SnS/Ti3C2Tx (MXene) Nanohybrid-Based Wearable Electromechanical Sensors for Sign-to-Text Translation and Sitting Posture Analysis

Adepu, Vivek; Kunchur, Aditya; Tathacharya, Manav; Mattela, Venkat; Sahatiya, Parikshit

doi:10.1021/acsaelm.2c00026

Cited by 14 publications

(25 citation statements)

References 42 publications

(48 reference statements)

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“…Essentially, the analytical performance of such kind of device usually depends on the electrical conductivity (or the extent of charge transport) within the materials, which is primarily governed by the intrinsic characteristics (e.g., intermolecular arrangement, molecular structure) and some extrinsic physical parameters like temperature, pressure, strain, etc. [12][13][14] Moreover, such organic molecule-based electronic device materials are biocompatible as well as environmentally sustainable compared to their inorganic analogs. The precise control over the charge transfer process allows the PDI-based fabricated thin films as an excellent flexible sensor for pressure and breath gas.…”

Section: This Work Demonstrates the Perylene Diimide (Pdi) Based Mult...mentioning

confidence: 99%

Perylene Diimide (PDI) based Flexible Multifunctional Sensor Design for Personal Healthcare Monitoring‐ A Complementary Approach Involving Experimental and Theoretical Investigations

Adepu

Tathacharya

Fernandes

et al. 2023

Adv Materials Technologies

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This work demonstrates the Perylene Diimide (PDI) based multifunctional sensor for breath‐sensing and Geriatric Emergency Signalling applications fabricated by an economically viable vacuum filtration deposition technique. The deposition of PDI molecules on the flexible substrate forms a moderately conducting percolating molecular network, exhibiting superior pressure and breath‐sensing performance. The pressure sensor displays a sensitivity of 2.42198 kPa−1 with response and recovery times of ≈191 and ≈166 msec. Also, the sensor displays response and recovery times of ≈211 msec and ≈2.651 sec for breath sensing. The durability of the sensor is evaluated using a pressure‐tapping machine, and the sensor displayed a negligible performance drop over ≈10 000 cycles. The experimental findings are complemented by an ab‐initio calculation‐based comprehensive theoretical analysis of the underlying transduction mechanism for pressure and breath sensing in the context of the percolating molecular network. The theoretical analysis reveals that applied pressure and molecular adsorption significantly influence the molecular conductivity as well as the inter‐molecular quantum mechanical tunneling component, which primarily contributes to the observed increase in conductivity with pressure and exposure to breath. An Android/iOS application is developed to wirelessly receive data via Bluetooth from the sensors connected to a microcontroller.

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Section: This Work Demonstrates the Perylene Diimide (Pdi) Based Mult...mentioning

confidence: 99%

Perylene Diimide (PDI) based Flexible Multifunctional Sensor Design for Personal Healthcare Monitoring‐ A Complementary Approach Involving Experimental and Theoretical Investigations

Adepu

Tathacharya

Fernandes

et al. 2023

Adv Materials Technologies

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“…P-Type 2D Semiconductors-Based Wearable Strain Sensor: Heart rate monitoring, [4] posture analysis, [5] and other applications of wearable strain sensors are intimately connected with human health. The performance of strain sensors is assessed by Gauge factor (GF), which is defined by the response (resistance or capacitance) per applied strain.…”

Section: P-type 2d Semiconductors-based Wearable Temperature Sensormentioning

confidence: 99%

“…[3] By continually monitoring longitudinal trends in vital signs, wearable devices offer the capability to yield a more thorough understanding of endogenous metabolic and stress processes related to an individual's health condition. [1] Wearable devices allow the possibility to extract physiological and psychological information by capturing a plethora of physical and chemical signals, such as heart rate, [4] posture, [5] respiration rate, [6] the composition of exhaled gas, [7,8] or perspiration. [9] 2D materials exhibit exceptional physical and chemical properties, making them promising materials for human wearables.…”

Section: Introductionmentioning

confidence: 99%

Wearable Sensors Based on Atomically Thin P‐Type Semiconductors

Jiang

Zhang

2023

Adv Materials Technologies

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Abstract2D materials have exceptional physical and chemical characteristics, which makes them attractive for wearable technology. These characteristics include high carrier mobility, outstanding mechanical performance, abundant chemistry, and excellent electrostatic tunability. However, due to the high electron doping effect of interfacial charge impurities and intrinsic defects, most reported 2D materials are n‐type. Complementary electronic devices and high‐performance wearable sensors necessitate the development of p‐type 2D semiconductors, which have superior electrocatalytic performance in oxidative processes compared to their n‐type counterparts. This review paper thoroughly accounts for recent advancements in 2D p‐type semiconductor‐based wearable sensors, covering basic understandings, synthesis and fabrication, functional devices, and sensor performance insights. Finally, challenges and future opportunities for 2D p‐type semiconductor‐based wearable sensors are discussed.

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“…So far, e-textiles Nanomaterials 2022, 12, 2039 2 of 47 have been proposed to be utilized in different areas, i.e., healthcare [7,8], sensing [9,10], defense [11,12], sports [13,14], personal protection [15,16], fashion [17,18], energy [19,20], thermal management [21,22], magnetic shielding [23,24], communication [25,26], etc. The incorporation of metal nanoparticles (silver [27,28], gold [29,30], copper [31,32], zinc oxide [33,34], gallium [35,36], platinum [37,38], aluminum [39,40], nickel [41,42], cobalt [43,44], tin [45,46], etc. ), carbon nanomaterials (carbon nanotube [47,48], graphene [49,50], carbon black [51,52], activated carbon [53,…”

Section: Introductionmentioning

confidence: 99%

Advances in the Robustness of Wearable Electronic Textiles: Strategies, Stability, Washability and Perspective

Sadi

Kumpikaitė

2022

Nanomaterials

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Flexible electronic textiles are the future of wearable technology with a diverse application potential inspired by the Internet of Things (IoT) to improve all aspects of wearer life by replacing traditional bulky, rigid, and uncomfortable wearable electronics. The inherently prominent characteristics exhibited by textile substrates make them ideal candidates for designing user-friendly wearable electronic textiles for high-end variant applications. Textile substrates (fiber, yarn, fabric, and garment) combined with nanostructured electroactive materials provide a universal pathway for the researcher to construct advanced wearable electronics compatible with the human body and other circumstances. However, e-textiles are found to be vulnerable to physical deformation induced during repeated wash and wear. Thus, e-textiles need to be robust enough to withstand such challenges involved in designing a reliable product and require more attention for substantial advancement in stability and washability. As a step toward reliable devices, we present this comprehensive review of the state-of-the-art advances in substrate geometries, modification, fabrication, and standardized washing strategies to predict a roadmap toward sustainability. Furthermore, current challenges, opportunities, and future aspects of durable e-textiles development are envisioned to provide a conclusive pathway for researchers to conduct advanced studies.

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SnS/Ti₃C₂T_x (MXene) Nanohybrid-Based Wearable Electromechanical Sensors for Sign-to-Text Translation and Sitting Posture Analysis

Cited by 14 publications

References 42 publications

Perylene Diimide (PDI) based Flexible Multifunctional Sensor Design for Personal Healthcare Monitoring‐ A Complementary Approach Involving Experimental and Theoretical Investigations

Perylene Diimide (PDI) based Flexible Multifunctional Sensor Design for Personal Healthcare Monitoring‐ A Complementary Approach Involving Experimental and Theoretical Investigations

Wearable Sensors Based on Atomically Thin P‐Type Semiconductors

Advances in the Robustness of Wearable Electronic Textiles: Strategies, Stability, Washability and Perspective

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