<?xml version='1.0' encoding='UTF-8'?><codeBook xmlns="ddi:codebook:2_5" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xsi:schemaLocation="ddi:codebook:2_5 https://ddialliance.org/Specification/DDI-Codebook/2.5/XMLSchema/codebook.xsd" version="2.5"><docDscr><citation><titlStmt><titl>Replication Data for: High performing solid-state organic electrochemical transistors enabled by glycolated polythiophene and ion-gel electrolyte with a wide operation temperature range from -50 to 110 °C</titl><IDNo agency="DOI">doi:10.21979/N9/4L8UE9</IDNo></titlStmt><distStmt><distrbtr source="archive">DR-NTU (Data)</distrbtr><distDate>2023-09-15</distDate></distStmt><verStmt source="archive"><version date="2023-09-15" type="RELEASED">1</version></verStmt><biblCit>Wu, Xihu, 2023, "Replication Data for: High performing solid-state organic electrochemical transistors enabled by glycolated polythiophene and ion-gel electrolyte with a wide operation temperature range from -50 to 110 °C", https://doi.org/10.21979/N9/4L8UE9, DR-NTU (Data), V1</biblCit></citation></docDscr><stdyDscr><citation><titlStmt><titl>Replication Data for: High performing solid-state organic electrochemical transistors enabled by glycolated polythiophene and ion-gel electrolyte with a wide operation temperature range from -50 to 110 °C</titl><IDNo agency="DOI">doi:10.21979/N9/4L8UE9</IDNo></titlStmt><rspStmt><AuthEnty affiliation="Nanyang Technological University">Wu, Xihu</AuthEnty></rspStmt><prodStmt><software>Origin</software><grantNo agency="Ministry of Education (MOE)">under AcRF Tier 2 grant (MOE2019-T2-2-106)</grantNo><grantNo agency="Ministry of Education (MOE)">AcRF Tier 1 grant (RG118/21)</grantNo></prodStmt><distStmt><distrbtr source="archive">DR-NTU (Data)</distrbtr><contact affiliation="Nanyang Technological University">Wu, Xihu</contact><depositr>Wu, Xihu</depositr><depDate>2023-09-15</depDate></distStmt><holdings URI="https://doi.org/10.21979/N9/4L8UE9"/></citation><stdyInfo><subject><keyword xml:lang="en">Chemistry</keyword><keyword xml:lang="en">Engineering</keyword><keyword>Chemistry</keyword><keyword>Engineering</keyword><keyword>Organic electrochemical transistor</keyword><keyword>Solid state electrolyte</keyword></subject><abstract>Figures Raw data</abstract><sumDscr><dataKind>Experimental data</dataKind></sumDscr></stdyInfo><method><dataColl><sources/></dataColl><anlyInfo/></method><dataAccs><setAvail/><useStmt/></dataAccs><othrStdyMat><relPubl><citation><titlStmt><IDNo agency="doi">10.1002/adfm.202209354</IDNo></titlStmt><biblCit>Wu, X., Chen, S., Moser, M., Moudgil, A., Griggs, S., Marks, A., ... &amp; Leong, W. L. (2023). High Performing Solid‐State Organic Electrochemical Transistors Enabled by Glycolated Polythiophene and Ion‐Gel Electrolyte with a Wide Operation Temperature Range from− 50 to 110° C. Advanced Functional Materials, 33(3), 2209354.</biblCit></citation><ExtLink URI="https://onlinelibrary.wiley.com/doi/abs/10.1002/adfm.202209354"/></relPubl><relPubl><citation><titlStmt><IDNo agency="handle">10356/164343</IDNo></titlStmt><biblCit>Wu, X., Chen, S., Moser, M., Moudgil, A., Griggs, S., Marks, A., ... &amp; Leong, W. L. (2023). High Performing Solid‐State Organic Electrochemical Transistors Enabled by Glycolated Polythiophene and Ion‐Gel Electrolyte with a Wide Operation Temperature Range from− 50 to 110° C. Advanced Functional Materials, 33(3), 2209354.</biblCit></citation><ExtLink URI="https://hdl.handle.net/10356/164343"/></relPubl></othrStdyMat></stdyDscr><otherMat ID="f118689" URI="https://researchdata.ntu.edu.sg/api/access/datafile/118689" level="datafile"><labl>Figures _ Raw Data.pptx</labl><notes level="file" type="DATAVERSE:CONTENTTYPE" subject="Content/MIME Type">application/vnd.openxmlformats-officedocument.presentationml.presentation</notes></otherMat></codeBook>