2D MoS2 Helical Liquid Crystalline Fibers for Multifunctional Wearable Sensors

Jun Hyun Park, Jang Hwan Kim, Su Eon Lee, Hyokyeong Kim, Heo Yeon Lim, Ji Sung Park, Taeyeong Yun, Jinyong Lee, Simon Kim, Ho Jun Jin, Kyeong Jun Park, Heemin Kang, Hoe Joon Kim, Hyeong Min Jin, Jiwoong Kim, Sang Ouk Kim, Bong Hoon Kim

Advanced Fiber Materials ›› 2024, Vol. 6 ›› Issue (6) : 1813-1824.

Advanced Fiber Materials ›› 2024, Vol. 6 ›› Issue (6) : 1813-1824. DOI: 10.1007/s42765-024-00450-4
Research Article

2D MoS2 Helical Liquid Crystalline Fibers for Multifunctional Wearable Sensors

Author information +
History +

Abstract

Fiber-based material systems are emerging as key elements for next-generation wearable devices due to their remarkable advantages, including large mechanical deformability, breathability, and high durability. Recently, greatly improved mechanical stability has been established in functional fiber systems by introducing atomic-thick two-dimensional (2D) materials. Further development of intelligent fibers that can respond to various external stimuli is strongly needed for versatile applications. In this work, helical-shaped semiconductive fibers capable of multifunctional sensing are obtained by wet-spinning MoS2 liquid crystal (LC) dispersions. The mechanical properties of the MoS2 fibers were improved by exploiting high-purity LC dispersions consisting of uniformly-sized MoS2 nanoflakes. Notably, three-dimensional (3D) helical fibers with structural chirality were successfully constructed by controlling the wet-spinning process parameters. The helical fibers exhibited multifunctional sensing characteristics, including (1) photodetection, (2) pH monitoring, (3) gas detection, and (4) 3D strain sensing. 2D materials with semiconducting properties as well as abundant surface reactive sites enable smart multifunctionalities in one-dimensional (1D) and helical fiber geometry, which is potentially useful for diverse applications such as wearable internet of things (IoT) devices and soft robotics.

Graphical Abstract

Cite this article

EndNote

Ris (Procite)

Bibtex

Download citation ▾
Jun Hyun Park, Jang Hwan Kim, Su Eon Lee, Hyokyeong Kim, Heo Yeon Lim, Ji Sung Park, Taeyeong Yun, Jinyong Lee, Simon Kim, Ho Jun Jin, Kyeong Jun Park, Heemin Kang, Hoe Joon Kim, Hyeong Min Jin, Jiwoong Kim, Sang Ouk Kim, Bong Hoon Kim. 2D MoS2 Helical Liquid Crystalline Fibers for Multifunctional Wearable Sensors. Advanced Fiber Materials, 2024, 6(6): 1813‒1824 https://doi.org/10.1007/s42765-024-00450-4

