Covalently Functionalized MXenes for Highly Sensitive Humidity Sensors

Janica, Iwona; Urban, Francesca; Hashemi, Payam; Nia, Ali Shaygan; Feng, Xinliang; Samorı́, Paolo; Ciesielski, Artur

doi:10.1002/smtd.202201651

Cited by 10 publications

(6 citation statements)

References 71 publications

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“…When the MXene SC absorbs sweat, the penetration of water molecules between the MXene nanosheets reduces the conductive pathway of MXene and weakens its conductivity. [ 22 ] Importantly, the paper layer undergoes volume expansion, which leads to relative sliding of the MXene nanosheets deposited on the paper to form cracks under stress. The islands and gaps induced by stress further reduce the conductive pathways of MXene, [ 33 ] thus further weakening its electrical conductivity, as shown in Figure S2a (Supporting Information).…”

Section: Resultsmentioning

confidence: 99%

“…However, when MXene comes into contact with water, water molecules can penetrate between the MXene nanosheets, which causes an expansion in the distance between them, leading to electron decoupling between the MXene sheets and thus reducing their electrical conductivity. [21,22] In addition, the charge depletion in the presence of adsorbed water molecules also contributes to the decrease in conductivity. [22] Moreover, this effect is aggravated when MXene is deposited on hydrophilic paper substrates, as volume expansion of paper upon water absorption can cause MXene sheets deposited on the paper surface to slide.…”

Section: Introductionmentioning

confidence: 99%

“…[21,22] In addition, the charge depletion in the presence of adsorbed water molecules also contributes to the decrease in conductivity. [22] Moreover, this effect is aggravated when MXene is deposited on hydrophilic paper substrates, as volume expansion of paper upon water absorption can cause MXene sheets deposited on the paper surface to slide. [23] These characteristics are unfavorable for the application of MXene in energy-storage e-skins that utilize sweat as the electrolyte.…”

Section: Introductionmentioning

confidence: 99%

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“Sweat‐Driven” MXene Composites with Energy‐Storage and Thermal‐Management Multifunctions: A Platform for Versatile Electronic Skins

Wang,

Luo,

Zheng

et al. 2023

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Most exogenous electronic skins (e‐skins) currently face challenges of complex structure and poor compatibility with the human body. Utilizing human secretions (e.g., sweat) to develop e‐skins is an effective solution strategy. Here, a new kind of “sweat‐driven” e‐skin is proposed, which realizes energy‐storage and thermal‐management multifunctions. Through the layer‐by‐layer assembly of MXene‐carbon nanotube (CNT) composite with paper, lightweight and versatile e‐skins based on supercapacitors and actuators are fabricated. Long CNTs wrap and entangle MXene nanosheets, enhancing their long‐distance conductivity. Furthermore, the CNT network overcomes the structural collapse of MXene in sweat, improving the energy‐storage performance of e‐skin. The “sweat‐driven” all‐in‐one supercapacitor with a trilayer structure is patternable, which absorbs sweat as electrolyte and harnesses the ions therein to store energy, exhibiting an areal capacitance of 282.3 mF cm−2 and a high power density (2117.8 µW cm−2). The “sweat‐driven” actuator with a bilayer structure can be driven by moisture (bending curvature of 0.9 cm−1) and sweat for personal thermal management. Therefore, the paper serves as a separator, actuating layer, patternable layer, sweat extractor, and reservoir. The “sweat‐driven” MXene‐CNT composite provides a platform for versatile e‐skins, which achieve the interaction with humans and offer insights into the development of multifunctional wearable electronics.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

“Sweat‐Driven” MXene Composites with Energy‐Storage and Thermal‐Management Multifunctions: A Platform for Versatile Electronic Skins

Wang,

Luo,

Zheng

et al. 2023

Small

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“…In comparison to other materials, porous crystalline materials possess unparalleled porosity and exceptional customizability, which equip them with a diverse range of outstanding properties (such as mechanical strength, ionic/electronic conductivity, optoelectronics, adsorption capacity, and stability) through guest loading, structural/compositional design, and post-synthetic modification. [4][5][6]60,62,[91][92][93][94][95] The interest of researchers worldwide in developing next-generation memory/ neuromorphic devices has been significantly piqued by these remarkable properties exhibited by porous crystalline materials.…”

Section: Kui Zhoumentioning

confidence: 99%

Porous crystalline materials for memories and neuromorphic computing systems

Ding,

Zhao,

Zhou

et al. 2023

Chem. Soc. Rev.

