From non-doped to dopable: The impact of methoxy functionalization on doping and thermoelectric properties of conjugated polymers

Hansol Lee; Landep Ayuningtias; Hoimin Kim; Jaehoon Lee; Jiyun Lee; Min-Jae Kim; Dongki Lee; Byung Mook Weon; Dong-Am Park; Nam-Gyu Park; Sung Yun Son; Junki Kim; Yun-Hi Kim; Boseok Kang

doi:10.1002/eom2.12442

EcoMat ›› 2024, Vol. 6 ›› Issue (4) : e12442. DOI: 10.1002/eom2.12442

RESEARCH ARTICLE

From non-doped to dopable: The impact of methoxy functionalization on doping and thermoelectric properties of conjugated polymers

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Abstract

The introduction of alkoxy side chains into the backbone of conjugated polymers is an effective way to change their properties. While the impact on the structure and optoelectronic properties of polymer thin films was well-studied in organic solar cells and transistors, limited research has been conducted on their effects on doping and thermoelectric properties. In this study, the effects of methoxy functionalization of conjugated backbones on the doping and thermoelectric properties are investigated through a comparative study of diketopyrrolopyrrole-based conjugated polymers with and without methoxy groups (P29DPP-BTOM and P29DPP-BT, respectively). Methoxy-functionalization significantly enhances doping efficiency, converting undopable pairs to dopable ones. This dramatic change is attributed to the structural changes in the polymer film caused by the methoxy groups, which increases the lamellar spacing and facilitates the incorporation of dopants within the polymer crystals. Moreover, methoxy-functionalization is advantageous in improving the Seebeck coefficient and power factor of the doped polymers, because it induces a bimodal orientational distribution in the polymer, which contributes to the increased splitting of Fermi and charge transport levels. This study demonstrates the impact of methoxy-functionalization of a conjugated polymer on doping behavior and thermoelectric properties, providing a guideline for designing high-performance conjugated polymers for thermoelectric applications.

Keywords

conjugated polymers / doping efficiency / methoxy functionalization / molecular doping / organic thermoelectrics

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Hansol Lee, Landep Ayuningtias, Hoimin Kim, Jaehoon Lee, Jiyun Lee, Min-Jae Kim, Dongki Lee, Byung Mook Weon, Dong-Am Park, Nam-Gyu Park, Sung Yun Son, Junki Kim, Yun-Hi Kim, Boseok Kang. From non-doped to dopable: The impact of methoxy functionalization on doping and thermoelectric properties of conjugated polymers. EcoMat, 2024, 6(4): e12442 https://doi.org/10.1002/eom2.12442

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Meng B, Liu J, Wang L. Recent development of n-type thermoelectric materials based on conjugated polymers. Nano Mater Sci. 2021;3(2):113-123. CrossRef Google scholar

[2]	Wang H, Yu C. Organic thermoelectrics: materials preparation, performance optimization, and device integration. Joule. 2019;3(1):53-80. CrossRef Google scholar

[3]	Kroon R, Mengistie DA, Kiefer D, et al. Thermoelectric plastics: from design to synthesis, processing and structure-property relationships. Chem Soc Rev. 2016;45(22):6147-6164. CrossRef Google scholar

[4]	Lee S, Kim S, Pathak A, et al. Recent progress in organic thermoelectric materials and devices. Macromol Res. 2020;28(6):531-552. CrossRef Google scholar

[5]	Zhao W, Ding J, Zou Y, Di CA, Zhu D. Chemical doping of organic semiconductors for thermoelectric applications. Chem Soc Rev. 2020;49(20):7210-7228. CrossRef Google scholar

[6]	Yuan D, Liu W, Zhu X. Efficient and air-stable n-type doping in organic semiconductors. Chem Soc Rev. 2023;52(11):3842-3872. CrossRef Google scholar

[7]	Scheunemann D, Järsvall E, Liu J, et al. Charge transport in doped conjugated polymers for organic thermoelectrics. Chem Phys Rev. 2022;3(2):21309. CrossRef Google scholar

[8]	Boyle CJ, Upadhyaya M, Wang P, et al. Tuning charge transport dynamics via clustering of doping in organic semiconductor thin films. Nat Commun. 2019;10(1):2827. CrossRef Google scholar

[9]	Yang K, Chen Z, Wang Y, Guo X. Alkoxy-functionalized bithiophene/thiazoles: versatile building blocks for high-performance organic and polymeric semiconductors. Acc Mater Res. 2023;4(3):237-250. CrossRef Google scholar

[10]	George Z, Kroon R, Gehlhaar R, et al. The influence of alkoxy substitutions on the properties of diketopyrrolopyrrole-phenyl copolymers for solar cells. Materials. 2013;6(7):3022-3034. CrossRef Google scholar

[11]	Huang H, Chen Z, Ponce Ortiz R, et al. Combining electron-neutral building blocks with intramolecular "conformational locks" affords stable, high-mobility p- and n-channel polymer semiconductors. J Am Chem Soc. 2012;134(26):10966-10973. CrossRef Google scholar

