Impact of Molecular Design on Degradation Lifetimes of Degradable Imine-Based Semiconducting Polymers.

Transient electronics are a rapidly emerging field due to their potential applications in the environment and human health. Recently, a few studies have incorporated acid-labile imine bonds into polymer semiconductors to impart transience; however, understanding of the structure-degradation property relationships of these polymers is limited. In this study, we systematically design and characterize a series of fully degradable diketopyrrolopyrrole-based polymers with engineered sidechains to investigate the impact of several molecular design parameters on the degradation lifetimes of these polymers. By monitoring degradation kinetics via ultraviolet-visible spectroscopy, we reveal that polymer degradation in solution is aggregation-dependent based on the branching point and Mn, with accelerated degradation rates facilitated by decreasing aggregation. Additionally, increasing the hydrophilicity of the polymers promotes water diffusion and therefore acid hydrolysis of the imine bonds along the polymer backbone. The aggregation properties and degradation lifetimes of these polymers rely heavily on solvent, with polymers in chlorobenzene taking six times as long to degrade as in chloroform. We develop a new method for quantifying the degradation of polymers in the thin film and observe that similar factors and considerations (e.g., interchain order, crystallite size, and hydrophilicity) used for designing high-performance semiconductors impact the degradation of imine-based polymer semiconductors. We found that terpolymerization serves as an attractive approach for achieving degradable semiconductors with both good charge transport and tuned degradation properties. This study provides crucial principles for the molecular design of degradable semiconducting polymers, and we anticipate that these findings will expedite progress toward transient electronics with controlled lifetimes.

[1]  Soon-Ki Kwon,et al.  Side-Chain-Induced Rigid Backbone Organization of Polymer Semiconductors through Semifluoroalkyl Side Chains. , 2016, Journal of the American Chemical Society.

[2]  Kush Patel,et al.  Harnessing Imine Diversity To Tune Hyperbranched Polymer Degradation , 2018 .

[3]  Karl Deisseroth,et al.  Stretchable and Fully Degradable Semiconductors for Transient Electronics , 2019, ACS central science.

[4]  T. Someya,et al.  Ultraflexible Near‐Infrared Organic Photodetectors for Conformal Photoplethysmogram Sensors , 2018, Advanced materials.

[5]  J. B. Tok,et al.  A design strategy for high mobility stretchable polymer semiconductors , 2021, Nature Communications.

[6]  P. Rossky,et al.  Impact of backbone fluorination on nanoscale morphology and excitonic coupling in polythiophenes , 2017, Proceedings of the National Academy of Sciences.

[7]  Sihong Wang,et al.  Nonhalogenated Solvent Processable and Printable High-Performance Polymer Semiconductor Enabled by Isomeric Nonconjugated Flexible Linkers , 2018, Macromolecules.

[8]  Zhenan Bao,et al.  Siloxane-terminated solubilizing side chains: bringing conjugated polymer backbones closer and boosting hole mobilities in thin-film transistors. , 2011, Journal of the American Chemical Society.

[9]  E. Poverenov,et al.  Unusual doping of donor-acceptor-type conjugated polymers using lewis acids. , 2014, Journal of the American Chemical Society.

[10]  Yang Zou,et al.  Biodegradable triboelectric nanogenerator as a life-time designed implantable power source , 2016, Science Advances.

[11]  Jin-Hu Dou,et al.  Strong Electron‐Deficient Polymers Lead to High Electron Mobility in Air and Their Morphology‐Dependent Transport Behaviors , 2016, Advanced materials.

[12]  Zhenan Bao,et al.  Side Chain Engineering in Solution-Processable Conjugated Polymers , 2014 .

[13]  Samuel E. Root,et al.  Stretchable and Degradable Semiconducting Block Copolymers. , 2018, Macromolecules.

[14]  Allister F. McGuire,et al.  Biocompatible and totally disintegrable semiconducting polymer for ultrathin and ultralightweight transient electronics , 2017, Proceedings of the National Academy of Sciences.

[15]  J. Lehn,et al.  Doubly degradable dynamers: dynamic covalent polymers based on reversible imine connections and biodegradable polyester units , 2012 .

[16]  Seneca J. Velling,et al.  Expandable Polymer Enabled Wirelessly Destructible High‐Performance Solid State Electronics , 2017 .

