Microchannel Structural Design For a Room-Temperature Liquid Metal Based Super-stretchable Sensor


Room-temperature liquid metal has been widely used in flexible and stretchable sensors, focusing on embedding liquid metal in microchannels, liquid metal microdroplets formation, captive sensors, and liquid metal nanoparticles, etc. In this paper, a facile Eutectic Galium-Indium (EGaln) liquid-based microfluidic high-sensitivity, skin-mountable, and ultra-soft stretchable sensor is developed. It comprises Ecoflex microfluidic assembly filled with EGaln, which serves as the working fluid of the stretchable sensor. The lithography method is applied to achieve microfluidic channel. The microfluidic channel is optimized by using topology method and finite element analysis, making this device with high conformability and high stretchability. This method achieved an outstanding effect on elastomer-encapsulated strain gauge, which displays an approximately linear behavior with a gauge factor (GF). The GF could reach as high as 4.95 when the strain ultimately reached 550%. Applications of detection of the joints, fingers, and wrists has been conducted and showed excellent results. This work can further facilitate the exploration and potential realization of a functional liquid-state device technology with superior mechanical flexibility and conformability.


Flexible and stretchable sensors have attracted substantial attention due to their unique characteristics, such as low modulus, light weight, high flexibility, and stretchability1,2,3,4,5,6. And flexible and stretchable sensors are widely used in emerging applications. These include soft robotics7, wearable consumer electronics8,9, e-skins10,11. As the demands for these applications increase, the requirements for flexible and stretchable sensors will be more stringent12. However, traditional metallic and semiconducting sensors only withstand very limited stretchability before fracture. Thus, they are not suitable for stretchable applications13,14. Aimed at this problem, diverse methods and strategies are proposed to achieve the stretchability. Some strain sensors used structuring of easy to stretchable, such as spring, buckling, wave15,16,17,18,19. The stretchability of the vast majority of sensors is achieved by embedding, depositing, and printing the conductive material and the substrate20,21,22,23,24. Diverse flexible and stretchable substrates25,26, novel mechanically durable materials27,28,29, deformable electrodes and novel processing technology30,31 is promising for the development of stretchable sensors in the near future driving innovations in stretchable sensors for emerging applications at a tremendous pace.

However, these sensors are not able to remain functional at strains over 100%, which limited by large-scale stretchability occasions. At the same time, material delamination and/or local fracture in rigid electronic components are frequently observed in stretchable sensors. The main reason for the poor durability is that there is an intrinsic difference in the Young’s modulus between the rigid conductors and the soft support material. To solve the problem of Young’s modulus mismatch, many materials have been explored. Liquid conductors have attracted substantial attention32,33,34,35, due to their advantages of low Young’s modulus and high durability, which are maintained even under a large strain. Awareness has grown among researchers that using softer liquid materials to generate stretchable conductors is a promising method to fabricate high-performance stretchable sensors. Wenlong Cheng fabricated reliable and long-term stretchable sensors using ionic liquids, which overcome the mechanical-mismatch problem31. A particular type of conductive liquid material that is eutectic gallium-indium (EGaln) come into people’s perspective35,36,37,38,39,40,41. EGaln is an alloy of gallium and indium that can maintain a liquid state at room temperature. Due to high surface tension and high electrical conductance42, EGaln is an ideal conductor for a stretchable and flexible sensor. However, the stretchable and flexible sensor with EGaln conductor also exist a drawback that is low gauge factor(GF)31. Here, we explore the GF influence factors, and design a reasonable microfluidic channel to increase the GF of stretchable and flexible sensor. And then the lithography technology is applied to establish a relative smooth microfluidic channel. The way of EGaln is injected into the microfluidic channel of Ecoflex elastomer is used to offer a sensor with high stretchability, high conformability.

Production Procedure

The entire production process is shown in Fig. 1 below. At first, the SU-8 2100 negative photoresist was spin-coated on the silicon wafer by 500 rpm (ramp rate of 100 rmp/s) for 7 s, followed by 1500 rmp (ramp rate of 100 rmp/s) for 60 s. This was followed by pre-exposure baking at 65 for 5 min and 95 for 30 min. Then the SU-8 layer was patterned using ultraviolet (UV) lithography by mask aligner (Karl Suss MJB3) for 53 s (130 mj/cm2 exposure energy). Samples were post-exposure baked at 65 for 5 min and 95 for 15 min. After cooling to room temperature, samples were soaked in SU-8 developer (MicroChem®) to chemically remove uncrosslinked material from the SU-8 layer. Next, Ecoflex was spin-coated on the silicon wafer with microfluidic channel and heated by heating plate at 60 °C. After the Ecoflex has solidified, the Ecoflex was peeled from the silicon wafer. Used same method fabricated Ecoflex flexible substrate without microfluidic channel. And then two Ecoflex flexible substrate was adhered to together. In last, the EGaln was injected in the microfluidic channel of the Ecoflex flexible substrate.

