<?xml version="1.0" encoding="utf-8"?>
<XML>
<ISCJOURNAL>
<YEAR>2021</YEAR>
<VOL>3</VOL>
<NO>9</NO>
<MOSALSAL>9</MOSALSAL>
<PAGE_NO>16</PAGE_NO>
<ARTICLES>

			<ARTICLE>
				<TitleF></TitleF>
				<TitleE>An overview of materials, processing, and applications for wearable electronics</TitleE>
				<TitleLang_ID>en</TitleLang_ID>
				<ABSTRACTS>
					<ABSTRACT>
						<Language_ID>en</Language_ID>
						<CONTENT>Wearable electronics are gaining widespread attention because of the potential applications of them in systems of wearable human care and health monitoring. These new devices are probably a collection of different appli-cations like batteries, sensors, displays, and so on. In these respects, conductive fibers, inks, and fabrics were examined. On the field, three materials categories including carbon, metal, and polymer-based materials were investigated. Materials of carbon have advantages like good electrical conductivity, structural and inherent flex-ibility, high thermal and chemical stability, light weight, ease of chemical operation, and potential production of mass, enabling them to be a good candidate for wearable and flexible electronics. Conducting polymers have a number of drawbacks in their natural state; however, by combining them with other materials, these drawbacks can be solved. Conducting polymer composites have a wide range of applications in optoelectronic, electronic, and electrical sectors due to their synergetic effects. Liquid metal was bestowed with new-emerging characteristics and  multifunctional  applications.  Due  to  the  high  surface  tension  and  limited  adherence  on  many  surfaces,  the  manufacturing approach of patterning liquid metals on flexible substrates has received a lot of attention up to now. The current state of wearable materials as actuators and fabrication processes are discussed in this review paper.</CONTENT>
					</ABSTRACT>
				</ABSTRACTS>
				<PAGES>
					<PAGE>
						<FPAGE>275</FPAGE>
						<TPAGE>290</TPAGE>
					</PAGE>
				</PAGES>
	
				<AUTHORS>
					<AUTHOR>
						<NameE>Mohammad</NameE>
						<MidNameE></MidNameE>		
						<FamilyE>Yusuf</FamilyE>
						<Organizations>
							<Organization>Department of Chemical Engineering</Organization>
						</Organizations>
						<Universities>
							<University>Universiti Teknologi PETRONAS</University>
						</Universities>
						<Countries>
							<Country>Malaysia</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>			
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<NameE>Sara</NameE>
						<MidNameE></MidNameE>		
						<FamilyE>Eskandarinezhad</FamilyE>
						<Organizations>
							<Organization>Department of Mining and Metallurgy</Organization>
						</Organizations>
						<Universities>
							<University>Yazd University</University>
						</Universities>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>s.eskandari.nezhad@gmail.com</Email>			
						</EMAILS>
					</AUTHOR>
				</AUTHORS>
				<KEYWORDS>
					<KEYWORD>
						<KeyText>Wearable electronics</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Conductive fibers</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Sensors</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Conductive fabrics</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Fabrication methods</KeyText>
					</KEYWORD>
					</KEYWORDS>
				<PDFFileName>Article7.pdf</PDFFileName>
				<REFRENCES>
				<REFRENCE>
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