Details

Autor(en) / Beteiligte

• Hacioglu, Serife O.
• Unlu, Naime A.
• Aktas, Ece
• Hizalan, Gonul
• Yildiz, Esra D.
• Cirpan, Ali
• Toppare, Levent

Titel

A triazoloquinoxaline and benzodithiophene bearing low band gap copolymer for electrochromic and organic photovoltaic applications

Ist Teil von

• Synthetic metals, 2017-06, Vol.228, p.111-119

Ort / Verlag

Lausanne: Elsevier B.V

Erscheinungsjahr

2017

Quelle

Alma/SFX Local Collection

Beschreibungen/Notizen

• •Combination of two acceptor units (benzotriazole and quinoxaline) which contribute imine bonds to the structure and a triazoloquinoxaline unit for enhancing electron accepting ability.•Ambipolar character with two well-defined redox couples in the n-doped state and multichromic behavior.•A wide absorption range in the visible region with a tail in the NIR region, which yields a low band gap of 1.2eV A new triazoloquinoxaline and benzodithiophene based copolymer was synthesized to investigate its electrochemical, optical and photovoltaic behaviors. According to the polymer design, combination of two acceptor units (benzotriazole and quinoxaline) which contribute imine bonds to the structure and a triazoloquinoxaline unit for enhancing electron accepting ability was pursued. As a result of electrochemical studies, the copolymer PTQBDT has a low lying HOMO energy level as −5.23eV which increases the chemical stability of the resulting polymer and leads to a higher Voc. In addition, the copolymer has an ambipolar character with two well-defined redox couples in the n-doped state and multichromic behavior. In the context of optical studies, PTQBDT has wide absorption range in the visible region with a tail in the NIR region, which yields a low band gap of 1.20eV. Organic photovoltaic devices were designed using PTQBDT (the electron donor) and PC71BM (the electron acceptor) for the preliminary studies. The resulting device exhibits a power conversion efficiency of 2.0% with a current density of 8.07mAcm−2, an open-circuit voltage of 0.45V, and a fill factor of 55%. The carrier mobility of the PTQBDT was calculated as 3.00×10−3cm2V−1s−1 via space-charge-limited current (SCLC) method.