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“…transition metal-based carbides, nitrides and carbonitrides 2D layered ceramics also known as MXene´s has drawn significant attention from the materials research community [8] . Thanks to their impressive physicochemical and charge transport properties this fascinating class of materials has found application in many different fields from energy conversion [9,10] /storage [11] to efficient electromagnetic shielding, photodetectors [12][13][14][15][16][17] , sensors [18,19] and biomedical devices [20] . To this date tens of different MXene compositions has been successfully synthesized and studied whereas possibility of synthesis of more than hundred different compositions has been predicted by the computational studies.…”

Section: Introductionmentioning

confidence: 99%

Non-covalent Functionalized Schottky Interface at Ti3C2Tx/n-Si Van der Waals Heterojunction

Ros Costals,

Francesc Cappela,

Tom

et al. 2023

Preprint

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Low dimensional 2D materials such as graphene and carbon nano tubes have attracted significant attention from the solid-state device community and are considered as a potential candidate electrode to make functional contact with the Silicon (Si) and other industry compatible semiconductors. In this work we envisioned to utilize one such interesting 2D material Ti3C2Tx belonging to a rapidly emerging family of transition metal carbides/nitrides also known as MXene´s to fabricate the classical yet interesting Schottky junctions by simple drop casting of aqueous conducting colloidal solution of Ti3C2Tx on c-Si. Precisely, we anticipate to tune the work function of the Ti3C2Tx as well as the built-in potential of these Ti3C2Tx/c-Si Van der Waals heterojunction through inserting ultrathin interlayer of cationic polyelectrolytes/organic dipoles with a defined dipole moment value. In order to accomplish the interface engineering inclusion poly(ethylene)amine (PEI 0.1%), third generation poly(amido-)amine (PAMAM G3)), were tested between the Ti3C2TX and c-Si substrates. Charge transport properties of the fabricated Schottky devices with the structure of Ti3C2TX/organic dipole (O.D.) /c-Si were evaluated through systematic analysis of the current-voltage (I-V) and capacitance-voltage (C-V) results. I-V measurements under dark conditions revealed that Schottky diodes fabricated with the (PEI 0.1%) and PAMAM G3 interlayers exhibited lowest reverse saturation current density (J0) value and improved built in potential (Vbi) value as compared to the devices with only 2D-Ti3C2Tx as contact. We report reduction in the work function value of Ti3C2Tx from 5.8 eV to 4.2 eV for Ti3C2Tx/PEI (0.1%) and 3.3 eV for Ti3C2Tx/PAMAM G3 heterostructures. On the basis of the inferences drawn from the surface analysis we ascribe this reduction in work function value to the formation of interfacial dipoles at the Ti3C2Tx/O.D. interface. Importantly this study highlights an innovative method to tune the work function of the Ti3C2Tx MXene inclusion of organic dipoles as interlayers.

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Covalently Functionalized MXenes for Highly Sensitive Humidity Sensors

Cited by 10 publications

References 71 publications

“Sweat‐Driven” MXene Composites with Energy‐Storage and Thermal‐Management Multifunctions: A Platform for Versatile Electronic Skins

“Sweat‐Driven” MXene Composites with Energy‐Storage and Thermal‐Management Multifunctions: A Platform for Versatile Electronic Skins

Porous crystalline materials for memories and neuromorphic computing systems

Non-covalent Functionalized Schottky Interface at Ti3C2Tx/n-Si Van der Waals Heterojunction

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