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基於石墨烯及生物碳基材料的可撓式電晶體應用與能量攫取

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Table of ContentsAbstract.......................................................................................................iFigure Captions........................................................................................xiTable Captions...................................................

....................................xxiChapter 1: Introduction1.1 Flexible electronics................................................................................11.2 Graphene the magical material ………………………….……….......21.2.1 Synthesis of graphene…………………………….….…...21.2.1.1 Mechanical exfoliati

on of graphene………………...……21.2.1.2 Epitaxial growth on Sic substrate………………….…..31.2.1.3 Chemical vapor deposition (CVD) method………….…..41.2.2 Graphene transfer…………………………………………....41.3 Application of graphene based Electronics……………………….......51.3.1 Graphene based flexible transparent electrode

……………….61.3.2 Top gated Graphene field effect transistor…………………….71.4 Challenges of flexible graphene based field effect transistors.……….91.5 Energy harvesting devices for flexible electronics………….........….91.6 Solar cell…………………………………………………………...101.6.1 Device architecture…………………………………………101.

6.2 Issues and Challenges of Perovskite solar cells………...121.7 Triboelectric nanogenerator (TENG)………………………………121.7.1 Working mode of TENG………………………………….141.8 Applications of TENG………………………………………………151.8.1 Applications of graphene based TENG…………………....151.8.2 Applications of bio-waste material ba

sed TENG………….171.9 Key challenges of triboelectric nanogenerator…………………....…191.10 Objective and scope of this study………………………………....19Chapter 2: Flexible graphene field effect transistor with fluorinated graphene as gate dielectric2.1 Introduction………………………………………………………....212.2 Material preparation a

nd Device fabrication………………. 232.2.1CVD Growth of Graphene on Copper Foil………………….232.2.2 Transfer of graphene over PET substrate……………...........252.2.3 Fabrication of fluorinated graphene ……………...........252.2.4 F-GFETs with FG as gate dielectric device fabrication……262.2.5 Material and electrical C

haracterization …………………272.3 Results and discussion…………………………………………….282.3.1 Material characterization of PG and FG……………...…...….282.3.2 Electrical characterization of F-GFET with FG as dielectrics..332.3.3 Mechanical stability test of F-GFET with FG as dielectrics ….362.4 Summary…………………………………………………

………....40Chapter 3: Robust sandwiched fluorinated graphene for highly reliable flexible electronics3.1 Introduction………………………………………………………….423.2 Material preparation and Device fabrication ………………….........443.2.1 CVD Growth of Graphene on Copper Foil…………………...443.2.2 Graphene fluorination …...…….…………

…………..............443.2.3 F-GFETs with sandwiched FG device fabrication....................443.2.4 Material and electrical Characterization…..............................453.3 Results and discussion ……………………………………...............453.3.1 Material characterization of sandwiched…………………….453.3.2 Electric

al characterization of F-GFET with sandwiched FG....473.3.3 Mechanical stability test of F-GFET with sandwiched FG…503.3.4 Strain transfer mechanism of sandwiched FG………………513.4 Summary…………………………………………………………....53Chapter 4: Functionalized fluorinated graphene as a novel hole transporting layer for ef

ficient inverted perovskite solar cells4.1 Introduction………………………………………………………….544.2 Material preparation and Device fabrication......................................564.2.1 Materials ………………………...…………………………564.2.2 CVD-Graphene growth ……………………………...…...564.2.3 Graphene fluorination …………………………………….564.

2.4 Transfer of fluorinated graphene…………………………...574.2.5 Device fabrication …………………………………….….574.2.6 Material and electrical Characterization …….....................584.3 Results and discussion …………………………………………….594.3.1 Surface electronic and optical properties of FGr……….….594.3.2 Characterization o

f FGr and perovskite surface ……….…644.3.3 Electrical performance of PSC………………….…….…...694.3.4 Electrical performance of Flexible PSC……………………724.4 Summary…………………………………………………………...78Chapter 5: Flexible layered-graphene charge modulation for highly stable triboelectric nanogenerator5.1 Introduction…………

