[1] T M TRITT, M A SUBRAMANIAN. Thermoelectric materials, phenomena, and applications: a bird's eye view. MRS Bulletin, 188(2006).

[2] G J SNYDER, E S TOBERER. Complex thermoelectric materials. Nature Materials, 105(2008).

[3] S SINGH, S LEE, H KANG et al. Thermoelectric power waves from stored chemical energy. Energy Storage Materials, 55(2016).

[4] S TU, T TIAN, A L OECHSLE et al. Improvement of the thermoelectric properties of PEDOT:PSS films via DMSO addition and DMSO/salt post-treatment resolved from a fundamental view. Chemical Engineering Journal, 132295(2022).

[5] X LIU, X L SHI, L ZHANG et al. One-step post-treatment boosts thermoelectric properties of PEDOT:PSS flexible thin films. Journal of Materials Science & Technology, 81(2023).

[6] F LI, H WANG, R HUANG et al. Recent advances in SnSe nanostructures beyond thermoelectricity. Advanced Functional Materials, 2200516(2022).

[7] C ZHOU, Y K LEE, Y YU et al. Polycrystalline SnSe with a thermoelectric figure of merit greater than the single crystal. Nature Materials, 1378(2021).

[8] W H LI, W H DENG, G E WANG et al. Conductive MOFs. EnergyChem, 100029(2020).

[9] T A GOETJEN, J LIU, Y WU et al. Metal-organic framework (MOF) materials as polymerization catalysts: a review and recent advances. Chemical Communications, 10409(2020).

[10] D E JARAMILLO, H JIANG, H A EVANS et al. Ambient- temperature hydrogen storage via vanadium(II)-dihydrogen complexation in a metal-organic framework. Journal of the American Chemical Society, 6248(2021).

[11] P LI, Y SHEN, D WANG et al. Selective adsorption-based separation of flue gas and natural gas in zirconium metal-organic frameworks nanocrystals. Molecules, 1822(2019).

[12] H LEE, D VASHAEE, D Z WANG et al. Effects of nanoscale porosity on thermoelectric properties of SiGe. Journal of Applied Physics, 094308(2010).

[13] OUAY B LE, M BOUDOT, T KITAO et al. Nanostructuration of PEDOT in porous coordination polymers for tunable porosity and conductivity. Journal of the American Chemical Society, 10088(2016).

[14] A J MINNICH, M S DRESSELHAUS, Z F REN et al. Bulk nanostructured thermoelectric materials: current research and future prospects. Energy & Environmental Science, 466(2009).

[15] L S XIE, G SKORUPSKII, M DINCĂ. Electrically conductive metal-organic frameworks. Chemical Reviews, 8536(2020).

[16] L SUN, B LIAO, D SHEBERLA et al. A microporous and naturally nanostructured thermoelectric metal-organic framework with ultralow thermal conductivity. Joule, 168(2017).

[17] Z CHEN, Y CUI, Y JIN et al. Nanorods of a novel highly conductive 2D metal-organic framework based on perthiolated coronene for thermoelectric conversion. Journal of Materials Chemistry C, 8199(2020).

[18] K J ERICKSON, F LEONARD, V STAVILA et al. Thin film thermoelectric metal-organic framework with high Seebeck coefficient and low thermal conductivity. Advanced Materials, 3453(2015).

[19] M DE LOURDES GONZALEZ-JUAREZ, E FLORE, M MARTIN-GONZALE et al. Electrochemical deposition and thermoelectric characterisation of a semiconducting 2-D metal-organic framework thin film. Journal of Materials Chemistry A, 13197(2020).

[20] O V GUTOV, M G HEVIA, E C ESCUDERO-ADAN et al. Metal-organic framework (MOF) defects under control: insights into the missing linker sites and their implication in the reactivity of zirconium-based frameworks. Inorganic chemistry, 8396(2015).

[21] A JADHAV, K GUPTA, P NINAWE et al. Imparting multifunctionality by utilizing biporosity in a zirconium-based metal-organic framework. Angewandte Chemie International Edition, 2215(2020).

[22] A O PATIL, A J HEEGER, F WUDL. Optical properties of conducting polymers. Chemical Reviews, 183(1988).

[23] Z HU, Y DING, X HU et al. Recent progress in 2D group IV-IV monochalcogenides: synthesis, properties and applications. Nanotechnology, 252001(2019).

[24] T LINDFORS, Z A BOEVA, R M LATONEN. Electrochemical synthesis of poly (3, 4-ethylenedioxythiophene) in aqueous dispersion of high porosity reduced graphene oxide. RSC advances, 25279(2014).

[25] V BUTOVA, A P BUDNYK, K M CHARYKOV et al. Partial and complete substitution of the 1,4-benzenedicarboxylate linker in UiO-66 with 1,4-naphthalenedicarboxylate: synthesis, characterization, and H₂-adsorption properties. Inorganic Chemistry, 1607(2019).

[26] S B ALIEV, D G SAMSONENKO, E A MAKSIMOVSKIY et al. Polyaniline-intercalated MIL-101: selective CO₂ sorption and supercapacitor properties. New Journal of Chemistry, 5306(2016).

[27] T C WANG, I HOD, C O AUDU et al. Rendering high surface area, mesoporous metal-organic frameworks electronically conductive. ACS Applied Materials & Interfaces, 12584(2017).

[28] B DHARE, S NAGARKAR, J KUMAR et al. Increase in electrical conductivity of MOF to billion-fold upon filling the nanochannels with conducting polymer. The Journal of Physical Chemistry Letters, 2945(2016).