[17]  Zhong Lin Wang,et al.  Seawater Degradable Triboelectric Nanogenerators for Blue Energy , 2020, Advanced Materials Technologies.

[18]  P. Rossky,et al.  Direct observation of backbone planarization via side-chain alignment in single bulky-substituted polythiophenes , 2018, Proceedings of the National Academy of Sciences.

[19]  Taeghwan Hyeon,et al.  Ultra‐Wideband Multi‐Dye‐Sensitized Upconverting Nanoparticles for Information Security Application , 2017, Advanced materials.

[20]  Zhenan Bao,et al.  Polymer Chemistries Underpinning Materials for Skin-Inspired Electronics , 2019, Macromolecules.

[21]  M. Toney,et al.  Fine-Tuning Semiconducting Polymer Self-Aggregation and Crystallinity Enables Optimal Morphology and High-Performance Printed All-Polymer Solar Cells. , 2019, Journal of the American Chemical Society.

[22]  T. Segura,et al.  Imine Hydrogels with Tunable Degradability for Tissue Engineering. , 2015, Biomacromolecules.

[23]  Huanyu Cheng,et al.  A Physically Transient Form of Silicon Electronics , 2012, Science.

[24]  G. Frey,et al.  Tuning Intra and Intermolecular Interactions for Balanced Hole and Electron Transport in Semiconducting Polymers , 2020 .

[25]  O. Farokhzad,et al.  Degradable Controlled-Release Polymers and Polymeric Nanoparticles: Mechanisms of Controlling Drug Release. , 2016, Chemical reviews.

[26]  Bumjoon J. Kim,et al.  Disintegrable n‐Type Electroactive Terpolymers for High‐Performance, Transient Organic Electronics , 2021, Advanced Functional Materials.

[27]  T. Shin,et al.  Investigation of Structure–Property Relationships in Diketopyrrolopyrrole-Based Polymer Semiconductors via Side-Chain Engineering , 2015 .

[28]  Cunjiang Yu,et al.  Moisture-triggered physically transient electronics , 2017, Science Advances.

[29]  Boris Murmann,et al.  Highly stretchable polymer semiconductor films through the nanoconfinement effect , 2017, Science.

[30]  T. Shin,et al.  Boosting the ambipolar performance of solution-processable polymer semiconductors via hybrid side-chain engineering. , 2013, Journal of the American Chemical Society.

[31]  Soon-Ki Kwon,et al.  Record high hole mobility in polymer semiconductors via side-chain engineering. , 2013, Journal of the American Chemical Society.

[32]  Khaled A. M. Gasem,et al.  Mutual Solubility Measurements of Hydrocarbon–Water Systems Containing Benzene, Toluene, and 3-Methylpentane , 2008 .

[33]  Z. Bao,et al.  Modular Synthesis of Fully Degradable Imine-Based Semiconducting p-Type and n-Type Polymers , 2021, Chemistry of Materials.

[34]  Frank C. Walsh,et al.  Review—The Development of Wearable Polymer-Based Sensors: Perspectives , 2020, Journal of The Electrochemical Society.

[35]  Liangbing Hu,et al.  Transient Electronics: Materials and Devices , 2016 .

[36]  Jin-Hu Dou,et al.  Influence of Alkyl Chain Branching Positions on the Hole Mobilities of Polymer Thin‐Film Transistors , 2012, Advanced materials.

[37]  Z. Bao,et al.  Integrating Emerging Polymer Chemistries for the Advancement of Recyclable, Biodegradable, and Biocompatible Electronics , 2021, Advanced science.

[38]  Jong Won Chung,et al.  A Design Strategy for Intrinsically Stretchable High-Performance Polymer Semiconductors: Incorporating Conjugated Rigid Fused-Rings with Bulky Side Groups. , 2021, Journal of the American Chemical Society.

[39]  Zhenan Bao,et al.  Biodegradable Polymeric Materials in Degradable Electronic Devices , 2018, ACS central science.

[40]  Lan Yin,et al.  The emergence of transient electronic devices , 2020, MRS Bulletin.

[41]  Zhenan Bao,et al.  Biodegradable and flexible arterial-pulse sensor for the wireless monitoring of blood flow , 2019, Nature Biomedical Engineering.

[42]  Sung-Ho Shin,et al.  Superior Toughness and Fast Self‐Healing at Room Temperature Engineered by Transparent Elastomers , 2018, Advanced materials.