Two-Dimensional Materials for Sensing: Graphene and Beyond

Varghese, Seba Sara; Varghese, Saino Hanna; Swaminathan, S.; Singh, Krishna Kumar; Mittal, Vikas

doi:10.3390/electronics4030651

“…This Special Issue comprises a total of 12 papers (four review papers and eight contributed articles) and spans a wide range of topics, which extend from first principle band structure calculations [14] and molecular dynamics simulations of the thermal properties [15] of 2D materials, over numerical simulations and compact modeling of 2D transistors [16][17][18] and other 2D devices [19,20], 2D material growth [21,22] and processing issues [22][23][24], up to experimental 2D devices and their applications [22,23,25]. Regarding the materials, the papers of the Special Issue deal with graphene and graphene nanoribbons [16][17][18][19][20]22,23,25], TMDs (transition metal dichalcogenide) [14,21,22,24,25], phosphorene, which frequently is called 2D black phosphorus [24,25], and 2D metal oxides [25].…”

Section: The Present Special Issuementioning

confidence: 99%

Two-Dimensional Electronics - Prospects and Challenges

2016

0

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“…Yogeesh and coauthors review their recent progress on flexible graphene devices and demonstrate a flexible graphene-based radio frequency receiver operating at 2.4 GHz [23]. Bablich, Kataria, and Lemme present a thorough overview on the application of 2D materials in optoelectronics [22], and, in the last review paper, Varghese and coauthors comprehensively discuss the use of 2D materials for gas sensors [25].…”

Section: The Present Special Issuementioning

confidence: 99%

“…This Special Issue comprises a total of 12 papers (four review papers and eight contributed articles) and spans a wide range of topics, which extend from first principle band structure calculations [14] and molecular dynamics simulations of the thermal properties [15] of 2D materials, over numerical simulations and compact modeling of 2D transistors [16][17][18] and other 2D devices [19,20], 2D material growth [21,22] and processing issues [22][23][24], up to experimental 2D devices and their applications [22,23,25]. Regarding the materials, the papers of the Special Issue deal with graphene and graphene nanoribbons [16][17][18][19][20]22,23,25], TMDs (transition metal dichalcogenide) [14,21,22,24,25], phosphorene, which frequently is called 2D black phosphorus [24,25], and 2D metal oxides [25].…”

Section: The Present Special Issuementioning

confidence: 99%

“…Regarding the materials, the papers of the Special Issue deal with graphene and graphene nanoribbons [16][17][18][19][20]22,23,25], TMDs (transition metal dichalcogenide) [14,21,22,24,25], phosphorene, which frequently is called 2D black phosphorus [24,25], and 2D metal oxides [25]. Finally, the papers discuss More Moore electronics and transistors [16][17][18], as well as applications belonging to the More Than Moore domain of semiconductor electronics, including optoelectronics [22], RF electronics [16,23], sensors [20,25], and field emitters [19].…”

Section: The Present Special Issuementioning

confidence: 99%

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Two-Dimensional Electronics — Prospects and Challenges

Schwierz

¹

2016

Electronics

2

0

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“…For example, the exposure of NH 3 , which act like an electron donor, increases the resistance value whereas electron-withdrawing NO 2 cause a decrease in resistance. 105 An implantable silk-fibroin encapsulated graphene-FET enzymatic biosensor that utilizes silkprotein both as enzyme immobilization material, and a device substrate-was developed for real-time glucose monitoring up to 3-10 mM. 106 Myung et al have reported rGO encapsulated with silicon-oxide NPs based FET biosensor that significantly increases the surfaceto-volume ratio and maintain high electrical conductivity for selective and sensitive real time detection of key biomarker proteins for breast cancer.…”

mentioning

confidence: 99%

Graphene based biosensors—Accelerating medical diagnostics to new-dimensions

Chauhan

¹

,

Maekawa

²

,

Kumar

³

2017

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Graphene has emerged as a champion material for a variety of applications cutting across multiple disciplines in science and engineering. Graphene and its derivatives have displayed huge potential as a biosensing material due to their unique physicochemical properties, good electrical conductivity, optical properties, biocompatibility, ease of functionalization, and flexibility. Their widespread use in making biosensors has opened up new possibilities for early diagnosis of life-threatening diseases and real-time health monitoring. Following an introduction and discussion on the significance of fabrication protocols and assembly, this review is intended to assess why graphene is suitable to build better biosensors, the working of existing biosensing schemes and their current status toward commercialization for wearable diagnostic and prognostic devices. We believe this review will provide a critical insight for harnessing graphene as a suitable biosensor for the clinical diagnostics, its future prospects and challenges ahead.

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Two-Dimensional Materials for Sensing: Graphene and Beyond

Cited by 367 publications

References 181 publications

Two-Dimensional Electronics - Prospects and Challenges

Two-Dimensional Electronics - Prospects and Challenges

Two-Dimensional Electronics — Prospects and Challenges

Graphene based biosensors—Accelerating medical diagnostics to new-dimensions

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