…………………………………………....795.2 Experimental Section……………………………………………….825.2.1 Large-area graphene growth ……………………………….825.2.2 Fabrication of Al2O3 as the CTL …………………………...825.2.3 Fabrication of a Gr-TENG with Al2O3 as the CTL………825.2.4 Material characterization and electrical measurements…….835.3 Results

and discussion.…………………………………...…………845.3.1 Material Characterization of Graphene Layers/Al2O3……845.3.2 Working Mechanism of Gr-TENG with Al2O3 as CTL…915.3.3 Electrical Characterization of Gr-TENG with Al2O3 CTL…945.3.4 Applications of the Gr-TENG with Al2O3 as CTL……….1015.4 Summary…………………………………………

……………….103Chapter 6: Eco-friendly Spent coffee ground bio-TENG for high performance flexible energy harvester6.1 Introduction…………………………………………………….......1046.2 Experimental Section…………………………………………….1086.2.1 Material Preparation …………………………………….1086.2.2 Fabrication of SCG powder based TENG………………...1086

.2.3 Fabrication of SCG thin-film based TENG ………………1096.2.4 Material characterization and electrical measurements….1106.3 Results and discussion.…………………………………...………1116.3.1 Material Characterization of SCG powder and thin film….1116.3.2 Working Mechanism of SCG-TENG……………………...1186.3.3 Electrical Cha

racterization of SCG-TENG……………….1226.3.4 Applications of the SCG thin-film based TENG………….1326.4 Summary………………………………………………………….134Chapter 7: Conclusions and future perspectives7.1 Conclusion………………………………………………………....1357.2 Future work …………………………….………………………….1377.2.1 Overview of flexible fluorinated g

raphene TENG..............1377.2.1.1 Initial results………………………………….…1387.2.2.1.1 Fabrication of FG-TENG………………1387.2.2.1.2 Working principle of FG-TENG……….1397.2.2.1.3 Electrical output of FG-TENG.………...140References…………………………………………………………….142Appendix A: List of publications………………….……………..........177A

ppendix B: Fabrication process of GFETs with fluorinated graphene (FG) as gate dielectric……........……………………………………….179Appendix C: Fabrication process of GFETs with sandwiched FG…....180Appendix D: Fabrication process of inverted perovskite solar cell with FGr as HTL…………………………………………………………….181Appendi

x E: Fabrication of a Gr-TENG with Al2O3 as the CTL…….182Appendix F: Fabrication of SCG based triboelectric nanogenerator….183Figure captionsFigure 1-1 Exfoliated graphene on SiO2/Si wafer……………………….3Figure 1-2 Epitaxial graphene growth on SiC substrate………………....3Figure 1-3 Growth mechanism of graphe

ne on Cu foil by CVD ……......4Figure 1-4 Wet transfer process of CVD grown graphene…………...….5Figure 1-5 RGO/PET based electrodes as a flexible touch screen.……....6Figure 1-6 Graphene based (a) touch panel (b) touch-screen phone…….7Figure 1-7 Flexible graphene transistors (a) (Top) Optical photograph

of an array of flexible, self-aligned GFETs on PET. (Bottom) The corresponding schematic shows a device layout. (b) Schematic cross-sectional and top views of top-gated graphene flake–based gigahertz transistors. (Left) AFM image of a graphene flake. (Right) Photograph of flexible graphene devices

fabricated on a PI substrate. (c) Cross-sectional schematic of flexible GFETs fabricated using a self-aligned process……8Figure 1-8 The magnitude of power needed for meet certain operation depending critically on the scale and applications………………………10Figure 1-9 Schematic diagrams of PSC in the (a) n-i

-p mesoscopic, (b) n-i-p planar, (c) p-i-n planar, and (d) p-i-n mesoscopic structures………...12Figure 1-10 Schematic illustration of the first TENG...………………...13Figure 1-11 Working modes of the TENG. (a) The vertical contact-separation mode. (b) The lateral sliding mode. (c) The single-electrode mode

. (d) The free-standing mode ………………………………...……14Figure 1-12 Schematic illustration of (a) device fabrication of graphene-based TENGs (b) graphene/EVA/PET-based triboelectric nanogenerators (c) device fabrication of stretchable CG based TENG with electrical output performance……………………………………………………...17

Figure 1-13 Schematic illustration and output performance of bio-waste material based TENG (a) Rice-husk (b) Tea leaves (c) Sun flower powder (SFP) (d) Wheat stalk based TENG………….…………………………18Figure 2-1 Graphene synthesis by LPCVD method……….…………...24Figure 2-2 Schematic diagram of (a) preparation pro

cess of 1L-FG/copper foil (b) Layer by layer assembly method was used for fabricating three-layer graphene over copper foil and then CF4 plasma treatment from top side to form 3L-FG/copper foil…………………….26Figure 2-3 Schematic illustration of fabrication process of F-GFET with FG as gate dielectric ……