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1.]
ZengW, ShuL, LiQ, ChenS, WangF, TaoX-M. Fiber-based wearable electronics: a review of materials, fabrication, devices, and applications. Adv Mater, 2014, 26: 5310
CrossRef Google scholar
[2.]
XuZ, GaoC. Graphene fiber: a new trend in carbon fibers. Mater Today, 2015, 18: 480
CrossRef Google scholar
[3.]
EomW, ShinH, AmbadeRB, LeeSH, LeeKH, KangDJ, HanTH. Large-scale wet-spinning of highly electroconductive MXene fibers. Nat Commun, 2020, 11: 2825
CrossRef Google scholar
[4.]
WangY, YokotaT, SomeyaT. Electrospun nanofiber-based soft electronics. NPG Asia Mater, 2021, 13: 22
CrossRef Google scholar
[5.]
DiJ, ZhangX, YongZ, ZhangY, LiD, LiR, LiQ. Carbon-nanotube fibers for wearable devices and smart textiles. Adv Mater, 2016, 28: 10529
CrossRef Google scholar
[6.]
LeeHB, VeerasubramaniGK, LeeKS, LeeH, HanTH. Joule heating-induced faradaic electrode-decorated graphene fibers for flexible fiber-shaped hybrid supercapacitor with high volumetric energy density. Carbon, 2022, 198: 252
CrossRef Google scholar
[7.]
HwangHS, JungHJ, KimJG, JeongHS, LeeWJ, KimSO. Artificial helical screws of 2D materials with Archimedean spiral arrangement. Adv Funct Mater, 2023, 33: 2212997
CrossRef Google scholar
[8.]
KellyFM, JohnstonJH. Colored and functional silver nanoparticle−wool fiber composites. ACS Appl Mater Interfaces, 2011, 3: 1083
CrossRef Google scholar
[9.]
ChengY, WangR, SunJ, GaoL. A stretchable and highly sensitive graphene-based fiber for sensing tensile strain, bending, and torsion. Adv Mater, 2015, 27: 7365
CrossRef Google scholar
[10.]
ZhaoY, LiX-G, ZhouX, ZhangY-N. Review on the graphene based optical fiber chemical and biological sensors. Sens Actuators B Chem, 2016, 231: 324
CrossRef Google scholar
[11.]
MaY, BaiD, HuX, RenN, GaoW, ChenS, ChenH, LuY, LiJ, BaiY. Robust and antibacterial polymer/mechanically exfoliated graphene nanocomposite fibers for biomedical applications. ACS Appl Mater Interfaces, 2018, 10: 3002
CrossRef Google scholar
[12.]
ZhaoX, ZhouY, XuJ, ChenG, FangY, TatT, XiaoX, SongY, LiS, ChenJ. Soft fibers with magnetoelasticity for wearable electronics. Nat Commun, 2021, 12: 6755
CrossRef Google scholar
[13.]
GeimAK. Graphene: status and prospects. Science, 2009, 324: 1530
CrossRef Google scholar
[14.]
LiX, ZhuH. Two-dimensional MoS2: properties, preparation, and applications. J Materiomics, 2015, 1: 33
CrossRef Google scholar
[15.]
CaldwellJD, AharonovichI, CassaboisG, EdgarJH, GilB, BasovDN. Photonics with hexagonal boron nitride. Nat Rev Mater, 2019, 4: 552
CrossRef Google scholar
[16.]
GogotsiY, AnasoriB. The rise of MXenes. ACS Nano, 2019, 13: 8491
CrossRef Google scholar
[17.]
BonaccorsoF, ColomboL, YuG, StollerM, TozziniV, FerrariAC, RuoffRS, PellegriniV. Graphene, related two-dimensional crystals, and hybrid systems for energy conversion and storage. Science, 2015, 347: 1246501
CrossRef Google scholar
[18.]
KimJE, HanTH, LeeSH, KimJY, AhnCW, YunJM, KimSO. Graphene oxide liquid crystals. Angew Chem Int Ed, 2011, 50: 3043
CrossRef Google scholar
[19.]
XiaY, MathisTS, ZhaoM-Q, AnasoriB, DangA, ZhouZ, ChoH, GogotsiY, YangS. Thickness-independent capacitance of vertically aligned liquid-crystalline MXenes. Nature, 2018, 557: 409
CrossRef Google scholar
[20.]
ZhangJ, UzunS, SeyedinS, LynchPA, AkuzumB, WangZ, QinS, AlhabebM, ShuckCE, LeiW, KumburEC, YangW, WangX, DionG, RazalJM, GogotsiY. Additive-free MXene liquid crystals and fibers. ACS Cent Sci, 2020, 6: 254
CrossRef Google scholar
[21.]
NarayanR, KimJE, KimJY, LeeKE, KimSO. Graphene oxide liquid crystals: discovery, evolution and applications. Adv Mater, 2016, 28: 3045
CrossRef Google scholar
[22.]
YangQ, XuZ, FangB, HuangT, CaiS, ChenH, LiuY, GopalsamyK, GaoW, GaoC. MXene/graphene hybrid fibers for high performance flexible supercapacitors. J Mater Chem, 2017, 5: 22113
CrossRef Google scholar
[23.]
FangB, ChangD, XuZ, GaoC. A review on graphene fibers: expectations, advances, and prospects. Adv Mater, 2020, 32: 1902664
CrossRef Google scholar
[24.]