Figure 1

Schematic illustration of the fabrication of the highly flexible and stretchable EGaln microchannel.

A microfluidic channel was created; optical micrographs of the patterns are shown in Fig. 2. Using this method, we were able to create microfluidic channel with high resolution crescent, which can meet the requirement of the size and flatness.

Figure 2

Photo of SU-8 microchannel on the silicon wafers fabricated by lithography.

Results and Discussion

Device design and working mechanism

This flexible and stretchable sensor operates based on a deformability-dependent resistive sensing mechanism, which can be described by Equation 142

$${\rm{\Delta }}R=R-{R}_{0}=\rho \frac{L+{\rm{\Delta }}L}{(\omega +{\rm{\Delta }}\omega )(h+{\rm{\Delta }}h)}-\rho \frac{L}{\omega h}$$

Where R and R0 are the resistances of the microchannel when stretched by ΔL and not stretched, respectively, \(\rho \) is the electrical resistivity of EGaln, L is the length of the microchannel, and \(\omega \) and h are the width and height of the cross-section of the microchannel, respectively. When the surface of the device is stretched, the microfluidic channel experiences a minute stretchability deformation, this leads to a decrease the cross-sectional area of the channel and increase the length of the channel which, in turn, results in an increase in the resistance of the EGaln across the microfluidic channel. However, upon the release of the external pressure and due to the elastic property of the Ecoflex, the microfluidic channel will recover to its original state. At the same time, the resistance value will return to the initial state. In this work, the specific increase and decrease in the electrical resistance of the EGaln correspond to the characteristic response of different mechanical forces applied on the tactile sensor. The actual fabricated tactile sensing device is shownin Fig. 3. Generally, EGaln liquid based flexible microfluidic flexible and stretchable sensor exhibits several distinctive features, such as superior thinness, high flexibility, large area conformability, and small physical size.

Figure 3

Image of liquid-based microfluidic stretchable sensor with outstanding property for flexibility, conformability and stretchability.

Mechanical deformation characterization

To execute its designated functions robustly and effectively, EGaln microchannel sensor need to have feature of high degree of flexibility, conformability and stretchability as well as be capable of withstanding a wide range of mechanical deformation, such as stretching, bending and twisting. In order to understand the performance of EGaln microchannel sensor, the force distribution of EGaln microchannel sensor corresponding to stretching, bending and twisting is analyzed by the analogue simulation. Figure 4 show the force distribution condition. The force distribution uniformly of device when stretched. Even if the stretchability up to 300%, this sensor don’t appear the high stress condition, which can prevent fatigue failure, making the sensor with a high stretchability. This explain the microchannel designed reasonable that don’t damage structure strength of the flexible substrate. The microchannel show uniformity deformation when stretched, contributing to create outstanding linearity sensor and establish the relationship of deformation and resistance change. What’s more, this device don’t appear high stress when bent and twisted, which well-illustrates this device can achieve the designated function robustly and effectively, not making the function failures due to high stress fatigue damage.

Figure 4

Schematic diagram of liquid-based microfluidic stretchable sensor on condition of stretchability, bend and wrinkle. (a) Schematic diagram of liquid-based microfluidic stretchable sensor tensile force corresponding to 100%, 200% and 300%. (b) Schematic diagram of liquid-based microfluidic stretchable sensor bending force corresponding to angle of 90°, 180° and 270°. (c) schematic diagram of liquid-based microfluidic stretchable sensor fold force corresponding to angle of 15°, 30° and 45°.

