a comprehensive bottom‐up cost model. The direct manufacturing cost (MC) and the minimum sustainable price (MSP) for an opaque single solar module (SSM) (MC = 187 ¥ m−2, MSP = 297 ¥ m−2) and for a tandem solar module (MC = 224 ¥ m−2, MSP = 438 ¥ m−2) are analyzed in detail. Within this calculation, the most expensive layers and processing steps are identified and highlighted. Importantly, the low levelized cost of energy (LCOE) value for an SSM with a 10% power conversion efficiency in a 20‐year range from 0.185 to 0.486 ¥ kWh−1, with a national average of 0.324 ¥ kWh−1 in China under an average solar irradiance of 1200 kWh m−2 year−1. Moreover, the impact on the cost of alternative materials and constructions, process throughputs, module efficiency, and module lifetime, etc., is presented and avenues to further reduce the MSP and LCOE values are indicated. The analysis shows that OPVs can emerge as a competitive alternative to established power generation technologies if the remaining issues (e.g., active layer material cost, module efficiency, and lifetime) can be resolved. Current cost drivers and potential avenues to reduce cost for organic solar modules by constructing a comprehensive bottom‐up cost model are examined. Moreover, the impact on the cost of alternative materials and constructions, process throughputs, module efficiency, and module lifetime, etc. is presented, and avenues for the further reduction of the minimum sustainable price and levelized cost of energy values are discussed.
- Subjects
INDIUM tin oxide; PHOTOVOLTAIC power systems; POTENTIAL theory (Physics); SOLUTION (Chemistry); ENERGY conservation; ENERGY consumption
- Publication
Advanced Energy Materials, 2019, Vol 9, Issue 3, pN.PAG
- ISSN
1614-6832
- Publication type
Article
- DOI
10.1002/aenm.201802521