……………………………………………….27Figure 2-4 (a) Raman spectra of PG, 1L-FG and 3L-FG after 30 min of CF4 plasma treatment over copper foil. (b) Peak intensities ratio ID/IG and optical transmittance of PG, 1L-FG and 3L-FG. Inset: image of PG and 1L-FG film over PET substrate. (c) Typical Raman spectra of PG, 1L

-FG and 3L-FG on PET substrate. (d) Optical transmittance of PG, 1L-FG and 3L-FG film over PET substrate. The inset shows the optical image of GFETs with FG as gate dielectrics on PET ……….…………30Figure 2-5 XPS analysis result of (a) PG (b) 1L-FG (c) 3L-FG where the C1s core level and several carbon f

luorine components are labeled. The inset shows the fluorine peak (F 1s) at 688.5 eV……………………….32Figure 2-6 (a) Water contact angle of PG, 1L-FG and 3L-FG over PET substrate. (b) The relationship between water contact angle of PG, 1L-FG and 3L-FG and surface-roughness………………………………………33Figure 2-7 (a) I

d vs. Vd of w/o-FG, w/1L-FG and w/3L-FG samples after 30 min of CF4 plasma (b) Id vs. Vg of w/o-FG, w/1L-FG and w/3L-FG samples at a fixed value of drain to source voltage, Vds of 0.5 V (c) Gate capacitance of w/o-FG, w/1L-FG and w/3L-FG samples (d) Gate leakage current of w/o-FG (naturally formed A

l2OX as gate dielectric), w/1L-FG and w/3L-FG samples ……………………………...…………...……...34Figure 2-8 (a) Schematic illustration of bending measurement setup at different bending radius. (i) Device measurement at (i) flat condition (ii) bending radius of 10 mm (iii) 8 mm (iv) 6 mm. Inset shows the photograph

of measurement setup. Change in (b) carrier mobility (c) ION of w/o-FG, w/1L-FG and w/3L-FG samples as a function of bending radius. The symbol ∞ represents the flat condition. Change in (d) carrier mobility (e) ION of w/o-FG, w/1L-FG and w/3L-FG samples as a function of bending cycles (Strain = 1.

56%)…………………………………….38Figure 3-1 Schematic illustration of the flexible top gate graphene field effect transistor with sandwich fluorinated graphene (FG as gate dielectric and substrate passivation layer) ……………………………...…………44Figure 3-2 Raman spectra of (a) PG/PET and PG/FG/PET substrate (b) sandwiche

d FG (FG/PG/FG/PET). Inset showing the optical transmittance of sandwiched FG. (c) HRTEM image for 1L-FG.……………….….…46Figure 3-3 (a) Id vs. Vd of FG/PG/FG device at variable vg (−2 to 2 V). (b) Id vs. Vg of FG/PG/FG. (c) Gate capacitance of FG/PG/FG ….…….48Figure 3-4 Raman spectra of devices under be

nding (a) PG/PET (Inset shows the 2D peak) (b) PG/FG/PET (inset shows the 2D peak) …….…49Figure 3-5 (a) Change in Mobility (b) change in ION of PG/PET and PG/FG/PET as a function of bending radius between bending radii of ∞ to 1.6 mm in tensile mode (c) Change in Mobility (d) Change in ION of PG/PET

and PG/FG/PET as a function of bending cycles. Inset of (c) shows the photograph of F-GFETs with sandwich FG on the PET substrate (e) change in resistance of w/1L-FG, 1L-FG/PG/1L-FG samples as a function of bending radius ………………………...……………….50Figure 3-6 Schematic evolution of proposed strain transf

er mechanism through PG/PET and PG/FG/PET. The inset of PG/PET sample shows the generation of sliding charge due to interfacial sliding between PG and PET ………………………………………………………………….….52Figure 4-1 FGr fabrication and transfer process …………….………....57Figure 4-2 (a) Raman analysis of pristine graphene a

nd the FGr samples after 5, 10, 20, and 30 min of CF4 plasma treatment over Cu foil (b) Raman intensity ratios (I2D/IG and ID/IG) of fluorinated graphene, with respect to the exposure time ……………………………………………60Figure 4-3 SEM images of (a) ITO, (b) ITO/1L-FGr, (c) ITO/2L-FGr, and (d) ITO/3L-FGr …………………