[12]	Kim HG, Kang B, Ko H, Lee J, Shin J, Cho K. Synthetic tailoring of solid-state order in diketopyrrolopyrrole-based copolymers via intramolecular noncovalent interactions. Chem Mater. 2015;27(3):829-838. CrossRef Google scholar

[13]	Qiu B, Chen S, Xue L, et al. Effects of alkoxy and fluorine atom substitution of donor molecules on the morphology and photovoltaic performance of all small molecule organic solar cells. Front Chem. 2018;6:413. CrossRef Google scholar

[14]	Song KW, Choi MH, Song HJ, Heo SW, Lee JY, Moon DK. Effect of replacing proton with alkoxy side chain for donor acceptor type organic photovoltaics. Sol Energy Mater Sol Cells. 2014;120:303-309. CrossRef Google scholar

[15]	Yu ZD, Lu Y, Wang JY, Pei J. Conformation control of conjugated polymers. Chemistry. 2020;26(69):16194-16205. CrossRef Google scholar

[16]	Lee J, Kim M, Kang B, et al. Side-chain engineering for fine-tuning of energy levels and nanoscale morphology in polymer solar cells. Adv Energy Mater. 2014;4(10):1400087. CrossRef Google scholar

[17]	Kim HG, Kim M, Clement JA, et al. Energy level engineering of donor polymers via inductive and resonance effects for polymer solar cells: effects of cyano and alkoxy substituents. Chem Mater. 2015;27(19):6858-6868. CrossRef Google scholar

[18]	Lee H, Park C, Sin DH, Park JH, Cho K. Recent advances in morphology optimization for organic photovoltaics. Adv Mater. 2018;30(34):1800453. CrossRef Google scholar

[19]	Liu Z, Hu Y, Li P, Wen J, He J, Gao X. Enhancement of the thermoelectric performance of dpp based polymers by introducing one 3,4-ethylenedioxythiophene electron-rich building block. J Mater Chem C. 2020;8(31):10859-10867. CrossRef Google scholar

[20]	Kiefer D, Kroon R, Hofmann AI, et al. Double doping of conjugated polymers with monomer molecular dopants. Nat Mater. 2019;18(2):149-155. CrossRef Google scholar

[21]	Li H, Song J, Xiao J, Wu L, Katz HE, Chen L. Synergistically improved molecular doping and carrier mobility by copolymerization of donor–acceptor and donor–donor building blocks for thermoelectric application. Adv Funct Mater. 2020;30(40):2004378. CrossRef Google scholar

[22]	Kroon R, Kiefer D, Stegerer D, Yu L, Sommer M, Muller C. Polar side chains enhance processability, electrical conductivity, and thermal stability of a molecularly p-doped polythiophene. Adv Mater. 2017;29(24):1700930. CrossRef Google scholar

[23]	Liu J, Qiu L, Alessandri R, et al. Enhancing molecular n-type doping of donor-acceptor copolymers by tailoring side chains. Adv Mater. 2018;30(7):1704630. CrossRef Google scholar

[24]	Huo L, Zhang S, Guo X, Xu F, Li Y, Hou J. Replacing alkoxy groups with alkylthienyl groups: a feasible approach to improve the properties of photovoltaic polymers. Angew Chem Int ed. 2011;50(41):9697-9702. CrossRef Google scholar

[25]	Xu J, Ji Q, Kong L, Du H, Ju X, Zhao J. Soluble electrochromic polymers incorporating benzoselenadiazole and electron donor units (carbazole or fluorene): synthesis and electronic-optical properties. Polymers. 2018;10(4):450. CrossRef Google scholar

[26]	Bao WW, Li R, Dai ZC, et al. Diketopyrrolopyrrole (DPP)-based materials and its applications: a review. Front Chem. 2020;8:679. CrossRef Google scholar

[27]	Luo H, Yu C, Liu Z, et al. Remarkable enhancement of charge carrier mobility of conjugated polymer field-effect transistors upon incorporating an ionic additive. Sci Adv. 2016;2(5):e1600076. CrossRef Google scholar

[28]	Ding J, Liu Z, Zhao W, et al. Selenium-substituted diketopyrrolopyrrole polymer for high-performance p-type organic thermoelectric materials. Angew Chem Int ed. 2019;58(52):18994-18999. CrossRef Google scholar

[29]	Kang I, Yun HJ, Chung DS, Kwon SK, Kim YH. Record high hole mobility in polymer semiconductors via side-chain engineering. J Am Chem Soc. 2013;135(40):14896-14899. CrossRef Google scholar

[30]	Kang K, Watanabe S, Broch K, et al. 2D coherent charge transport in highly ordered conducting polymers doped by solid state diffusion. Nat Mater. 2016;15(8):896-902. CrossRef Google scholar

[31]	Nam G-H, Sun C, Chung DS, Kim Y-H. Enhancing doping efficiency of diketopyrrolopyrrole-copolymers by introducing sparse intramolecular alkyl chain spacing. Macromolecules. 2021;54(17):7870-7879. CrossRef Google scholar

