We set out to demonstrate the development of a highly conductive polymer based on poly-(3,4-ethylenedithia thiophene) (PEDTT), PEDOTs structural analogue historically notorious for structural disorder and limited conductivities. The caveat therein was previously described to lie in intra-molecular repulsions. We demonstrate how a tremendous >2600-fold improvement in conductivity and metallic features, such as magnetoconductivity can be achieved. This is achieved through a careful choice of the counter-ion (sulphate) and the use of oxidative chemical vapour deposition (oCVD). It is shown that high structural order on the molecular level was established and the formation of crystallites tens of nanometres in size was achieved. We infer that the sulphate ions therein intercalate between the polymer chains, thus forming densely packed crystals of planar molecules with extended π-systems. Consequently, room-temperature conductivities of above 1000 S cm-1 are achieved, challenging those of conventional PEDOT:PSS. The material is in the critical regime of the metal-insulator transition.
Keywords: 105 Low-Dimension (1D/2D) materials; 106 Metallic materials; 201 Electronics / Semiconductor / TCOs; 203 Magnetics / Spintronics / Superconductors; 301 Chemical syntheses / processing; 500 Characterization; PEDOT; PEDTT; conducting polymers; magnetotransport; metal–insulator transition.
© 2021 The Author(s). Published by National Institute for Materials Science in partnership with Taylor & Francis Group.