………………………………….61Figure 4-4 XPS analysis of FGr with (a) 5 min (b) 10 min and (c) 20 min of CF4 plasma treatment on the Cu foil (d) The fluorine peak (F1s) of FGr (f) The correlation of the carbon-to-fluorine fraction (C/F) with exposure time and the corresponding carrier concentrations …………….………62Fi

gure 4-5 Tauc plots and UV–Vis absorption spectra of FGr films with CF4 plasma treatment for (a) 5, (b) 10, and (c) 20 min ….………......….63Figure 4-6 WCAs on PEDOT: PSS and 1L, 2L, and 3L FGr samples ...64Figure 4-7 (a) Mechanism of large grain growth of perovskite on a non-wetting surface (b) Top-vi

ew and cross-sectional surface morphologies of perovskites on various HTLs ………………………………...…………65Figure 4-8 XRD of perovskite films on various HTL substrates ….…...66Figure 4-9 UPS spectra of various numbers of FGr layers on ITO: (a) cut-off and (b) valance band spectra …………………………………….….67Figure 4-10

Energy band diagrams of PSCs with (a) PEDOT: PSS, (b) 1L-FGr, (c) 2L-FGr, and (d) 3L-FGr as HTL …………………….…….68Figure 4-11 (a) Steady state PL spectra of PEDOT: PSS/perovskite and FGr/perovskite films. (b) TRPL spectral decay of PEDOT: PSS/perovskite and FGr/perovskite films………………………….……69Figure 4-1

2 (a) Schematic representation of a PSC having an inverted device configuration. (b) Cross-sectional HRTEM image of the ITO/ FGr–perovskite interface………………………………………...………70Figure 4-13 Photovoltaic parameters of PSCs incorporating various HTL substrates: (a) PCE (%), (b) Voc (V), (c) Jsc (mA/cm2), an

d (d) FF (%)....71Figure 4-14 Normalized PCEs of target and control PSCs incorporating various HTL substrates, measured in a N2-filled glove box. (a) Thermal stability at 60 °C (b) Light soaking effect under 1 Sun (c) Stability after several days …………………………………………………………….72Figure 4-15 (a) Schematic r

epresentation of the structure of a flexible PSC on a PET substrate (b) J–V curves of control and target flexible PSCs, measured under both forward and reverse biases. (c) Average PCE of flexible PSCs incorporating PEDOT: PSS and FGr HTLs……….…73Figure 4-16 (a) Normalized averaged PCEs of the flexibl

e PSCs after bending for 10 cycles at various bending radii. (b) Normalized averaged PCEs of the flexible PSCs plotted with respect to the number of bending cycles at a radius of 6 mm ………………………………………………75Figure 4-17 Photovoltaics parameters of flexible PSCs with various HTL substrates: (a) JSC (mA/c

m2), (b) Voc (V), and (c) FF (%) ……………....75Figure 4-18 XRD patterns of perovskite films on PET/ITO/FGr, recorded before and after bending 500 times …………………………………….76Figure 4-19 SEM images of (a) perovskite films/FGr/ITO/PET before bending (b) after bending 500 times (c) perovskite films/PEDOT: PSS/

ITO/PET before bending (d) after bending 500 times ……………….…77Figure 4-20 PL spectra of perovskite films on PET/ITO/FGr, recorded before and after various bending cycles …………………………….…78Figure 5-1 Schematic illustration showing the fabrication process of a flexible Gr-TENG with Al2O3 as the CTL ……………