[32]	Li H, DeCoster ME, Ming C, et al. Enhanced molecular doping for high conductivity in polymers with volume freed for dopants. Macromolecules. 2019;52(24):9804-9812. CrossRef Google scholar

[33]	Fujimoto R, Yamashita Y, Kumagai S, et al. Molecular doping in organic semiconductors: fully solution-processed, vacuum-free doping with metal–organic complexes in an orthogonal solvent. J Mater Chem C. 2017;5(46):12023-12030. CrossRef Google scholar

[34]	Yurash B, Cao DX, Brus VV, et al. Towards understanding the doping mechanism of organic semiconductors by Lewis acids. Nat Mater. 2019;18(12):1327-1334. CrossRef Google scholar

[35]	Kang YH, Ko S-J, Lee M-H, Lee YK, Kim BJ, Cho SY. Highly efficient and air stable thermoelectric devices of poly(3-hexylthiophene) by dual doping of Au metal precursors. Nano Energy. 2021;82:105681. CrossRef Google scholar

[36]	Wu L, Li H, Chai H, Xu Q, Chen Y, Chen L. Anion-dependent molecular doping and charge transport in ferric salt-doped P3HT for thermoelectric application. ACS Appl Electron Mater. 2021;3(3):1252-1259. CrossRef Google scholar

[37]	Lee H, Li H, Kim YS, et al. Novel dithienopyrrole-based conjugated copolymers: importance of backbone planarity in achieving high electrical conductivity and thermoelectric performance. Macromol Rapid Commun. 2022;43(19):2200277. CrossRef Google scholar

[38]	Min Han J, Eun Yoon S, Hyun Jung K, et al. Dopant-dependent thermoelectric performance of indoloindole-selenophene based conjugated polymer. Chem Eng J. 2022;431:133779. CrossRef Google scholar

[39]	Suh EH, Jeong MK, Lee K, et al. Understanding the solution-state doping of donor–acceptor polymers through tailored side chain engineering for thermoelectrics. Adv Funct Mater. 2022;32(51):2207886. CrossRef Google scholar

[40]	Sahalianov I, Hynynen J, Barlow S, Marder SR, Muller C, Zozoulenko I. UV-to-IR absorption of molecularly p-doped polythiophenes with alkyl and oligoether side chains: experiment and interpretation based on density functional theory. J Phys Chem B. 2020;124(49):11280-11293. CrossRef Google scholar

[41]	Suh EH, Kim SB, Yang HS, Jang J. Regulating competitive doping in solution-mixed conjugated polymers for dramatically improving thermoelectric properties. Adv Funct Mater. 2022;32(46):2207413. CrossRef Google scholar

[42]	Mendez H, Heimel G, Winkler S, et al. Charge-transfer crystallites as molecular electrical dopants. Nat Commun. 2015;6(1):8560. CrossRef Google scholar

[43]	Lee JH, Yoon S, Ko MS, Lee N, Hwang I, Lee MJ. Improved performance of organic photovoltaic devices by doping F4TCNQ onto solution-processed graphene as a hole transport layer. Org Electron. 2016;30:302-311. CrossRef Google scholar

[44]	Untilova V, Biskup T, Biniek L, Vijayakumar V, Brinkmann M. Control of chain alignment and crystallization helps enhance charge conductivities and thermoelectric power factors in sequentially doped P3HT:F4TCNQ films. Macromolecules. 2020;53(7):2441-2453. CrossRef Google scholar

[45]	Tang J, Pai Y-H, Liang Z. Strategic insights into semiconducting polymer thermoelectrics by leveraging molecular structures and chemical doping. ACS Energy Lett. 2022;7(12):4299-4324. CrossRef Google scholar

[46]	Zhong Y, Untilova V, Muller D, et al. Preferential location of dopants in the amorphous phase of oriented regioregular poly(3-hexylthiophene-2,5-diyl) films helps reach charge conductivities of 3000 S cm⁻¹. Adv Funct Mater. 2022;32(30):2202075. CrossRef Google scholar

[47]	Reiser P, Müller L, Sivanesan V, et al. Dopant diffusion in sequentially doped poly(3-hexylthiophene) studied by infrared and photoelectron spectroscopy. J Phys Chem C. 2018;122(26):14518-14527. CrossRef Google scholar

[48]	Zhang F, Mohammadi E, Qu G, Dai X, Diao Y. Orientation-dependent host-dopant interactions for manipulating charge transport in conjugated polymers. Adv Mater. 2020;32(39):e2002823. CrossRef Google scholar

[49]	Wang D, Ding J, Dai X, et al. Triggering ZT to 0.40 by engineering orientation in one polymeric semiconductor. Adv Mater. 2023;35(2):e2208215. CrossRef Google scholar

[50]	Glaudell AM, Cochran JE, Patel SN, Chabinyc ML. Impact of the doping method on conductivity and thermopower in semiconducting polythiophenes. Adv Energy Mater. 2015;5(4):1401072. CrossRef Google scholar