Broadband mechanoresponsive liquid metal sensors

Rahman, Md. Saifur; Huddy, Julia E.; Hamlin, Andrew B.; Scheideler, William J.

doi:10.1038/s41528-022-00206-3

Cited by 14 publications

(16 citation statements)

References 34 publications

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“…As the signal frequency increases, these phenomena concentrate current density near the conductors' outer surface, increasing ohmic losses. [11,[32][33][34] The skin effect occurs due to the formation of circulating eddy currents, which null current density at the center and produce a current density that decreases exponentially as a function of depth with a characteristic length scale, δ, the skin depth. This skin depth (δ) is characteristic of a conductor with a given resistivity ( ) and permeability ( ), de ned mathematically as:…”

Section: Resultsmentioning

confidence: 99%

“…However, this magnetic energy storage is counterbalanced by losses originating in the series resistance of the windings while subjected to direct current (DC) and alternating current (AC). For instance, when subjected to high-frequency excitation using alternating current (AC), inductors incur extra resistive losses in addition to their inherent DC resistance (R dc ) [11][12][13] . Figure 1b shows an electrical model of an inductor that accounts for interwinding capacitance and the frequency-dependent AC resistance (R ac ).…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

3D Woven Liquid Metals for High-Frequency Stretchable Circuits

Rahman,

Tiwari,

Agnew

et al. 2024

Preprint

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Mechanically flexible and stretchable inductive coils are a critical component for enabling communication, sensing, and wireless power transfer capabilities in future wearable electronic devices that conform to the body for healthcare and the Internet of Things (IoT) applications. However, the mechanical conformability of leading stretchable materials such as liquid metals (LMs) sacrifices electromagnetic performance since conductivity lags behind conventional rigid Cu wires, leading to lossy radio-frequency (RF) characteristics. Here, we present a strategy leveraging multistranded three-dimensional (3D) woven 'litz' transmission lines to amplify the resonant RF performance of LM inductors. Through comprehensive simulations and experiments, we discovered that interwoven LM litz wires boost the Quality Factor (Q) by 80 % compared to standard liquid metal wires. We also demonstrate a fabrication methodology for stretchable coils that retain high Q (>30), outperforming the previously reported LM coils and maintaining 98 % of their wireless transmission efficiency under up to 30 % biaxial strain. Moreover, we showcase the versatility of this approach by 3D printing four-terminal 'choke' inductors optimized for RF filtering and inductance tunability, overcoming the fabrication limitations of traditional planar printed electronics. These results offer valuable insights into the design and implementation of 3D-printed magnetics for a diverse suite of electromagnetic device applications.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

3D Woven Liquid Metals for High-Frequency Stretchable Circuits

Rahman,

Tiwari,

Agnew

et al. 2024

Preprint

Self Cite

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“…As another example, we have also demonstrated a twin-wire network of 29 photoresistors. The proposed strategies can provide crucial advantages for high-density 4-wire interfacing of arrays of resistive or impedance sensors, independently on materials (conventional or nano-cracked metals, [2,[30][31][32] liquid metals, [33] etc. ), signal to be measured (temperature, strain, blood flow, light, etc.…”

Section: Discussionmentioning

confidence: 99%

Twin‐Wire Sensor Networks

Rossi

Montoya

Falconi

2023

Advanced Sensor Research

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A fundamental limit to high‐density sensing is that adding sensors increases the number of wires, pads, and interconnections. This problem is even worse for low‐values resistive or impedance sensors which, for high accuracy, require 4‐wire measurements. Here, twin‐wire sensor networks are described which enable 4‐wire measurements with significantly fewer wires, pads, and interconnections. The effects of the resistor noise can be minimized by minimum‐resistance sensing paths. A single chopper switch and straightforward digital operations can reject the equivalent input offset and low‐frequency noise voltages of the instrumentation amplifier, thus requiring no hardware changes. The inclusion in the network of a reference resistor can compensate the errors of both the biasing current and the instrumentation amplifier voltage gain. For validation, an extremely compact, robust, and easy‐to‐connect flexible‐PCB twin‐wire 29‐temperature‐sensors network requiring only 32 pads is demonstrated. This device is placed on an anthropomorphic head phantom for detecting the temperature and location of a touching object or on the hand of a volunteer for monitoring skin temperature during mental and physical stimulations. A twin‐wire 29‐photoresistors network is also presented. The strategies reported here can be applied to any high‐density array of resistive or impedance sensors (temperature, strain, blood flow, light, etc.) and may find wide application in robotics and wearable or epidermal devices.

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“…[355][356][357][358] These properties have expanded their applications in fields like flexible sensors, wearable electronic devices, biomedicine, exoskeleton systems, and soft robotics. [359][360][361][362] LMs have demonstrated remarkable deformability and mobility in both aqueous and non-aqueous environments, 363 making them promising for soft actuators. Several LM-based soft actuation methods, including electrochemical actuation, are being developed for pumps, soft robots, and motors.…”

Section: Other Metal-based Materialsmentioning

confidence: 99%