Thermal-Driven Phase Separation of Double-Cable Polymers Enables Efficient Single-Component Organic Solar Cells

Feng G, Li J, He Y, Zheng W, Wang J, Li C, Tang Z, Osvet A, Li N, Brabec C, Yi Y, Yan H, Li W (2019)


Publication Language: English

Publication Type: Journal article

Publication year: 2019

Journal

Book Volume: 3

Pages Range: 1765-1781

Journal Issue: 7

DOI: 10.1016/j.joule.2019.05.008

Abstract

Conventional organic solar cells (OSCs) need two components that function as donor and acceptor, respectively. Although there has been wishful thinking about constructing OSCs based on a single component, it is generally believed to be highly challenging to achieve efficient single-component OSCs (SCOSCs). In this work, we design a new double-cable conjugated polymer containing a strongly crystalline backbone as donor and aromatic side units as acceptor. With a high annealing temperature (230°C), both the backbones and perylene bisimide side units could self-organize into ordered nanostructures. This enables efficient charge transport and low charge recombination, resulting in a record efficiency of 6.3% in SCOSCs. The cells also exhibit excellent stability, with >90% efficiency retention over 300 h of continuous one-sun illumination. These results suggest that the concept of SCOSCs is highly promising, especially to overcome the limitations of conventional OSCs toward industrial application.

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APA:

Feng, G., Li, J., He, Y., Zheng, W., Wang, J., Li, C.,... Li, W. (2019). Thermal-Driven Phase Separation of Double-Cable Polymers Enables Efficient Single-Component Organic Solar Cells. Joule, 3(7), 1765-1781. https://doi.org/10.1016/j.joule.2019.05.008

MLA:

Feng, Guitao, et al. "Thermal-Driven Phase Separation of Double-Cable Polymers Enables Efficient Single-Component Organic Solar Cells." Joule 3.7 (2019): 1765-1781.

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