To further evaluate and quantify the structural strength of flexible EGaln microchannel sensor, the device is handled by loading test and meticulous observe the change of the microchannel. Figure 5 show the flexible EGaln microchannel sensor without experiences loading test and EGaln being confined within the channels without leakage. Then the flexible EGaln sensor was stretched several times by the parallel direction, in addition to the cross section area get small without any failure modes. Then flexible EGaln microchannel sensor was loaded by the way of bending and twisting in different direction and angle several times. The experimental result depicts that the channel with well-maintained structure without cross section area change, edge coarse and leakage. This express flexible EGaln microchannel sensor with outstanding mechanical stability even if on condition of experience several forms of mechanical deformations. In other words, as a liquid state device, flexible EGaln microchannel sensor displayed excellent mechanical deformability with superior working fluid confinement. It is worth noting that several bonding forms for Ecoflex was explored to enhance working fluid confinement. Three distinct bonding strategies respectively are thermal bonding, ozone treatment and oxygen plasma treatment that seem to not achieve the ideal effect for Ecoflex bonding. On condition of performing many groups experiments, two Ecoflex have not bonded together successfully. Aimed this condition, the room temperature solidification was used to bond two Ecoflex. Firstly, the Ecoflex was spin-coated on the silicon wafer with microchannel, the Ecoflex was peeled from the silicon wafer after the Ecoflex is in the complete solidification. Another Ecoflex is was spin-coated on the silicon wafer without microchannel for 25 min, which the Ecoflex is in the condition of half solidification that put on bonding not only damage the channel structures, but also complete bond together. Due to the two Ecoflex substrates complete bond together, the peel test by pulling the two substrates don’t separate the two Ecoflex substrates.

Figure 5

(a) Photograph of the device with no applied deformation (left) with the corresponding microscopy image of the EGaln in microfluidic channel (right). (b) Photograph of the device being stretched in a direction parallel to the channel (left) with the corresponding microscopy image showing that the EGaln confinement was well maintained within the channel (right). (c) Photographs of the device as it underwent different forms of user applied deformation: twisting, bending and compressing. (d) Photograph of the same device after it went through all the different mechanical deformations (left) with the corresponding microscopy image showing the integrity of the EGaln confinement within the microchannel (right).

Performance analysis

This sensor has already demonstrated preeminent mechanical performances which suffered no structural damage on condition of high strength mechanical charging. The flexible EGaln microchannel sensor is device that to accomplish design functions. It isn’t not enough that this sensor only has high mechanical durability. The sensor working mechanism is the change of resistance corresponding to the change of the cross-sectional area of the microchannel as the sensor stretched. The cross-sectional area of the microchannel of this sensor gets smaller when stretched, leading to the resistance gets bigger. In general, it is helpful to accomplish design functions that more obvious increased resistance value and outstanding linear relationship of increased resistance value and strain. The response characteristic of flexible EGaln microchannel sensor was conducted. The Gauge factor is one important index to measure the sensitivity of strain sensors, which can be determined by Equation 2.

$$\mathrm{GF}=\frac{{{\rm{\Delta }}{\rm{R}}/{\rm{R}}}_{{\rm{O}}}}{{\rm{\varepsilon }}}$$

Where GF is the gauge factor of the stretchable sensor. ΔR is the change of the sensor’s resistance when stretching. Ro is the sensor’s original resistance without any stretch. ε = ΔL/Lo, which is the sensor strain. ΔR is the change of the sensor’s length when stretching. Ro is the sensor’s original effective length without any stretch. According to the calculation, the GF could reach as high as 4.95 when the sensor was ultimately stretched to 550%, and it was stretched broken nearly reaching 590%, which showed excellent sensitivity for the EGaln based sensors. The detailed relationship between GF and strain is shown in Fig. 6(a). Besides the outstanding sensitivity, some properties including comfortableness, repeatability, etc., are also essential effects for the wearable sensor to satisfy the requirements of human monitoring. According to the repeatable experiments, the sensor just generated minor stress change even through suffer large-scale stretch. Line x-y3 in Fig. 6(b) signify the condition of the tensile force and strain, which can decrease discomfortableness caused by excessive stress. Line x-y1 and Line x-y2 in the Fig. 6(b) signify first and fifth stretchability curve respectively. These two lines are almost overlapping. which shows the excellent repeatability of the sensor in case of multiple stretches. The great repeatability not only can offer accuracy monitoring parameter for subsequent analysis after several times uses, but also can satisfy human monitoring during movements.

Figure 6

(a) The relationship between GF and strain. (b) The relationship of resistance change and strain (blue lines), x-y1 and x-y2 signify first stretchability and fiftieth stretchability. Photograph of relationship of tensile force and strain (orange line), x-y3 signify the condition of the tensile force and strain. Photographs of this sensors attached on the joint (c)/fingers (d)/wrists (e) of different motions, and corresponding resistance change.

