High Performance Flexible Temperature Sensors via Nanoparticle Printing

Rahman, Taibur; Cheng, Chiu-Ping; Karagoz, Burcu; Renn, Mike; Schrandt, Matthew; Gellman, Andrew J.; Panat, Rahul

doi:10.1021/acsanm.9b00628

Cited by 49 publications

(46 citation statements)

References 58 publications

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“…The requirement of a difference in temperature over the material poses challenges in terms of monitoring absolute temperatures of single spots, in particular for small dimensions and thicknesses where the whole material is heated. So far, the most commonly used self-powered temperature sensor is the thermocouple (TC), which provides thermovoltages based on the difference in Seebeck coefficients of two electronic conductors forming a junction 28 . However, the sensitivity of TCs is limited to tens of microvolts per kelvin due to low electronic Seebeck coefficients 29 .…”

Section: Introductionmentioning

confidence: 99%

Ultrasensitive electrolyte-assisted temperature sensor

et al. 2020

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Heat sensors form an important class of devices that are used across multiple fields and sectors. For applications such as electronic skin and health monitoring, it is particularly advantageous if the output electronic signals are not only high, stable, and reproducible, but also self-generated to minimize power consumption. Here, we present an ultrasensitive heat sensing concept that fulfills these criteria while also being compatible with scalable low-cost manufacturing on flexible substrates. The concept resembles a traditional thermocouple, but with separated electrodes bridged by a gel-like electrolyte and with orders of magnitudes higher signals (around 11 mV K−1). The sensor pixels provide stable and reproducible signals upon heating, which, for example, could be used for heat mapping. Further modification to plasmonic nanohole metasurface electrodes made the sensors capable of also detecting light-induced heating. Finally, we present devices on flexible substrates and show that they can be used to detect human touch.

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Section: Introductionmentioning

confidence: 99%

Ultrasensitive electrolyte-assisted temperature sensor

et al. 2020

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“…The electromechanical properties and flexibility of touch sensors will be different due to the materials and manufacturing processes. Therein, the coating [64,65], printing [66,67], spinning [68,69], and transferring [70,71] are some method-keys of the current studies. Flexible sensor electrodes are also formed via transferring conductive materials onto elastomeric (textile or silicone).…”

Section: Manufacturing Technologiesmentioning

confidence: 99%

Flexible wearable sensors - an update in view of touch-sensing

Kim

2021

Science and Technology of Advanced Materials

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Nowadays, much of user interface is based on touch and the touch sensors have been common for displays, Internet of things (IoT) projects, or robotics. They can be found in lamps, touch screens of smartphones, or other wide arrays of applications as well. However, the conventional touch sensors, fabricated from rigid materials, are bulky, inflexible, hard, and hard-to-wear devices. The current IoT trend has made these touch sensors increasingly important when it added in the skin or clothing to affect different aspects of human life flexibly and comfortably. The paper provides an overview of the recent developments in this field. We discuss exciting advances in materials, fabrications, enhancements, and applications of flexible wearable sensors under view of touch-sensing. Therein, the review describes the theoretical principles of touch sensors, including resistive, capacitive, and piezoelectric types. Following that, the conventional and novel materials, as well as manufacturing technologies of flexible sensors are considered to. Especially, this review highlights the multidisciplinary approaches such as e -skins, e -textiles, e -healthcare, and e -control of flexible touch sensors. Finally, we summarize the challenges and opportunities that use is key to widespread development and adoption for future research.

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“…For printed electronics, numerous metallic NPs have been developed, including Cu [32][33][34], Au [31,35,36], Pd [37,38], Ni [26], and Ag [39,40]. Among them, Ag is one of the widely used metals due to the excellent electrical conductivity and low affinity for oxygen.…”

Section: Metal Nanoparticles (Nps)mentioning

confidence: 99%

Advanced Nanomaterials, Printing Processes, and Applications for Flexible Hybrid Electronics

Park

Kim

et al. 2020

Materials

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Recent advances in nanomaterial preparation and printing technologies provide unique opportunities to develop flexible hybrid electronics (FHE) for various healthcare applications. Unlike the costly, multi-step, and error-prone cleanroom-based nano-microfabrication, the printing of nanomaterials offers advantages, including cost-effectiveness, high-throughput, reliability, and scalability. Here, this review summarizes the most up-to-date nanomaterials, methods of nanomaterial printing, and system integrations to fabricate advanced FHE in wearable and implantable applications. Detailed strategies to enhance the resolution, uniformity, flexibility, and durability of nanomaterial printing are summarized. We discuss the sensitivity, functionality, and performance of recently reported printed electronics with application areas in wearable sensors, prosthetics, and health monitoring implantable systems. Collectively, the main contribution of this paper is in the summary of the essential requirements of material properties, mechanisms for printed sensors, and electronics.

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High Performance Flexible Temperature Sensors via Nanoparticle Printing

Cited by 49 publications

References 58 publications

Ultrasensitive electrolyte-assisted temperature sensor

Ultrasensitive electrolyte-assisted temperature sensor

Flexible wearable sensors - an update in view of touch-sensing

Advanced Nanomaterials, Printing Processes, and Applications for Flexible Hybrid Electronics

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