………………...83Figure 5-2 The Raman spectra of (a) graphene/Al-foil/PET and (b) graphene/Al2O3/Al-foil/PET. The I2D/IG of graphene layers (1L, 3L and 5L) over (c) Al-foil/PET substrate (d) Al2O3/Al-foil/PET substrate …...85Figure 5-3 XRD patterns of (a) graphene/Al-foil/PET and (b) graphene/Al2O3/Al-foi

l/PET ……………………………………………86Figure 5-4 FESEM image of the graphene surface on (a) Al-foil/PET and (b) Al2O3/Al-foil/PET. EDS analysis of (c) graphene/Al-foil/PET and (d) graphene/Al2O3/Al-foil/PET (e) EDS elemental mapping of the graphene/Al2O3/Al-foil/PET presenting C K series, O K series and Al K ser

ies …………………………………………………………….………87Figure 5-5 3D AFM images of (a) 1L-Gr (b) 3L-Gr (c) 5L-Gr on Al foil (d) 1L-Gr (e) 3L-Gr (f) 5L-Gr on Al2O3/Al foil………………….….….89Figure 5-6 Work function of graphene layers on the (a) Al-foil (b) Al2O3/Al-foil substrate by KPFM. Inset showing the surface potential of

graphene layers (1L, 3L and 5L) over Al-foil and Al2O3 substrate (c) energy band diagrams for 1L-Gr, 3L-Gr and 5L-Gr over Al2O3 ……....90Figure 5-7 Schematic illustration of Electronic energy levels of graphene samples and AFM tip without and with electrical contact for three cases: (i) tip and the

1L-Gr (ii) tip and the 3L-Gr and (iii) tip and the 5L-Gr over Al2O3/Al foil/PET……………………………………….…...…………91Figure 5-8 Working mechanism of Gr-TENG with Al2O3 ….….…...…93Figure 5-9 a) ISC and (b) VOC of 1L-, 3L- and 5L-Gr-TENGs without Al2O3 CTL (c) Sheet resistance of graphene as a function of number

of layers ………………………………...…...…………………………….95Figure 5-10 Electrical output of the Gr-TENG with Al2O3 CTL: (a) ISC and (b) VOC of 1L-, 3L- and 5L-Gr. Magnification of the (c) ISC and (d) VOC of the 3L-Gr-TENG with Al2O3 as the CTL. Average mean (e) ISC and (f) VOC generated by pristine Gr-TENGs (1L, 3L

and 5L) and Gr-TENGs (1L, 3L and 5L) with Al2O3 CTL. Error bars indicate standard deviations for 4 sets of data points ……………...…………….….…......96Figure 5-11 (a) CV of Al/Al2O3/3L-Gr/Al at 100 kHz and 1 MHz (b) CV hysteresis of 3L-Gr-TENG with Al2O3 as CTL with different sweeping voltages (c) Surface

charge density of graphene (1L, 3L and 5L)-based TENG with and without Al2O3 as CTL ………………………………...98Figure 5-12 Circuit diagram of output (a) VOC and (b) ISC measurement of 3L-Gr TENG with Al2O3 CTL as a function of different resistors as external loads. Variation in VOC and ISC w.r.t different re

sistors as external loads of (c) 3L-Gr TENG with Al2O3 CTL (d) 3L-Gr TENG without Al2O3 CTL. Relationship between electrical output power and external loading resistance (e) 3L-Gr TENG with Al2O3 CTL (f) 3L-Gr TENG without Al2O3 CTL…………………………………….………………...99Figure 5-13 (a)Electrical stability and du

rability of the 3L-Gr TENG with Al2O3 (b) Schematic illustrations showing the charge-trapping mechanism of 3L-Gr-TENG without and with Al2O3 charge trapping layer ………101Figure 5-14 (a) Photograph showing 20 LEDs being powered (b) Circuit diagram of bridge rectifier (c) Charging curves of capacitors

with various capacitances (d) Photograph of powering a timer …….………………102Figure 6-1 The schematic diagram of the fabrication process for SCG powder based TENG ……………………………………………….….108Figure 6-2 The schematic diagram of the fabrication process for SCG thin-film based TENG via thermal evaporation meth

od ………………109Figure 6-3 FESEM image of (a) SCG powder (inset image illustrates the high magnification of SCG powder) (b) SCG thin-film/Al foil/PET (inset image illustrates the high magnification of SCG thin-film). EDS of the (c) SCG powder (d) SCG thin-film/Al foil/PET…………………………. 112Figure 6-4 Raman

spectra analysis (a) pristine SCG powder (b) SCG thin-film/Al foil/PET. XRD patterns of (c) SCG powder (d) SCG thin film with different thickness ……………………………………… ……….115Figure 6-5 FTIR analysis of the (a) pristine SCG powder sample (b) SCG thin film………………………………………………………………...116Figure 6-6 3D AFM ima

