Stability of push-pull small molecule donors for organic photovoltaics: spectroscopic degradation of acceptor endcaps on benzo[1,2-:4,5-′]dithiophene cores

High efficiency organic photovoltaic devices have relied on the development of new donor and acceptor materials to optimize opto-electronic properties, promote free carrier generation, and suppress recombination losses. With single junction efficiencies exceeding 15%, materials development must now...

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Bibliographic Details
Published in:Journal of materials chemistry. A, Materials for energy and sustainability Materials for energy and sustainability, 2019-08, Vol.7 (34), p.19984-19995
Main Authors: Watts, Kristen E, Nguyen, Trung, Tremolet de Villers, Bertrand J, Neelamraju, Bharati, Anderson, Michael A, Braunecker, Wade A, Ferguson, Andrew J, Larsen, Ross E, Larson, Bryon W, Owczarczyk, Zbyslaw R, Pfeilsticker, Jason R, Pemberton, Jeanne E, Ratcliff, Erin L
Format: Article
Language:English
Subjects:
Acceptor materials
Bleaching
Carrier recombination
Chromophores
Cores
Degradation
Density functional theory
Donors (electronic)
Dynamic stability
Efficiency
Electronics industry
Functional groups
Insulators
Optoelectronics
Organic chemistry
Photobleaching
Photodegradation
Photoelectrons
Photovoltaic cells
Photovoltaics
Properties (attributes)
Recombination
Redox properties
Ring opening
Solar cells
Time dependence
White light
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Summary:High efficiency organic photovoltaic devices have relied on the development of new donor and acceptor materials to optimize opto-electronic properties, promote free carrier generation, and suppress recombination losses. With single junction efficiencies exceeding 15%, materials development must now target long-term stability. This work focuses on the photobleaching dynamics and degradation chemistries of a class of small molecule donors inspired by benzodithiophene terthiophene cores (BDT-3T) with rhodanine endcaps, which have demonstrated 9% efficiency in single junction devices and >11% in ternary cells. Density functional theory was used to design three additional molecules with similar synthetic pathways and opto-electronic properties by simply changing the electron accepting endcap to benzothiazoleacetonitrile, pyrazolone, or barbituric acid functional groups. This new class of semiconductors with equivalent redox properties enables systematic investigation into photobleaching dynamics under white light illumination in air. Degradation chemistries are assessed via unique spectroscopic signatures for the BDT-3T cores and the endcaps using photoelectron spectroscopies. We show that the pyrazolone undergoes significant degradation due to ring opening, resulting in complete bleaching of the chromophore. The barbituric and rhodanine endcap molecules have moderate stability, while the benzothiazoleacetonitrile group produces the most stable chromophore despite undergoing some oxidative degradation. Collectively, our results suggest the following: (i) degradation is not just dependent on redox properties; (ii) core group stability is not independent of the endcap choice; and (iii) future design of high efficiency materials must consider both photo and chemical stability of the molecule as a whole, not just individual donor or acceptor building blocks. Degradation pathways of small molecule donors for organic photovoltaics are shown to be dependent on chemical traits and not just redox properties.
ISSN:2050-7488
2050-7496
DOI:10.1039/c9ta06310b