Summary: | Double quantum dots (DQDs) have emerged as versatile and efficient absorbing light devices owing to their more adjusting parameters than the single QD’s. Using the system-reservoir theory, tunneling effect on the quantum photovoltaic properties is explored detailedly in a DQDs photocell. The results show that the quantum photovoltaic yields evaluated by the short-circuit current, open-circuit voltage and output power, are greatly enhanced by the electron tunneling effect between two adjacent QDs. Not only that, further discussion reveals that the redistribution of carriers due to the tunneling effect is responsible for the efficient quantum photovoltaic properties. And the robust tunneling effect can greatly reduce the passive impact caused by the energy mismatch, the role difference between the ambient temperature and tunneling effect is also clarified in the photovoltaic properties. Insights into tunneling effect between two adjacent QDs not only reveal the microscopic carriers transporting regime, but also may inspire some artificial strategies for efficient assembled QD arrays photocell in the future.
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