KimIH, YunT, KimJ-E, YuH, SasikalaSP, LeeKE, KooSH, HwangH, JungHJ, ParkJY, JeongHS, KimSO. Mussel-inspired defect engineering of graphene liquid crystalline fibers for synergistic enhancement of mechanical strength and electrical conductivity. Adv Mater, 2018, 30: 1803267
CrossRef Google scholar
[25.]
ChenS, KimS, ChenW, YuanJ, BashirR, LouJ, van der ZandeAM, KingWP. Monolayer MoS2 nanoribbon transistors fabricated by scanning probe lithography. Nano Lett, 2019, 19: 2092
CrossRef Google scholar
[26.]
Kotekar-PatilD, DengJ, WongSL, LauCS, GohKEJ. Single layer MoS2 nanoribbon field effect transistor. Appl Phys Lett, 2019, 114 013508
CrossRef Google scholar
[27.]
VoiryD, MohiteA, ChhowallaM. Phase engineering of transition metal dichalcogenides. Chem Soc Rev, 2015, 44: 2702
CrossRef Google scholar
[28.]
ConleyHJ, WangB, ZieglerJI, HaglundRF Jr, PantelidesST, BolotinKI. Bandgap engineering of strained monolayer and bilayer MoS2. Nano Lett, 2013, 13: 3626
CrossRef Google scholar
[29.]
EllisJK, LuceroMJ, ScuseriaGE. The indirect to direct band gap transition in multilayered MoS2 as predicted by screened hybrid density functional theory. Appl Phys Lett, 2011, 99 261908
CrossRef Google scholar
[30.]
LuC-P, LiG, MaoJ, WangL-M, AndreiEY. Bandgap, mid-gap states, and gating effects in MoS2. Nano Lett, 2014, 14: 4628
CrossRef Google scholar
[31.]
LiJ, NaiiniMM, VaziriS, LemmeMC, ÖstlingM. Inkjet Printing of MoS2. Adv Funct Mater, 2014, 24: 6524
CrossRef Google scholar
[32.]
WibmerL, LagesS, UnruhT, GuldiDM. Excitons and trions in one-photon- and two-photon-excited MoS2: a study in dispersions. Adv Mater, 2018, 30: 1706702
CrossRef Google scholar
[33.]
KaweckiB, PodgórskiJ. Numerical results quality in dependence on Abaqus plane stress elements type in big displacements compression test. Appl Comput Sci, 2017, 13: 56
CrossRef Google scholar
[34.]
BertolazziS, BrivioJ, KisA. Stretching and breaking of ultrathin MoS2. ACS Nano, 2011, 5(12): 9703
CrossRef Google scholar
[35.]
VukasovicT, VivancoJF, CelentanoD, García-HerreraC. Characterization of the mechanical response of thermoplastic parts fabricated with 3D printing. J Adv Manuf Technol, 2019, 104: 4207
CrossRef Google scholar
[36.]
Börgesson L. ABAQUS. In: Stephansson O, Jing L, Tsang C-F, editors. Developments in geotechnical engineering. Elsevier; 1996. p. 565.
[37.]
DaiH, TangM, HuangJ, WangZ. A series of molecule-intercalated MoS2 as anode materials for sodium ion batteries. ACS Appl Mater & Interfaces, 2021, 13: 10870
CrossRef Google scholar
[38.]
GanX, ZhaoH, LeiD, WangP. Improving electrocatalytic activity of 2H-MoS2 nanosheets obtained by liquid phase exfoliation: covalent surface modification versus interlayer interaction. J Catal, 2020, 391: 424
CrossRef Google scholar
[39.]
SunY, YinS, PengR, LiangJ, CongX, LiY, LiC, WangB, LinM-L, TanP-H, WanC, LiuK. Abnormal out-of-plane vibrational Raman mode in electrochemically intercalated multilayer MoS2. Nano Lett, 2023, 23: 5342
CrossRef Google scholar
[40.]
O’NeillA, KhanU, ColemanJN. Preparation of high concentration dispersions of exfoliated MoS2 with increased flake size. Chem Mater, 2012, 24: 2414
CrossRef Google scholar
[41.]
SanchezEMS, ZavagliaCAC, FelisbertiMI. Unsaturated polyester resins: influence of the styrene concentration on the miscibility and mechanical properties. Polymer, 2000, 41: 765
CrossRef Google scholar
[42.]
ClarksonCM, El Awad AzrakSM, ChowdhuryR, ShuvoSN, SnyderJ, SchuenemanG, OrtalanV, YoungbloodJP. Melt spinning of cellulose nanofibril/polylactic acid (CNF/PLA) composite fibers for high stiffness. ACS Appl Polym Mater, 2019, 1: 160
CrossRef Google scholar
[43.]
GuntiR, Ratna PrasadAV, GuptaAVSSKS. Preparation and properties of successive alkali treated completely biodegradable short jute fiber reinforced PLA composites. Polym Compos, 2016, 37: 2160
CrossRef Google scholar
[44.]
SantoroM, ShahSR, WalkerJL, MikosAG. Poly(lactic acid) nanofibrous scaffolds for tissue engineering. Adv Drug Deliv Rev, 2016, 107: 206
CrossRef Google scholar
[45.]
ChakrabartiB, LiuY, LaGroneJ, CortezR, FauciL, du RoureO, SaintillanD, LindnerA. Flexible filaments buckle into helicoidal shapes in strong compressional flows. Nat Phys, 2020, 16: 689
CrossRef Google scholar
