A review on application of graphene‐based microfluidics

Chen, Xueye; Zhang, Shuai; Han, Wu; Wu, Zhongli; Chen, Yao; Wang, Shouxin

doi:10.1002/jctb.5710

Cited by 13 publications

(13 citation statements)

References 108 publications

(111 reference statements)

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“…Graphene as a new type of two-dimensional carbon nanomaterial shows excellent physical and chemical properties that have drawn wide attention in recent years. [1][2][3][4] Among the various preparation methods, the improved Hummers' oxidation-reduction method is one of the most promising methods for the industrialization of the preparation of graphene, with the advantages of having a simple process and high yield. [5,6] This method requires graphite as a precursor or treatment of the carbon source by high-temperature graphitization.…”

Section: Introductionmentioning

confidence: 99%

Effects of Minerals in Anthracite on the Formation of Coal‐Based Graphene

et al. 2019

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The minerals in raw anthracite significantly limit the preparation of coal‐based graphene. Raw and demineralized anthracites were graphitized and coal‐based graphene was prepared by improved Hummers’ oxidation‐reduction method. The morphologies, crystal structures and spectroscopic characteristics of the products in various stages were characterized by scanning electron microscopy, transmission electron microscopy, X‐ray diffraction, Fourier transform infrared spectroscopy, X‐ray photoelectron spectroscopy and Raman spectroscopy. The results show that demineralized or not, anthracite can be used to prepare graphene, but the minerals in anthracite physically inhibit the directional development of graphene sheets. And the residual high temperature conversion products of the minerals embedded between graphene sheets will lead to multiple irregular pore defects on the surface of graphene, which will have strongly unfavorable effects on the properties of coal‐based graphene materials. Demineralization of raw anthracite can reduce the defective pores and oxygen‐containing functional groups on the surface of coal‐based graphene and improves its morphology and properties.

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Section: Introductionmentioning

confidence: 99%

Effects of Minerals in Anthracite on the Formation of Coal‐Based Graphene

et al. 2019

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“…As the result, graphene may have a combination of interesting properties such as large specific surface area [44], high conductivity and flexibility [45,46] as well as unique optical [47,48] and thermal [49,50] properties. Due to these capabilities, graphene can potentially be applicable in many applications including electronics [51], energy conversion and storage devices [45,52], medicine [53], composites [54,55], and microfluidics [56] and also as adsorbent for removal of organic and inorganic poullants from the environment [57].…”

Section: Adsorptionmentioning

confidence: 99%

Applications of Carbon Nanostructures Produced in Molten Salts

Kamali

2020

Green Production of Carbon Nanomaterials in Molten Salts and Applications

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The cathodic exfoliation of graphite in molten salts can be considered as a low-cost and efficient method for the scalable production of carbon nanostructures with various applications including anode materials for Li ion batteries, supercapacitors, ceramic-based composites and adsorbents for removal of organic pollutants. Various nanostructured carbon materials, such as molten salt-produced graphene nanosheets decorated with SnO 2 nanocrystals, Sn-filled carbon nanostructures and graphene-wrapped Si nanoparticles can be fabricated for the application as active materials for lithium-ion batteries. As another application, interconnected graphene nanostructures comprising of nanosheets and nanoscrolls were found to exhibit an excellent performance in electrochemical supercapacitor studies. Moreover, slip cast alumina ceramics containing a low amount of molten salt graphene demonstrated higher values of mechanical properties in comparison with that of bare alumina. As another example, 3D graphene nanosheets produced in molten salts exhibit a high dye adsorption performance in a wide range of the solution pH from 2 to 11. The current chapter reviews these applications. KeywordsMolten salts • Graphene • Supercapacitors • Li-ion batteries • Anode • Ceramic composites • Water purification 6.1 SnO 2 -Graphene Anode Materials for Li-Ion Batteries

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“…Microfluidics is an entirely new field that manipulates fluids in channels as small as tens of micrometers in diameter 4 . The key advantages of these microfluidic systems include regulated liquid flow, minimal reagent and sample use, rapid analysis, system compactness and parallelization, reduced waste generation, along disposability 5,6 . Previously, microfluidics was primarily concerned with incorporating microsensors with fluidic elements (pumps, actuators and valves, so on) and the miniaturization of analytical assays.…”

Section: Introductionmentioning

confidence: 99%

“…Graphene's unique and exotic features include its ultra-light honey comb structure with a planar density of roughly 0.77 mg/m 2 and super thinness (0.35 nm). Because of these features, graphene has piqued the interest of many researchers in the manufacture of microfluidic sensors, and its applications have already been addressed by Chen et al, Sengupta et al, and others 5,15 . Inspired by these graphene-based microfluidic sensors in 2015, Yang et al, for the very first time, fabricated a microfluidic sensor using MoS 2 for fluorescent DNA detection 16 .…”

Section: Introductionmentioning

confidence: 99%