Polydopamine Shell as a Ga<sup>3+</sup> Reservoir for Triggering Gallium–Indium Phase Separation in Eutectic Gallium–Indium Nanoalloys

Xie, Wanjie; Allioux, François-Marie; Namivandi-Zangeneh, Rashin; Ghasemian, Mohammad B.; Han, Jialuo; Rahim, Md. Arifur; Tang, Jianbo; Yang, Jiong; Mousavi, Maedehsadat; Mayyas, Mohannad; Cao, Zhengjun; Centurion, Franco; Christoe, Michael J.; Zhang, Chengchen; Wang, Yifang; Merhebi, Salma; Baharfar, Mahroo; Ng, Gervase; Esrafilzadeh, Dorna; Boyer, Cyrille; Kalantar‐zadeh, Kourosh

doi:10.1021/acsnano.1c07278

Cited by 30 publications

(43 citation statements)

References 75 publications

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“…In another study on the effect of functional coating on the performance of LM-based gas sensors, the surfaces of EGaIn NPs were coated with polydopamine (PDA) shells at various thicknesses. 160 According to the obtained results, surface coating of NPs accompanied by Ga 3+ diffusion and coordination into PDA shells resulted in an enhancement in interfacial polarity and induced Ga−In phase separation. While the increase in the interfacial polarity favored NO 2 sensing performance, Ga−In phase separation showed a counteracting effect by increasing the electrical resistivity (due to lower conductivity of In compared to EGaIn).…”

mentioning

confidence: 72%

“…Semiconductor metal oxides (SMOs) are the most popular materials for gas sensing applications where changes in electrical properties of SMO are tracked upon physical or chemical interactions with target gaseous compounds. , When it comes to Ga-based LMs, the native oxide layer, rapidly formed on the surface, is known to feature semiconducting properties suited for gas sensing applications. , The most interesting feature of LM-based gas sensing interfaces is tailorable sensing properties achieved via manipulation of morphology and size of sensing elements as well as versatile deposition of functional coatings on LMs droplets. , …”

Section: Lm-based Gas Sensorsmentioning

confidence: 99%

“…(B) PDA-coated EGaIn particles utilized for NO 2 sensing: (i) disposition of different PDA thicknesses and (ii) their impact on gas sensing performance. Reproduced from ref . Copyright 2021 American Chemical Society.…”

Section: Lm-based Gas Sensorsmentioning

confidence: 99%

“…157,158 The most interesting feature of LM-based gas sensing interfaces is tailorable sensing properties achieved via manipulation of morphology and size of sensing elements 159 as well as versatile deposition of functional coatings on LMs droplets. 160,161 Conventional LM-Based Gas Sensors. Traditionally, thin films of gallium oxides have been exploited as gas sensing elements for both reducing and oxidizing gaseous species.…”

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confidence: 99%

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Emerging Role of Liquid Metals in Sensing

Baharfar

Kalantar‐zadeh

2022

ACS Sens.

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Low melting point metals and alloys are the group of materials that combine metallic and liquid properties, simultaneously. The fascinating characteristics of liquid metals (LMs) including softness and high electrical and thermal conductivity, as well as their unique interfacial chemistry, have started to dominate various research disciplines. Utilization of LMs as responsive interfaces, enabling sensing in a flexible and versatile manner, is one of the most promising traits demonstrated for LMs. In the context of LMs-enabled sensors, gallium (Ga) and its alloys have emerged as multipurpose functional materials with many compelling physical and chemical properties. Responsiveness to different stimuli and easy-to-functionalize interfaces of Ga-based LMs make them ideal candidates for a variety of sensing applications. However, despite the vast capabilities of Ga-based LMs in sensing, applications of these materials for developing different sensors have not been fully explored. In the present review, we provide a comprehensive overview regarding the applications of Ga-based LMs in a wide range of sensing approaches that cover different physical and chemical sensors. The unique features of Ga-based LMs, which make them promising materials for sensing, are discussed in subsections followed by relevant case studies. Finally, challenges as well as the prospected future and developing motifs are highlighted for each type of LM-based sensors.

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confidence: 72%

Section: Lm-based Gas Sensorsmentioning

confidence: 99%

Section: Lm-based Gas Sensorsmentioning

confidence: 99%

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confidence: 99%

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Emerging Role of Liquid Metals in Sensing

Baharfar

Kalantar‐zadeh

2022

ACS Sens.

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“…25,27 However, the LM surfaces possess limited interactions with external substrates. [31][32][33][34] This hinders the practical utilization of Ga NPs as an antibacterial depot since it requires the processing of the Ga NPs as stable surface coatings. Such a surface coating process of Ga NPs has remained a critical bottleneck for their extensive use in antibacterial applications.…”

Section: Introductionmentioning

confidence: 99%

Assembly of surface-independent polyphenol/liquid gallium composite nanocoatings

et al. 2022

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Liquid Metal‐Based Biosensors: Fundamentals and Applications

Jamalzadegan,

Kim,

Mohammad

et al. 2024

Adv Funct Materials

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Biosensors are analytical tools for monitoring various parameters related to living organisms, such as humans and plants. Liquid metals (LMs) have emerged as a promising new material for biosensing applications in recent years. LMs have attractive physical and chemical properties such as deformability, high thermal and electrical conductivity, low volatility, and low viscosity. LM‐based biosensors represent a new strategy in biosensing particularly for wearable and real‐time sensing. While early demonstrations of LM biosensors focus on monitoring physical parameters such as strain, motion, and temperature, recent examples show LM can be an excellent sensing material for biochemical and biomolecular detection as well. In this review, the recent progress of LM‐based biosensors for personalized healthcare and disease monitoring via both physical and biochemical signaling is survey. It is started with a brief introduction of the fundamentals of biosensors and LMs, followed by a discussion of different mechanisms by which LM can transduce biological or physiological signals. Next, it is reviewed example LM‐based biosensors that have been used in real biological systems, ranging from real‐time on‐skin physiological monitoring to target‐specific biochemical detection. Finally, the challenges and future directions of LM‐integrated biosensor platforms is discussed.

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Polydopamine Shell as a Ga³⁺ Reservoir for Triggering Gallium–Indium Phase Separation in Eutectic Gallium–Indium Nanoalloys

Cited by 30 publications

References 75 publications

Emerging Role of Liquid Metals in Sensing

Emerging Role of Liquid Metals in Sensing

Assembly of surface-independent polyphenol/liquid gallium composite nanocoatings

Liquid Metal‐Based Biosensors: Fundamentals and Applications

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Polydopamine Shell as a Ga3+ Reservoir for Triggering Gallium–Indium Phase Separation in Eutectic Gallium–Indium Nanoalloys

Cited by 30 publications

References 75 publications

Emerging Role of Liquid Metals in Sensing

Emerging Role of Liquid Metals in Sensing

Assembly of surface-independent polyphenol/liquid gallium composite nanocoatings

Liquid Metal‐Based Biosensors: Fundamentals and Applications

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Product

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Polydopamine Shell as a Ga³⁺ Reservoir for Triggering Gallium–Indium Phase Separation in Eutectic Gallium–Indium Nanoalloys