Nano, Volume 09, Issue 05, July 2014.
In this paper, we have designed and synthesized four bithiazole-bridged sensitizers (BT-T2, TBT-T2, BT-T3 and TBT-T3) with triphenylamine and indoline as the donor segment and applied them to dye-sensitized solar cells (DSSCs). For triphenylamine-based sensitizers as BT-T2 and TBT-T2, adding one thiophene unit between triphenylamine donor and bithiazole moiety not only led to bathochromic shift of the maximum absorption and increase of molar extinction coefficient, but also enhanced the photovoltaic conversion efficiency from 7.12% of BT-T2 to 7.51% of TBT-T2. But for indoline-based sensitizers as BT-T3 and TBT-T3, adding one thiophene unit between indoline donor and bithiazole moiety resulted in hypochromatic shift instead of bathochromic shift. We employed the density functional theory (DFT) calculations to further investigate the influence of the thiophene unit on their optical and electronic properties and photovoltaic performance of corresponding DSSC devices. Given the results, a reasonable explanation is the introduction of thiophene unit suppressed the intramolecular charge transfer and charge separation in the conjugation system of indoline-based sensitizer, which led to the hypochromatic shift of the maximum absorption wavelength and finally the low Jsc. Since the Jsc dropped sharply from 15.26 mAcm-2 to 4.52 mAcm-2, the photovoltaic conversion efficiency decreased dramatically from 7.86% to 1.93%. In this paper, we investigated the effect of thiophene unit between donor and bithiazole bridge on the performance of DSSCs. The results showed that thiophene unit enhanced the photovoltaic conversion efficiency from 7.12% of BT-T2 to 7.51% of TBT-T2 for triphenylamine-based sensitizers, but decreased dramatically from 7.86% of BT-T3 to 1.93% of TBT-T3 for indoline-based sensitizers. The reason may be that the introduction of thiophene unit suppressed the intramolecular charge transfer in the conjugation system of indoline-based sensitizer, which led to the low Jsc.
XIAOYU ZHANG et al
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In this paper, we have designed and synthesized four bithiazole-bridged sensitizers (BT-T2, TBT-T2, BT-T3 and TBT-T3) with triphenylamine and indoline as the donor segment and applied them to dye-sensitized solar cells (DSSCs). For triphenylamine-based sensitizers as BT-T2 and TBT-T2, adding one thiophene unit between triphenylamine donor and bithiazole moiety not only led to bathochromic shift of the maximum absorption and increase of molar extinction coefficient, but also enhanced the photovoltaic conversion efficiency from 7.12% of BT-T2 to 7.51% of TBT-T2. But for indoline-based sensitizers as BT-T3 and TBT-T3, adding one thiophene unit between indoline donor and bithiazole moiety resulted in hypochromatic shift instead of bathochromic shift. We employed the density functional theory (DFT) calculations to further investigate the influence of the thiophene unit on their optical and electronic properties and photovoltaic performance of corresponding DSSC devices. Given the results, a reasonable explanation is the introduction of thiophene unit suppressed the intramolecular charge transfer and charge separation in the conjugation system of indoline-based sensitizer, which led to the hypochromatic shift of the maximum absorption wavelength and finally the low Jsc. Since the Jsc dropped sharply from 15.26 mAcm-2 to 4.52 mAcm-2, the photovoltaic conversion efficiency decreased dramatically from 7.86% to 1.93%. In this paper, we investigated the effect of thiophene unit between donor and bithiazole bridge on the performance of DSSCs. The results showed that thiophene unit enhanced the photovoltaic conversion efficiency from 7.12% of BT-T2 to 7.51% of TBT-T2 for triphenylamine-based sensitizers, but decreased dramatically from 7.86% of BT-T3 to 1.93% of TBT-T3 for indoline-based sensitizers. The reason may be that the introduction of thiophene unit suppressed the intramolecular charge transfer in the conjugation system of indoline-based sensitizer, which led to the low Jsc.
XIAOYU ZHANG et al
Click for full article
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