To further demonstrate the reliability and practicality of flexible EGaln microchannel sensor, we attached this device to our human hand and probed its capability in recognizing different hand gestures. As a proof of concept of its application in detecting and differentiating various hand muscle induced motions, the tactile sensor was attached to the finger, wrist and joint and its dynamic pressure responses were monitored while different hand motions were executed. Figure 6(c) shows that the great change of sensor resistance will be chance when stretched. This result proved this sensor with outstanding strain performance, making it is easy to recognize the gesture of hand. There is no question for detecting the large-scale tensile strain. At the same time, the tensile scale will be gradually decreased, the change of sensor resistance still effective as shown in Fig. 6(d). The resistance make corresponding changes with the different bending angle and the resistance presents periodic to some extent, which explains this sensor with outstanding fatigue resistance and can pick up loading for a long time before fracture. What’s more, this sensor was applied on the wrist that can realize different rotary angles, the different rotary angles corresponding to different resistance change value, from the other way to explain this sensor with highly sensitivity that can catch angular variation accurately as shown in Fig. 6(d).


We have demonstrated a flexible and stretchable EGaln microchannel sensor. The use of EGaln as the sensing element provides high sensitivity corresponding at the large-scale stretchability and EGaln as flexible substrate provides strength supporting of large-scale stretchability. The method of lithography was applied to establish channel that meet the requirement of size and flatness. Using the advance bonding way to stick two Ecoflex together, contributing to EGaln microchannel sensor with excellent mechanical deformability and superior working fluid confinement. Furthermore, this method is applied to the fabrication of an elastomer-encapsulated strain gauge that displays an approximately linear behavior. The gauge factor can reach as high as 4.95 when the strain reached the ultimate 550% strain,, which enormous increase value of gauge factor for the flexible sensor based on EGaln as conductor. This kind of sensor is easy to follow human skin mechanical deformations of bending and twisting that show the outstanding potential for emerging applications.


  1. 1.

    Trung, T. Q. & Lee, N. E. Flexible and Stretchable Physical Sensor Integrated Platforms for Wearable Human-Activity Monitoringand Personal Healthcare. Advanced Materials 28, 4338–4372 (2016).

    CAS  Article  Google Scholar 

  2. 2.

    Dickey, M. D. Stretchable and Soft Electronics using Liquid Metals. Advanced Materials 29, 1606425 (2017).

    Article  Google Scholar 

  3. 3.

    Khoshmanesh, K. et al. Liquid metal enabled microfluidics. Lab on A Chip 17, 974–993 (2017).

    CAS  Article  Google Scholar 

  4. 4.

    Chen, J. et al. Polydimethylsiloxane (PDMS)-based flexible resistive strain sensors for wearable applications. Applied Sciences 8, 345 (2018).

    Article  Google Scholar 

  5. 5.

    Chossat, J. B., Park, Y. L., Wood, R. J. & Duchaine, V. A Soft Strain Sensor Based on Ionic and Metal Liquids. IEEE Sensors Journal 13, 3405–3414 (2013).

    ADS  CAS  Article  Google Scholar 

  6. 6.

    Gao, Q. et al. Highly stretchable sensors for wearable biomedical applications. Journal of Materials Science, 1–37 (2019).

  7. 7.

    Majidi, C. Soft Robotics: A Perspective—Current Trends and Prospects for the Future. Soft Robotics 1, 5–11 (2014).

    Article  Google Scholar 

  8. 8.

    Gong, S. et al. A wearable and highly sensitive pressure sensor with ultrathin gold nanowires. Nature Communications 5, 3132 (2014).

    Article  Google Scholar 

  9. 9.

    Xu, S. et al. Soft microfluidic assemblies of sensors, circuits, and radios for the skin. Science 344, 70–74 (2015).

    ADS  Article  Google Scholar 

  10. 10.

    Hammock, M. L., Chortos, A., Tee, C. K., Tok, B. H. & Bao, Z. 25th Anniversary Article: The Evolution of Electronic Skin (E‐Skin): A Brief History, Design Considerations, and Recent Progress. Advanced Materials 25, 5997–6038 (2013).

    CAS  Article  Google Scholar 

  11. 11.

