• 研究论文 •
范路洁, 陈莉, 何崟, 刘皓. 基于3D导电材料的柔性应力/应变传感器[J]. 化学进展, 2021, 33(5): 767-778.
Lujie Fan, Li Chen, Yin He, Hao Liu. Flexible Pressure/Strain Sensors Based on 3D Conductive Materials[J]. Progress in Chemistry, 2021, 33(5): 767-778.
柔性应力/应变传感器作为智能可穿戴设备的重要组成部分,在人体运动检测、健康监测、机器人和电子皮肤等方面得到了广泛应用。其中,3D导电材料(如气凝胶、海绵和泡沫等)不仅拥有3D互连微结构,还具有优异的可压缩性和导电性,在一定程度上解决了传感器同时拥有高灵敏度和宽检测限的难题。本文根据制备3D导电材料的原材料将其划分为生物质材料、碳材料、聚合物材料、金属纳米材料以及MXene材料五种类型;并总结了3D导电材料的制备方法及其在传感器应用领域的创新与发展;最后讨论了基于3D导电材料的柔性应力/应变传感器的发展前景。
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Materials | Methods | Transduction Mechanisms | Gauge Factor or Sensitivity(Kpa-1) | Detection limit/Pressure range | Response Time(ms) | Stability (cycles tested) | ref |
---|---|---|---|---|---|---|---|
PDOT:PSS/CNF /PDMS | 1)Freeze-drying 2)Annealing | Resistance/ strain | GF=14.8(~95%) | - 100% strain | - | 4000 | |
PPy/cellulose | 1)Freeze-drying 2)In-situ polymerization | Resistance/ pressure | 58.9(0~5 kpa) 0.7(5~20 kpa) | - 20 kpa | - | - | |
Natural Wood | 1)Chemical treating 2)Freeze-drying 3)carbonization | Resistance/ pressure | - | - 80% | - | 10 000 | |
Wood/PDMS | 1)Chemical treating 2)Freeze-drying 3)carbonization | Resistance/ pressure | 10.74(0~100 kpa) | - 100 kpa | 20 | 13 000 | |
BC/MWCNTs | 1)supercritical CO2 method | Resistance/ strain | GF=21(~16% ) | - 16% strain | 390 | 1000 | |
Chitosan/Carbon black | 1)Freeze-drying 2)stirring | Resistance/ pressure | GF=7.5(~ 10%) | 1.33% 85% | - | 200 | |
KGM/SiO2 | 1)Electrospinning 2)Freeze-drying 3)carbonization | Resistance/ pressure | 0.43(0~3 kpa) 1.02(>3 kpa) | 10 pa 5 kpa | - | 1000 |
Materials | Methods | Transduction Mechanisms | Gauge Factor or Sensitivity(Kpa-1) | Detection limit/Pressure range | Response Time(ms) | Stability (cycles tested) | ref |
---|---|---|---|---|---|---|---|
GR/Carboxymethyl cellulose | 1)Freeze-drying 2)carbonization | Resistance/ pressure | GF=1.58 | - 70% | - | 4000 | |
GRO/cellulose nanocrystals/X | 1)Freeze-drying 2)carbonization | Resistance/ pressure | GF=369.4(<0.012%) GF=5.81(<5%) | 0.25 pa 99% | - | 10 000 | |
GRO/PU sponge/ Natural Rubber | 1)Removal template | Resistance/ strain | GF=210(10%~40%) | - 60% | 370 | - | |
GRO/ Polyorganosiloxane | 1)Crosslinking | Resistance/ pressure | - | 10 pa 110 kpa | - | 10 000 | |
CNT/PI | 1)Freeze-drying 2)Annealing | Resistance/ pressure | 11.28(0~5 kpa) 0.33(15~60 kpa) | 10 pa 61 kpa(80%) | 50 | 1000 | |
CNT/rGO-CNF | 1)Freeze-drying 2)Annealing | Resistance/ pressure | 22.05(0~100 pa) 11.82(0~1 kpa) 0.44(1~-5 kpa) | 0.875 pa 5 kpa | - | 50 000 | |
