Ka Lai Wong1,Chujun Zhang1,Zhuoqiong Zhang1,Mingwei Hao1,Yuanyuan Zhou1,Shu Kong So1
Hong Kong Baptist University1
Ka Lai Wong1,Chujun Zhang1,Zhuoqiong Zhang1,Mingwei Hao1,Yuanyuan Zhou1,Shu Kong So1
Hong Kong Baptist University1
Solar cells have penetrated many cities as Building Integrated Photovoltaic (BIPV) or the energy source for standalone Internet of Things (IoT) devices. Traditionally, photovoltaic (PV) cells are evaluated using 1 sun irradiance. However, in a city, factors such as air pollution, cloudiness and cell installation orientation may attenuate the receivable solar energy. Also, the power conversion efficiency (PCE) of a PV cell is highly irradiance-dependent. Evaluating urban outdoor PV cells using 1 sun irradiance could lead to inaccurate prediction of PCE and overestimated output power in actual usage. Herein, we analyzed daytime irradiances of 11 cities located across the globe. Our results show that realistic irradiances (RI) in most cities are between 0.01 and 0.5 sun, reflecting the irradiance under a cloudy to mostly sunny sky. Under such an RI window, the PCEs of 9 different PV technologies were compared. 7 PV technologies have compromised performance. 2 PV technologies, organic and perovskite PVs, show enhanced PCE under the RI window and are favorable for urban outdoor applications. The tested perovskite PV reached 21% PCE while the non-fullerene-based organic solar cell has improved to 18% PCE under a cloudy sky. The potential of powering IoT devices with these PV technologies under sub-optimal irradiance conditions in cities is also highlighted.