Conjugated Polymers Bearing Iridium Complexes for Triplet Photovoltaic Devices

Schulz, Gisela L.; Holdcroft, Steven

doi:10.1021/cm800955f

Cited by 85 publications

(72 citation statements)

References 17 publications

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“…The MEH-PPV/C 60 bilayer photovoltaic device without PtOEP attained a short-circuit current ( J sc ) of 0.3 mA cm The enhanced photocurrent and power-conversion effi ciency in the PtOEP blended MEH-PPV/C 60 bilayer photovoltaic device can be attributed to the increased population of long-lived, mobile triplet excitons in the conjugated polymer, which is consistent with our PIA results and previously published data. [7][8][9][10][11][12][13][14][15] The long exciton diffusion length of the triplet excitons increases intersystem crossing effi ciency of MEH-PPV. Similar to our results, Cleave et al, reported that the enhanced triplet-exciton population of poly[(2-methoxy-5-(3,7-dimethyl)-octyloxy)-1,4-phenylenevinylene] (OC 1 C 10 -PPV) originated from the triplettriplet energy transfer from PtOEP to OC 1 C 10 -PPV.…”

Section: Resultsmentioning

confidence: 99%

“…[7][8][9][10][11][12][13][14][15] In general, these conjugated polymers with aromatic structure show weak spin-orbit coupling and thus limit the generation of triplet excitons. [ 16 ] Nonetheless, the tripletexciton density of these conjugated polymers could be enhanced by increasing the intersystem crossing (ISC) effi ciency [7][8][9] through spin-orbit coupling or triplet-triplet energy transfer [11][12][13][14] from the dopant to the conjugated polymer in the blended system.…”

Section: Introductionmentioning

confidence: 99%

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Triplet Exciton and Polaron Dynamics in Phosphorescent Dye Blended Polymer Photovoltaic Devices

Lee

Hwang

Byeon

et al. 2010

Adv Funct Materials

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The triplet exciton and polaron dynamics in phosphorescent dye (PtOEP) blended polymer (MEH‐PPV) photovoltaic devices are investigated by quasi‐steady‐state photo‐induced absorption (PIA) spectroscopy. According to the low‐temperature PIA and photoluminescence (PL) results, the increase in strength of the triplet‐triplet (T1‐Tn) absorption of MEH‐PPV in the blend system originates from the triplet‐triplet energy transfer from PtOEP to MEH‐PPV. The PtOEP blended MEH‐PPV/C60 bilayer photovoltaic device shows a roughly 30%–40% enhancement in photocurrent and power‐conversion efficiency compared to the device without PtOEP. However, in contrast to the bilayer device results, the bulk heterojunction photovoltaic devices do not show a noticeable change in photocurrent and power‐conversion efficiency in the presence of PtOEP. The PIA intensity, originating from the polaron state, is only slightly higher (within the experimental error), indicating that carrier generation in the bulk heterojunction is not enhanced in the presence of PtOEP. The rate and probability of the exciton dissociation between PtOEP and PCBM is much faster and higher than that of the triplet‐triplet energy transfer between PtOEP and MEH‐PPV.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Triplet Exciton and Polaron Dynamics in Phosphorescent Dye Blended Polymer Photovoltaic Devices

Lee

Hwang

Byeon

et al. 2010

Adv Funct Materials

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“…34 Furthermore, a 35 times higher of PCE was obtained in polymer/fullerene device by coordinating 50 mol% of Ir complex to conjugated backbone of poly(fluoreneco-phenylpyridine) due to the formation of the triplet state in Ir containing polymers. 41 Previously, we reported the conjugation of a triplet Ir complex (feed ratio: 1 mol%) to the famous high efficiency donor polymer PTB7. The PCE was found to be significantly increased compared to the Ir-free control polymer.…”