ge of SCG thin-film with various thickness (a) 50 nm (b)100 nm and (c) 200 nm……………………………………...117Figure 6-7 Schematic illustration of working principle of SCG thin-film based TENG …………………………………………………………...119Figure 6-8 Finite element simulation of the generated voltage difference for SCG thin-film b

ased TENG based on the contact and separation between SCG thin film and PTFE …………….……………………….120Figure 6-9 (a) The setup for electrical property testing, which including a Keithley 6514 system electrometer and linear motor. Electrical output (b) ISC (c) VOC of TENGs based on different friction pairs

for checking the triboelectric polarity of SCG…………………………………………...123Figure 6-10 Electrical measurement of (a) ISC and (b) VOC of the SCG thin-film based TENG. Mean value of (d) ISC (e) VOC and (f) Output power density of the pristine SCG powder and thermal deposited SCG thin-film based TENG. ...………

………………………………………125Figure 6-11 (a) Schematic illustration of KPFM for measuring the work function. (b) Surface potential images of SCG thin film with various thickness (50 nm, 100 nm and 200 nm). (c) Surface potential and (d) Work function vs SCG thin film with various thickness (50 nm, 100 nm and 20

0 nm).………….……………………………………………….128Figure 6-12 (a) Isc and (b) Voc of SCG thin film based TENG under different contact frequencies (c) Isc and (d) Voc of SCG thin film based TENG under different separation distance…………………………….129Figure 6-13 Electrical response (a) ISC (b) VOC of pristine SCG powder an

d (c) ISC (d) VOC of SCG thin-film based TENG with respect to different relative humidity (35-85% RH) …………………………….131Figure 6-14 Electrical stability and durability test of the output performance of (a) pristine SCG powder based TENG (b) SCG thin-film based TENG……………………………………………………………132Figure 6-15

Applications of the SCG thin film based TENG as a power supply: (a) Circuit diagram of the bridge-rectifier for charging a capacitor (b) Charging curves of capacitors with various capacitances (0.1, 2.2 and 3.3 µF) (c) Photograph of powering a timer…………………...………133Figure 7-1 Schematic illustration o

f FG based TENG…….….……….139Figure 7-2 Working mechanism of FG based TENG…………………140Figure 7-3 Electrical output of FG-TENG: (a) Isc and (b) Voc …….….141Table captionsTable 2-1 Comparison of flexible G-FETs on/off ratio of our work with other’s work…………………………………………………...………...40Table 3-1 Summary of th

e electrical and mechanical performance of flexible w/o-FG, w/ 1L-FG, w/3L-FG and sandwich FG (FG/PG/FG) samples......................................................................................................52Table 3.2: Comparison of the electrical and mechanical performance of sandwich FG ba

sed F-GFET with previous F-GFET with different gate dielectrics……………………………………………………….………53Table 4-1 Best photovoltaic performance from control and target devices prepared on rigid and flexible substrates……………………………......74Table 5-1 EDS elemental analysis of graphene over Al-foil/PET and Al2O3/Al-foi

l/PET ………………………………………………………88Table 5-2 Comparison of electrical output performance of Gr-TENGs with and without Al2O3 CTL samples used in this study………………103Table 6-1 EDS elemental analysis of SCG-Powder and SCG thin film /Al foil/PET………………………………………………………………...113Table 6-2 Comparison of electrical o

utput performance of SCG-TENGs samples used in this study……………………………………………...126

可自我修補導電超分子膠體於多功能感測器及自供電能量收集元件之應用

為了解決Free font generator的問題，作者艾米爾 這樣論述：

考慮到凝膠的優點，具有導電自修復凝膠是下一代可穿戴式裝備最有潛力的選擇。在此研究中，我們統整了自修復凝膠的研究現況與進展以及設計策略與應用。到目前為止，基於自修復凝膠的傳感器與能量裝置在人體運動測量和能量收集方面提供了極具吸引力的可能性。然而，基於此凝膠的研究仍處於起步階段，且尚未從理論實現至實際應用。還需要考慮一些因素，例如，在不影響其他的功能情況下，凝膠的設計和準備過程需要仔細考慮靈敏度。凝膠裝備的工作範圍也是另一個值得注意的因子。除此之外，機械性能對於自修復凝膠裝備非常重要。幸運的是，凝膠基質中的配位鍵與交聯劑的存在可以增強機械性質，如高強度和快速修復。機械性能也需要根據所需的應用進行