    Park, S. et al. Silicones for Stretchable and Durable Soft Devices: Beyond Sylgard-184. Acs Applied Materials & Interfaces 10 (2018).

  12. 12.

    Kenry et al. Highly Flexible Graphene Oxide Nanosuspension Liquid-Based Microfluidic Tactile Sensor. Small 12, 1593–1604 (2016).

    CAS  Article  Google Scholar 

  13. 13.

    Cheng, Y., Wang, R., Sun, J. & Gao, L. A Stretchable and Highly Sensitive Graphene-Based Fiber for Sensing Tensile Strain, Bending, and Torsion. Advanced Materials 27, 7365–7371 (2015).

    CAS  Article  Google Scholar 

  14. 14.

    Zhang, W., Zhu, R., Nguyen, V. & Yang, R. Highly sensitive and flexible strain sensors based on vertical zinc oxide nanowire arrays. Sensors & Actuators A Physical 205, 164–169 (2014).

    CAS  Article  Google Scholar 

  15. 15.

    Webb, R. C. et al. Ultrathin conformal devices for precise and continuous thermal characterization of human skin. Nature Materials 12, 938–944 (2013).

    ADS  CAS  Article  Google Scholar 

  16. 16.

    Zhang, J. et al. Self-Monitoring and Self-Delivery of Photosensitizer-Doped Nanoparticles for Highly Effective Combination Cancer Therapy in Vitro and in Vivo. Acs Nano 9, 9741 (2015).

    CAS  Article  Google Scholar 

  17. 17.

    Yu, J. et al. Omnidirectionally Stretchable High-Performance Supercapacitor Based on Isotropic Buckled Carbon Nanotube Films. Acs Nano 10, 5204–5211 (2016).

    CAS  Article  Google Scholar 

  18. 18.

    Gao, L. et al. Optics and Nonlinear Buckling Mechanics in Large-Area, Highly Stretchable Arrays of Plasmonic Nanostructures. Acs Nano 9547, 5968–5975 (2015).

    Article  Google Scholar 

  19. 19.

    Cooper, C. B. et al. Stretchable Capacitive Sensors of Torsion, Strain, and Touch Using Double Helix Liquid Metal Fibers. Advanced Functional Materials 27, n/a–n/a (2017).

    Google Scholar 

  20. 20.

    Li, G., Wu, X. & Lee, D. W. A galinstan-based inkjet printing system for highly stretchable electronics with self-healing capability. Lab on A Chip 16, 1366–1373 (2016).

    CAS  Article  Google Scholar 

  21. 21.

    Lu, T., Finkenauer, L., Wissman, J. & Majidi, C. Rapid Prototyping for Soft‐Matter Electronics. Advanced Functional Materials 24, 3351–3356 (2014).

    CAS  Article  Google Scholar 

  22. 22.

    Yan, C. et al. Stretchable and wearable electrochromic devices. Acs Nano 8, 316 (2014).

    CAS  Article  Google Scholar 

  23. 23.

    Wang, Y. et al. Wearable and Highly Sensitive Graphene Strain Sensors for Human Motion Monitoring. Advanced Functional Materials 24, 4666–4670 (2014).

    CAS  Article  Google Scholar 

  24. 24.

    Mert, V., Behrens, A. M., Ayyub, O. B., Ayoub, J. J. & Peter, K. Sprayable Elastic Conductors Based on Block Copolymer Silver Nanoparticle Composites. Acs Nano 9, 336–344 (2015).

    Article  Google Scholar 

  25. 25.

    Larmagnac, A., Eggenberger, S., Janossy, H. & Vörös, J. Stretchable electronics based on Ag-PDMS composites. Scientific Reports 4, 7254 (2014).

    ADS  CAS  Article  Google Scholar 

  26. 26.

    Choi, D. Y. et al. Highly Stretchable, Hysteresis-Free Ionic Liquid-Based Strain Sensor for Precise Human Motion Monitoring. Acs Appl Mater Interfaces 9, 1770–1780 (2017).

    CAS  Article  Google Scholar 

  27. 27.

    Nam, I. et al. Omnidirectionally stretchable, high performance supercapacitors based on a graphene–carbon-nanotube layered structure. Nano Energy 15, 33–42 (2015).

    CAS  Article  Google Scholar 

  28. 28.

    Lee, M. S. et al. High-performance, transparent, and stretchable electrodes using graphene-metal nanowire hybrid structures. Nano Letters 13, 2814–2821 (2013).