GO-MWNT | 1)3D-printing | Resistance/ strain | - | - 200% | - | 106 |
Materials | Methods | Transduction Mechanisms | Gauge Factor or Sensitivity(Kpa-1) | Detection limit/Pressure range | Response Time(ms) | Stability (cycles tested) | ref |
---|---|---|---|---|---|---|---|
PVA/CuNW | Freeze-drying | Resistance/ pressure | 0.267(<10 kpa) | <500 pa 60% | - | - | |
PDMS/GR/ NH4HCO3 | Removal template | Capacitance/ pressure | 0.12(0~10 kpa) 0.042(10~100 kpa) 0.004(100~500 kpa) | 5 pa 500 kpa | 7 | >5000 | |
TPU/CARBON NANOSTRUTURE /POPCORN SALFs | Removal template | Resistance/ pressure | GF=1.5(0~60%) | 1% 60% | - | - | |
PU/CNFs/AgNW | Coating | Resistance/ pressure | GF=26.07(0~0.06%) | - 80% | - | 500 | |
PU/AU | Gold ion sputtering | Resistance/ pressure | 0.059(0~4.7 kpa) 0.096(4.7~10.2 kpa) 0.122(10.2~14.2 kpa) | 0.568 pa 60% | 9 | 1000 | |
MF | carbonization | Resistance/ pressure | 100.29(0~2 kpa) 21.22(2~10 kpa) | 3 pa 10 kpa | - | 11 000 |
Materials | Methods | Transduction Mechanisms | Gauge Factor or Sensitivity(Kpa-1) | Detection limit/Pressure range | Response Time(ms) | Stability (cycles tested) | ref |
---|---|---|---|---|---|---|---|
AgNW/PU FOAM | Coating | Resistance/ Pressure and strain | - | 80% | - | 1000 | |
AgNP/PDMS | Removal template | Piezoelectric/ pressure | 50(<4 kpa) 1.8(4~110 kpa) 0.8(110~200 kpa) | 4.1 pa 200 kpa | 200 | 50 000 | |
CuNW | Freeze-drying | Resistance/ pressure | 0.02~0.7(0~210 pa) | - | 80 | - | |
CuNW/PVP/PDMS | Carbonization | Resistance/ pressure | 0.00711(0~35 kpa) | 640 pa 35 kpa- | 16 | 1000 | |
Cu-Ag NWs/rGO/ SBS | Doping | Resistance/ Strain | GF=87 362 | - 374% | - | - |
Materials | Methods | Transduction Mechanisms | Gauge Factor or Sensitivity(Kpa-1) | Detection limit/ Pressure range | Response Time(ms) | Stability (cycles tested) | ref |
---|---|---|---|---|---|---|---|
MXene/rGO | Freeze-drying Annealing | Resistance/ Pressure | 4.05(<1 kpa) 22.56(>1 kpa) | 10 pa 30 kpa | 242 | 10 000 | |
MXene/CNCs | Freeze-drying Annealing | Resistance/ pressure | 45.5(0~10 kpa) | 1 pa 10 kpa | 189 | 10 000 | |
MXene/BC | Freeze-drying Annealing | Resistance/ pressure | 12.5(0~10 kpa) | 1 pa 10 kpa | 167 | 100 000 | |
MXene/PU FOAM | Coating | Resistance /pressure | 147(<5.37 kpa) 132(5.37~18.6 kpa) | 9 pa 18.6 kpa | 138 | 10 000 | |
MXene/CS/PU FOAM | Coating | Resistance/ pressure | 0.014(0~6.5 kpa) 0.015(6.5~85.1 kpa) | 9 pa 85% | 19 | 5000 | |
MXene/PS/GO | Freeze-drying Annealing | Resistance/ pressure | 61(<3.3 kpa) 334(3.3~6.4 kpa) 609(>6.4 kpa) | 6 pa 10 kpa | 232 | 6000 |
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