[46.]
JungHJ, Padmajan SasikalaS, LeeKE, HwangHS, YunT, KimIH, KooSH, JainR, LeeGS, KangYH, KimJG, KimJT, KimSO. Self-planarization of high-performance graphene liquid crystalline fibers by hydration. ACS Cent Sci, 2020, 6: 1105
CrossRef Google scholar
[47.]
LiuS, WangY, MingX, XuZ, LiuY, GaoC. High-speed blow spinning of neat graphene fibrous materials. Nano Lett, 2021, 21: 5116
CrossRef Google scholar
[48.]
LiH, ZhangQ, YapCCR, TayBK, EdwinTHT, OlivierA, BaillargeatD. From bulk to monolayer MoS2: evolution of Raman scattering. Adv Funct Mater, 2012, 22: 1385
CrossRef Google scholar
[49.]
Plechinger G, Heydrich S, Eroms J, Weiss D, Schüller C, Korn T. Raman spectroscopy of the interlayer shear mode in few-layer MoS2 flakes. Appl Phys Lett. 2012;101.
[50.]
SteinhoffA, KimJH, JahnkeF, RösnerM, KimDS, LeeC, HanGH, JeongMS, WehlingTO, GiesC. Efficient excitonic photoluminescence in direct and indirect band gap monolayer MoS2. Nano Lett, 2015, 15: 6841
CrossRef Google scholar
[51.]
KimDW, OkJM, JungW-B, KimJ-S, KimSJ, ChoiHO, KimYH, JungH-T. Direct observation of molybdenum disulfide, MoS2, domains by using a liquid crystalline texture method. Nano Lett, 2015, 15: 229
CrossRef Google scholar
[52.]
JiangH, ZhengL, WeiY, WangX. In-situ investigation of the elastic behavior of two-dimensional MoS2 on flexible substrate by nanoindentation. J Phys D Appl Phys, 2021, 54 504006
CrossRef Google scholar
[53.]
BarzegarA, NamnabatMS, NiyaeeFN, TabarraeiA. Linear and nonlinear buckling analysis of double-layer molybdenum disulfide by finite elements. Finite Elem Anal Des, 2023, 218 103919
CrossRef Google scholar
[54.]
LiH, LiuS, LiX, HaoR, WangX, ZhangW, ZhengZ, FengQ. All-solid, ultra-micro, and ultrasensitive pH sensor by monolayer MoS2-based array field-effect transistors. ACS Appl Nano Mater, 2021, 4: 8950
CrossRef Google scholar
[55.]
TimmerB, OlthuisW, BergA. Ammonia sensors and their applications—a review. Sens Actuators B Chem, 2005, 107: 666
CrossRef Google scholar
[56.]
PandeyS, NandaKK. Au nanocomposite based chemiresistive ammonia sensor for health monitoring. ACS Sens, 2016, 1: 55
CrossRef Google scholar
[57.]
ChoB, HahmMG, ChoiM, YoonJ, KimAR, LeeY-J, ParkS-G, KwonJ-D, KimCS, SongM, JeongY, NamK-S, LeeS, YooTJ, KangCG, LeeBH, KoHC, AjayanPM, KimD-H. Charge-transfer-based gas sensing using atomic-layer MoS2. Sci Rep, 2015, 5: 8052
CrossRef Google scholar
[58.]
JärvinenT, LoriteGS, PeräntieJ, TothG, SaarakkalaS, VirtanenVK, KordasK. WS2 and MoS2 thin film gas sensors with high response to NH3 in air at low temperature. Nanotechnology, 2019, 30 405501
CrossRef Google scholar
[59.]
AmjadiM, KyungK-U, ParkI, SittiM. Stretchable, skin-mountable, and wearable strain sensors and their potential applications: a review. Adv Funct Mater, 2016, 26: 1678
CrossRef Google scholar
[60.]
WangY, WangL, YangT, LiX, ZangX, ZhuM, WangK, WuD, ZhuH. Wearable and highly sensitive graphene strain sensors for human motion monitoring. Adv Funct Mater, 2014, 24: 4666
CrossRef Google scholar
[61.]
PetersenKE. Silicon as a mechanical material. Proc IEEE, 1982, 70: 420
CrossRef Google scholar
[62.]
McMillenG. Tendril perversion in intrinsically curved rods. J Nonlinear Sci, 2002, 12: 241
CrossRef Google scholar
[63.]
ChengY, WangR, ChanKH, LuX, SunJ, HoGW. A biomimetic conductive tendril for ultrastretchable and integratable electronics, muscles, and sensors. ACS Nano, 2018, 12: 3898
CrossRef Google scholar
[64.]
WooJ, LeeH, YiC, LeeJ, WonC, OhS, JekalJ, KwonC, LeeS, SongJ, ChoiB, JangK-I, LeeT. Ultrastretchable helical conductive fibers using percolated Ag nanoparticle networks encapsulated by elastic polymers with high durability in omnidirectional deformations for wearable electronics. Adv Funct Mater, 2020, 30: 1910026
CrossRef Google scholar
[65.]
FarahS, AndersonDG, LangerR. Physical and mechanical properties of PLA, and their functions in widespread applications—a comprehensive review. Adv Drug Deliv Rev, 2016, 107: 367
CrossRef Google scholar
Funding
Ministry of Education(2015R1A3A2033061); Ministry of Science and ICT, South Korea(CAP22071-000)

Accesses

Citations

Detail
Sections
Recommended

/