    ADS  CAS  Article  Google Scholar 

  29. 29.

    Liang, J. et al. Silver Nanowire Percolation Network Soldered with Graphene Oxide at Room Temperature and Its Application for Fully Stretchable Polymer Light-Emitting Diodes. Acs Nano 8, 1590–1600 (2014).

    CAS  Article  Google Scholar 

  30. 30.

    Park, S. J. et al. Fabrication of graphite grids via stencil lithography for highly sensitive motion sensors. Carbon 96, 491–496 (2016).

    CAS  Article  Google Scholar 

  31. 31.

    Muth, J. T. et al. Embedded 3D printing of strain sensors within highly stretchable elastomers. Advanced Materials 26, 6307–6312 (2014).

    CAS  Article  Google Scholar 

  32. 32.

    Yan, S. et al. Liquid metal-based amalgamation-assisted lithography for fabrication of complex channels with diverse structures and configurations. Lab on A Chip 18 (2018).

  33. 33.

    Kazem, N., Bartlett, M. D. & Majidi, C. Extreme Toughening of Soft Materials with Liquid Metal. Advanced Materials 30, 1706594 (2018).

    Article  Google Scholar 

  34. 34.

    Park, Y. L., Majidi, C., Kramer, R., Bérard, P. & Wood, R. J. Hyperelastic pressure sensing with a liquid-embedded elastomer. Journal of Micromechanics & Microengineering 20, 125029–125034(125026) (2010).

    ADS  Article  Google Scholar 

  35. 35.

    Majidi, C., Kramer, R. & Wood, R. J. A non-differential elastomer curvature sensor for softer-than-skin electronics. Smart Materials & Structures 20, 105017 (2011).

    ADS  Article  Google Scholar 

  36. 36.

    Kazem, N., Hellebrekers, T. & Majidi, C. Soft Multifunctional Composites and Emulsions with Liquid Metals. Advanced Materials 29 (2017).

  37. 37.

    Tang, S. Y. et al. On-Chip Production of Size-Controllable Liquid Metal Microdroplets Using Acoustic Waves. Small 12, 3861–3869 (2016).

    CAS  Article  Google Scholar 

  38. 38.

    Tang, S. Y. et al. Microfluidic Mass Production of Stabilized and Stealthy Liquid Metal Nanoparticles. Small 14 (2018).

  39. 39.

    Tabatabai, A., Fassler, A., Usiak, C. & Majidi, C. Liquid-phase gallium-indium alloy electronics with microcontact printing. Langmuir 29, 6194–6200 (2013).

    CAS  Article  Google Scholar 

  40. 40.

    Ozutemiz, K. B., Wissman, J., Ozdoganlar, O. B. & Majidi, C. EGaIn–Metal Interfacing for Liquid Metal Circuitry and Microelectronics Integration. Advanced Materials Interfaces, 1701596 (2018).

  41. 41.

    Tavakoli, M. et al. EGaIn-Assisted Room-Temperature Sintering of Silver Nanoparticles for Stretchable, Inkjet-Printed, Thin-Film Electronics. Advanced Materials, 1801852 (2018).

  42. 42.

    Park, Y. L., Chen, B. R. & Wood, R. J. Design and Fabrication of Soft Artificial Skin Using Embedded Microchannels and Liquid Conductors. IEEE Sensors Journal 12, 2711–2718 (2012).

    ADS  CAS  Article  Google Scholar 

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This research was partially supported by National Natural Science Foundation of China (61803364, U1713219), Shenzhen Fundamental Research Project (JCYJ20180302145549896), Key Deployment Project of Chinese Academy of Sciences (Grant NO. KFZD-SW-214) and SIAT Innovation Program for Excellent Young Researchers. (Grant NO. 2016053).

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H.L., L.W. and Q.W.G. designed the research. H.L. and Q.W.G. co-wrote the paper. Q.W.G. fabricated the sensor. Q.W.G. and J.Y.Z. carried out the measurements. J.J.Z. and Z.W.X. did the mechanical analysis. All authors commented on the final paper.

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Correspondence to Hui Li or Lei Wang.

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Gao, Q., Li, H., Zhang, J. et al. Microchannel Structural Design For a Room-Temperature Liquid Metal Based Super-stretchable Sensor. Sci Rep 9, 5908 (2019). https://doi.org/10.1038/s41598-019-42457-7

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