Section: Introductionmentioning

confidence: 99%

Enhanced power conversion efficiency in iridium complex-based terpolymers for polymer solar cells

et al. 2018

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By introducing various low concentrations of Iridium complexes to the famous donor polymer of PTB7-Th backbone, new heavy metal containing terpolymers have been demonstrated. When blended with PC 71 BM, an obvious increase of power conversion efficiency (PCE) is obtained in 1 mol% Ir containing polymer for different photovoltaic devices either using Ca or PDIN as cathode interface layers. The impact of molecular weight on the photovoltaic performance has been particularly considered by using three batches of control polymer PTB7-Th to ensure a fair and more convincing comparison. At similar molecular weight conditions (M n : 60 kg mol −1 , M w : 100-110 kg mol), the 1 mol% Ir containing PTB7-ThIr1/PC 71 BM blends exhibits enhanced PCE to 9.19% compared with 7.92% of the control PTB7-Th. Through a combination of physical measurement, such as optoelectrical characterization, GIWAXS and pico-second time-resolved photoluminescence, the enhancement are contributed from comprehensive factors of higher hole mobility, less bimolecular recombination and more efficient slow process of charge separation. 3-9 To improve the PCEs of OSCs, numerous strategies have been employed through materials innovation and device engineering. (i) The first and most important is to design and synthesize new suitable donor-acceptor (D-A) type conjugated oligomers or alternating copolymers with high optical absorption, low bandgap, relatively lower highest occupied molecular orbital (HOMO) energy levels and high hole mobility in order to function as good electron donors in BHJ OSCs. Among many different materials categories, fluorinated-thieno [3,4-b] thiophene-based PTB7 and PTB7-Th and derivatives have proven to be excellent candidates.3,10-13 (ii) To overcome the shortcomings of fullerenes, such as weak absorption in the solar spectrum range, limited structural and energy level variability as well as device instability of the most widely used fullerene acceptors, the exploration of high performance new non-fullerene electron acceptors which comprise electron-deficient building blocks with low-lying HOMO and lowest unoccupied molecular orbital energy levels, strong absorption and high electron mobilities finds increasing attention in the field of OSCs.14-19 (iii) The involvement of suitable anode or cathode interface materials to reduce the interfacial energy barriers and facilitate an efficient hole or electron extraction from the active layer have also been

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“…The use of organic materials in organic optoelectronic devices such as organic light emitting diodes (OLEDs), organic transistors, organic solar cells (OSCs) and organic-hybrid solar cells is an area of increasing research interest [1]. The advantages of using organic materials are reduced cost of fabrication, easy processing, large scale production and compatibility with flexible substrates [2][3][4].…”

Section: Introductionmentioning

confidence: 99%

Study of intersystem crossing mechanism in organic materials

Ompong

Singh

2015

Phys. Status Solidi C

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Intersystem crossing rate from singlet excited state to triplet excited state of an organic molecule has been derived using exciton‐spin‐orbit‐molecular vibration interaction as a perturbation operator. Incorporation of heavy metal atom enhances the spin‐orbit interaction and hence the intersystem crossing rate because it depends on the square of the heaviest atomic number. We found that in the presence of heavy atom the singlet‐triplet energy difference still plays an influential role in the intersystem crossing process. The derived exciton‐spin‐orbit‐molecular vibration interaction operator flips the spin of the singlet exciton to triplet exciton after photoexcitaion from the singlet ground state with the assistance of molecular vibrational energy. From this operator an expression for the intersystem crossing rate is derived and calculated in some organic solids. (© 2016 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)

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Conjugated Polymers Bearing Iridium Complexes for Triplet Photovoltaic Devices

Cited by 85 publications

References 17 publications

Triplet Exciton and Polaron Dynamics in Phosphorescent Dye Blended Polymer Photovoltaic Devices

Triplet Exciton and Polaron Dynamics in Phosphorescent Dye Blended Polymer Photovoltaic Devices

Enhanced power conversion efficiency in iridium complex-based terpolymers for polymer solar cells

Study of intersystem crossing mechanism in organic materials

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