Page 12 of 12                             Wu et al. Soft Sci 2023;3:35  https://dx.doi.org/10.20517/ss.2023.26

                   Energy 2020;73:104744.  DOI
               19.      Wong TH, Yiu CK, Zhou J, et al. Tattoo-like epidermal electronics as skin sensors for human machine interfaces. Soft Sci 2021;1:10.
                   DOI
               20.      Wang R, Sun L, Zhu X, et al. Carbon nanotube-based strain sensors: structures, fabrication, and applications. Adv Mater Technol
                   2023;8:2200855.  DOI
               21.      Basarir F, Madani Z, Vapaavuori J. Recent advances in silver nanowire based flexible capacitive pressure sensors: from structure,
                   fabrication to emerging applications. Adv Mater Inter 2022;9:2200866.  DOI
               22.      Baharfar M, Kalantar-Zadeh K. Emerging role of liquid metals in sensing. ACS Sens 2022;7:386-408.  DOI  PubMed
               23.      Li G, Li C, Li G, et al. Development of conductive hydrogels for fabricating flexible strain sensors. Small 2022;18:e2101518.  DOI
               24.      Dickey MD. Stretchable and soft electronics using liquid metals. Adv Mater 2017;29:1606425.  DOI  PubMed
               25.      Zhang M, Yao S, Rao W, Liu J. Transformable soft liquid metal micro/nanomaterials. Mat Sci Eng R 2019;138:1-35.  DOI
               26.      Ma J, Krisnadi F, Vong MH, Kong M, Awartani OM, Dickey MD. Shaping a soft future: patterning liquid metals. Adv Mater
                   2023;35:e2205196.  DOI  PubMed
               27.      Park YG, Lee GY, Jang J, Yun SM, Kim E, Park JU. Liquid metal-based soft electronics for wearable healthcare. Adv Healthc Mater
                   2021;10:e2002280.  DOI  PubMed
               28.      Khoshmanesh K, Tang SY, Zhu JY, et al. Liquid metal enabled microfluidics. Lab Chip 2017;17:974-93.  DOI
               29.      Wu P, Wang Z, Yao X, Fu J, He Y. Recyclable conductive nanoclay for direct in situ printing flexible electronics. Mater Horiz
                   2021;8:2006-17.  DOI  PubMed
               30.      Neumann TV, Dickey MD. Liquid Metal direct write and 3d printing: a review. Adv Mater Technol 2020;5:2000070.  DOI
               31.      Li X, Li M, Zong L, et al. Liquid metal droplets wrapped with polysaccharide microgel as biocompatible aqueous ink for flexible
                   conductive devices. Adv Funct Mater 2018;28:1804197.  DOI
               32.      Mohammed MG, Kramer R. All-printed flexible and stretchable electronics. Adv Mater 2017;29:1604965.  DOI  PubMed
               33.      Tang L, Mou L, Zhang W, Jiang X. Large-scale fabrication of highly elastic conductors on a broad range of surfaces. ACS Appl Mater
                   Interfaces 2019;11:7138-47.  DOI
               34.      Tang L, Cheng S, Zhang L, et al. Printable metal-polymer conductors for highly stretchable bio-devices. iScience 2018;4:302-11.  DOI
                   PubMed  PMC
               35.      Xu J, Guo H, Ding H, et al. Printable and recyclable conductive ink based on a liquid metal with excellent surface wettability for
                   flexible electronics. ACS Appl Mater Interfaces 2021;13:7443-52.  DOI
               36.      Wu P, Fu J, Xu Y, He Y. Liquid metal microgels for three-dimensional printing of smart electronic clothes. ACS Appl Mater Interfaces
                   2022;14:13458-67.  DOI
               37.      Lin  Y,  Genzer  J,  Dickey  MD.  Attributes,  fabrication,  and  applications  of  gallium-based  liquid  metal  particles.  Adv  Sci
                   2020;7:2000192.  DOI  PubMed  PMC
               38.      Markvicka EJ, Bartlett MD, Huang X, Majidi C. An autonomously electrically self-healing liquid metal-elastomer composite for
                   robust soft-matter robotics and electronics. Nat Mater 2018;17:618-24.  DOI  PubMed
               39.      Wang S, Nie Y, Zhu H, et al. Intrinsically stretchable electronics with ultrahigh deformability to monitor dynamically moving organs.
                   Sci Adv 2022;8:eabl5511.  DOI  PubMed  PMC
               40.      Ozutemiz KB, Wissman J, Ozdoganlar OB, Majidi C. EGain-metal interfacing for liquid metal circuitry and microelectronics
                   integration. Adv Mater Interfaces 2018;5:1701596.  DOI
               41.      Liao M, Liao H, Ye J, Wan P, Zhang L. Polyvinyl alcohol-stabilized liquid metal hydrogel for wearable transient epidermal sensors.
                   ACS Appl Mater Interfaces 2019;11:47358-64.  DOI  PubMed
               42.      Hu G, Wang S, Yu J, Zhang J, Sun Y, Kong D. A facile and scalable patterning approach for ultrastretchable liquid metal features. Lab
                   Chip 2022;22:4933-40.  DOI
               43.      Park YG, An HS, Kim JY, Park JU. High-resolution, reconfigurable printing of liquid metals with three-dimensional structures. Sci
                   Adv 2019;5:eaaw2844.  DOI  PubMed  PMC
               44.      Boley JW, White EL, Kramer RK. Mechanically sintered gallium-indium nanoparticles. Adv Mater 2015;27:2355-60.  DOI  PubMed
               45.      Chang H, Zhang P, Guo R, et al. Recoverable liquid metal paste with reversible rheological characteristic for electronics printing. ACS
                   Appl Mater Interfaces 2020;12:14125-35.  DOI
               46.      Thrasher CJ, Farrell ZJ, Morris NJ, Willey CL, Tabor CE. Mechanoresponsive polymerized liquid metal networks. Adv Mater
                   2019;31:e1903864.  DOI  PubMed
               47.      Kazem N, Hellebrekers T, Majidi C. Soft multifunctional composites and emulsions with liquid metals. Adv Mater 2017;29:1605985.
                   DOI  PubMed
               48.      Malakooti MH, Kazem N, Yan J, et al. Liquid metal supercooling for low-temperature thermoelectric wearables. Adv Funct Mater
                   2019;29:1906098.  DOI