最佳化，當可穿戴裝備由凝膠製成時，環境穩定性與長時間穩定性就顯得非常重要了。與傳統的彈性體裝備不同，它可能會在乾在的環境下可預見地喪失水分，並在零下溫度凍結。換句話說，凝膠裝備會在惡劣環境下失去功能，使的它們不適合拿來應用。因此，引入自修復能力與適合的聚合物，在所有環境下可以修復結構上的損傷並恢復感測能力，將大大提升導電凝膠的使用壽命。如第一章和第二章所討論的，很少有策略會以選擇材料來獲得需要的性質。本篇論文中，第三章合成並開發了含有聚硫辛酸(PTA)、Fe3+離子、焦蜜石酸 (PTA)和互穿聚苯胺(PANI)的協同超分子網絡導電自修復凝膠(CSGs)。通過這些物理鍵(氫鍵、離子鍵、配位鍵)互

相固定的非共價鍵網路提供了可逆的超分子鍵結，並可以自由成型且可注射的。這有助於高拉伸性(超過50倍伸長率)以及機械性和電性時間尺度分別為90秒和0.7秒的超快速自我修復。最佳超分子凝膠傳感器展現出出色的應變敏感性(應變係數 = 11)以及高可調壓力靈敏度(2.8 KPa-1)。穩定的電性、高耐用性(> 800 次循環)和對各種材質的優異黏附性能有助於檢測人體大的(關節運動)和細微的(肌肉運動)形變。還可以通過人體運動檢測、黏合劑的應用、3D列印的可注射式導電墨水來進一步研究多功能CSGs的實際應用。具有可自我修復且有廣泛工作溫度範圍的可變形能量收集設備仍然是自主軟性電子產品的挑戰。在此，第四章

報導了可自修復、可拉伸和完全抗凍的摩擦起電奈米發電凝膠(TENG)，其工作溫度範圍為 -40 至 80°C。首先，通過將聚硫辛酸與 Fe3+ 和植酸(PA)的超分子交聯劑混合製備電極凝膠，並加入導電聚合物聚(3,4-亞乙基二氧噻吩)聚苯乙烯磺酸鹽 (PEDOT:PSS)。第二，使用氨基和羥基封端的聚（二甲基矽氧烷）(PDM)以及異佛爾酮二異氰酸酯和矽油產生摩擦電凝膠層。這些凝膠網路由具有可逆物理鍵的超分子相互作用構成，能提供高達50倍應變的高拉伸性和快速自癒性(電極凝膠為4分鐘，摩擦層凝膠為24小時)。所得凝膠TENG即使在5000次循環操作後也表現出優異的性能，並且在多次切割/自修復後仍然表

現出穩定的性能。它的輸出增加當被雙軸拉伸至 150% 應變仍然保持彈性，確保其彈性的適用性。此外，能量收集能力經驗證適用於 -40 至 80°C。最後，從TENG凝膠收集的能量被證明可以為商業電子產品供電。多年以來，人們一直試圖模仿人類的舌頭。然而，由於損耗、溫度影響、檢測範圍等限制，它們仍然有侷限性。在第五章中，合成了一種自修復水凝膠的人工生物電子舌(E-tongue)，以黏蛋白作為分泌蛋白，氯化鈉作為離子傳輸電解質，殼聚醣/聚（丙烯酰胺-共聚丙烯酸）作為保持水凝膠網絡的主要3D結構。引入這種電子舌是為了模擬澀味和苦味，使用循環伏安法(CV)對目標物質進行測量，可再29.3 mM- 0.59

µM和63.8 mM- 6.38 µM的範圍內檢測澀味單寧酸 (TA)和苦味硫酸奎寧(QS)，靈敏度分別為0.2和0.12 wt%-1。這種電子舌的味覺選擇性是在混合多種具有味道的化學物質下進行的，以顯示其對苦澀化學物質的高選擇性。電自癒性通過CV響應顯示，以說明短時間內的電性恢復。此外，還使用了HeLa細胞進行細胞毒性測試，其中≥ 95 %的明確存活率證明了其生物相容性。電子舌在-5°C時的具有抗凍感應表明這項工作在低於零的環境中是有優勢的。實際使用飲料和水果檢測口味，以確認未來在食品口味檢測和類人機器人中具有潛在應用。