Published 2023-12-30
Keywords
- Polymer Composite; Thermal;Electrical Properties; Conductivity.
How to Cite
Padaki, R., & K., A. (2023). Electrical and Thermal Properties of Polymer Nanocomposites. Kristu Jayanti Journal of Computational Sciences (KJCS), 3(1), 91–98. https://doi.org/10.59176/kjcs.v3i1.2328
Abstract
Biodegradable polymers has inherent drawbacks, such as limited thermal stability and electrical conductivity, which hinder their widespread application in various fields, including electronic devices. These challenges result in less-than-optimal electrical and thermal properties when compared to standalone biodegradable polymers. Various techniques, such as co-polymerization, cross-linking and blending, with other polymers, can address and enhance the electrical and thermal properties of biodegradable polymers. Among these methods, the creation of nanocomposites emerges as very important approach to significantly improve the overall characteristics and applications of biodegradable polymers. This article provides a comprehensive overview of the electrical and thermal properties of biodegradable polymers. Additionally, it delves into the discussion of biodegradable polymer nanocomposites, encompassing blends of polymers, inorganic materials, and other nanomaterials.
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References
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[4] Peng X, Dong K, Wu Z, Wang J, Wang ZL.: A review on emerging biodegradable polymers for environmentally benign transient electronic skins. J Mater Sci, 56, 16765–89, 2021.
[5] Martina M, Hutmacher DW. Biodegradable polymers applied in tissue engineering research: a review. Polym Int. 56, 145–57, 2007.
[6] Kaur D, Bharti A, Sharma T, Madhu C.: Dielectric Properties of ZnO-Based Nanocomposites and Their Potential Applications. Int J Opt, 2021, 1–20, 2021.
[7] Abdelhamid HN.: Zinc hydroxide nitrate nanosheets conversion into hierarchical zeolitic imidazolate frameworks nanocomposite and their application for CO2 sorption. Mater Today Chem, 15, 100-222, 2020.
[8] El-Bery HM, Abdelhamid HN.: Photocatalytic hydrogen generation via water splitting using ZIF-67 derived Co3O4@C/TiO2. J Environ Chem Eng, 9, 105702, 2021.
[9] Ching-Li Huang, Yu-Chieh Pao, Shi-Yen Chen, Jhih-Yang Hsu, Chia-Lin Tsai, Yen-Ju Cheng.: Synthesis of Asymmetric Benzotrithiophene/Benzotriselenophene Building Blocks and Their Donor–Acceptor Copolymers: Chalcogen Effect on Face-on/Edge-on Orientations and Charge Transport. Macromolecules. 56 (17) , 6722-6732, 2023.
[10] Sung Yun Son, Taiho Park, Wei You.: Understanding of Face-On Crystallites Transitioning to Edge-On Crystallites in Thiophene-Based Conjugated Polymers. Chemistry of Materials, 33 (12) , 4541-4550, 2021.
[11] Milani MA, Gonzlez D, Quijada R, Basso NR, Cerrada ML, Azambuja DS, Galland GB.: Polypropylene/graphene nanosheet nanocomposites by in situ polymerization: synthesis, characterization and fundamental properties. Compos Sci Technol.84,1–7, 2013.
[12] Jerika AC, Helen T, Yangju L, Yu Z, Zhenan B.: Integrating Emerging Polymer Chemistries for the Advancement of Recyclable, Biodegradable, and Biocompatible Electronics. Advanced Sciences. 8, 2101233, 2021.
[13] Ali S, Bae J, Lee CH, Choi KH, Doh YH.: All-printed and highly stable organic resistive switching device based on graphene quantum dots and polyvinylpyrrolidone composite. Org Electron. 25, 225–31, 2015.
[14] Hosseini NR, Lee J-S.: Biocompatible and Flexible Chitosan-Based Resistive Switching Memory with Magnesium Electrodes. Adv Funct Mater. 25, 5586–92, 2015.
[16] Muhammad RA, Leni M, Riyanto R, Jaidan J, Zainuddin N, Ida S.: Dielectric Properties and Flexibility of Polyacrylonitrile/Graphene Oxide Composite Nanofibers. ACS Omega, 7, 33087–33096, 2022.
[17] Sun D, Gu T, Mao Y, Huang C, Qi X, Yang J, et al.: Fabricating High-Thermal-Conductivity, High-Strength, and High-Toughness Polylactic Acid-Based Blend Composites via Constructing Multioriented Microstructures. Biomacromolecules. 23, 1789–802, 2022.
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[19] Patel GB, Singh NL, Singh F, Kulriya PK.: Effect of swift heavy ions irradiation on physicochemical and dielectric properties of chitosan and chitosan-Ag nanocomposites. Radiat Phys Chem. 181, 109288, 2021.
[20] Bekas D, Hou Y, Liu Y, Panesar A. 3D printing to enable multifunctionality in polymer-based composites: a review, Composites Part B: Engineering. 179, 107540, 2019.
[21] Congliang H, Xin Q, Ronggui Y.: Thermal conductivity of polymers and polymer nanocomposites. Material Science and Engineering R. 132, 1-22, 2018.
[22] Hirai T, Leolukman M, Liu CC, Han E, Kim YJ, Ishida Y, Hayakawa T, Kakimoto MA, Nealey PF, Gopalan P.: One-step direct-patterning template utilizing self-assembly of POSS-containing block copolymers. Adv Mater. 21, 1–5, 2009.
[23] Chen WC, Kuo SW, Lu CH, Chang FC.: Specific interactions and self-assembly structures through competitive interactions of crystalline-amorphous diblock copolymer/homopolymer blends: poly(-caprolactone)- b-poly(4-vinyl pyridine)/poly(vinyl phenol). Macromolecules. 42, 3580–90, 2009.