Morphological and electrical control of fullerene dimerization determines organic photovoltaic stability

Heumüller T, Mateker WR, Distler A, Fritze UF, Cheacharoen R, Nguyen WH, Biele M, Salvador MF, von Delius M, Egelhaaf HJ, Mcgehee MD, Brabec C (2016)

Publication Language: English

Publication Status: Published

Publication Type: Journal article, Original article

Publication year: 2016

Journal

Energy and Environmental Science Royal Society of Chemistry

Book Volume: 9

Pages Range: 247-256

Journal Issue: 1

DOI: 10.1039/c5ee02912k

Abstract

Fullerene dimerization has been linked to short circuit current (J) losses in organic solar cells comprised of certain polymer-fullerene systems. We investigate several polymer-fullerene systems, which present J loss to varying degrees, in order to determine under which conditions dimerization occurs. By reintroducing dimers into fresh devices, we confirm that the photo-induced dimers are indeed the origin of the J loss. We find that both film morphology and electrical bias affect the photodimerization process and thus the associated loss of J. In plain fullerene films, a higher degree of crystallinity can inhibit the dimerization reaction, as observed by high performance liquid chromatography (HPLC) measurements. In blend films, the amount of dimerization depends on the degree of mixing between polymer and fullerene. For highly mixed systems with very amorphous polymers, no dimerization is observed. In solar cells with pure polymer and fullerene domains, we tune the fullerene morphology from amorphous to crystalline by thermal annealing. Similar to neat fullerene films, we observe improved light stability for devices with crystalline fullerene domains. Changing the operating conditions of the investigated solar cells from V to J also significantly reduces the amount of dimerization-related J loss; HPLC analysis of the active layer shows that more dimers are formed if the cell is held at V instead of J. The effect of bias on dimerization, as well as a clear correlation between PL quenching and reduced dimerization upon addition of small amounts of an amorphous polymer into PC60BM films, suggests a reaction mechanism via excitons.

Authors with CRIS profile

Thomas Heumüller Institute Materials for Electronics and Energy Technology (i-MEET) Andreas Distler Institute Materials for Electronics and Energy Technology (i-MEET) Michael Filipe Salvador Institute Materials for Electronics and Energy Technology (i-MEET) Max von Delius Lehrstuhl für Organische Chemie II Christoph Brabec Institute Materials for Electronics and Energy Technology (i-MEET)

Additional Organisation(s)

Exzellenz-Cluster Engineering of Advanced Materials

Involved external institutions

Stanford University US United States (USA) (US) BELECTRIC OPV GmbH DE Germany (DE)

How to cite

APA:

Heumüller, T., Mateker, W.R., Distler, A., Fritze, U.F., Cheacharoen, R., Nguyen, W.H.,... Brabec, C. (2016). Morphological and electrical control of fullerene dimerization determines organic photovoltaic stability. Energy and Environmental Science, 9(1), 247-256. https://dx.doi.org/10.1039/c5ee02912k

MLA:

Heumüller, Thomas, et al. "Morphological and electrical control of fullerene dimerization determines organic photovoltaic stability." Energy and Environmental Science 9.1 (2016): 247-256.

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