Water-processed carbon nanotube/graphene hybrids with enhanced field emission properties

Song, Minghao; Xu, Peng; Song, Yenan; Wang, Xu; Li, Zhenhua; Shang, Xuefu; Wu, Huizhen; Zhao, Pei; Wang, Miao

doi:10.1063/1.4930966

Cited by 22 publications

(8 citation statements)

References 20 publications

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“…SGVCNTs show higher current density than SGCNTs, which is due to the minimized screening effect. Here in our samples, the E th is defined as the field required to emit a current density of 0.1 A cm −2 [46] and the E th value of SGVCNTs was found to be 1.931 V μm −1 which is ∼1.5 and ∼1.2 times lower than CNTs and SGCNTs heterostructures, respectively (shown in figure S3(b)).…”

Section: Field Emission Studiesmentioning

confidence: 76%

“…where J is the macroscopic current density, f is the emitter's local work function, E is the applied electric field, β is the field enhancement factor, N is the density of the emission sites, α is the average area of the emission sites, a and b are known as the first and second FN constants and their values are 1.54×10 −6 AeV/V 2 and 6.83×10 7 eV −3/2 V/cm, respectively [45]. As the work function (f) of graphene and CNTs are the same (f=5.0 eV), we have chosen the work function of the SGCNTs heterostructure f=5.0 eV [46,47]. Figure 5(a) shows emitter average current density (J) versus electric field (E) plots of FLG, CNTs, SGCNTs and, SGVCNTs.…”

Section: Field Emission Studiesmentioning

confidence: 99%

“…Here SGVCNTs show lower E th in comparison with the other samples. The E on is defined as field required to emit the current density of 10 μA cm −2 [17,46], which is coming out to be 1.89, 1.2, 0.78, 0.45 V μm −1 for FLG, CNTs, SGCNTs and SGVCNTs, respectively (shown in figure S3(a)). From these analyses it is realized that the E on of SGVCNTs is ∼4 times lower than that of FLG and ∼3 times lower than non-vertical CNTs which is due to the small apex curvature, high specific surface, high aspect ratio, nanometer-sized tip radii [19,20].…”

Section: Field Emission Studiesmentioning

confidence: 99%

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Study of field emission properties of pure graphene-CNT heterostructures connected via seamless interface

Riyajuddin

Kumar²,

Soni³

et al. 2019

Nanotechnology

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Vertically aligned carbon nanotubes (CNTs) have proven to be one of the best materials for use as an efficient field emitter. To further improve their efficiency as well as long-term use in practical devices, it is necessary to reduce the quantum resistance originating from the interface between electrode and emitters and the entanglement of the CNTs in a bundle texture. Thus, the incorporation of graphene at the bottom of CNT bundles via a seamless carbonaceous interface can easily solve this bottleneck. In this work we have demonstrated for the first time, growth and field emission properties of pure seamless graphene-CNT heterostructures and pure seamless graphene-vertically patterned oriented CNTs heterostructures (SGVCNTs) on Si/SiO2 substrates in contrast to the bare CNT mats and few-layer graphene structures without using any tedious post transfer processes. It was observed that seamless SGVCNTs show better field emission performance in terms of higher current density (236 mA cm−2), lowered turn-on field (0.45 V μm−1) and threshold field (1.931 V μm−1 @100 mA cm−2), and improved field enhancement factor (β ∼ 41 315) which is improved ∼4 fold when compared to a bare CNT mat. The significant improvement of the field emission performance of SGVCNTs is mainly attributed to the low resistive seamless C–C covalent carbonaceous interface, the higher number of emitter sites and patterned vertical orientation that leads to long-term stability of the field emitter with minimal loss up to 32 h. This finding could provide an important solution for carbonaceous material based field emitters for real phase device applications.

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Section: Field Emission Studiesmentioning

confidence: 76%

Section: Field Emission Studiesmentioning

confidence: 99%

Section: Field Emission Studiesmentioning

confidence: 99%

See 1 more Smart Citation

Study of field emission properties of pure graphene-CNT heterostructures connected via seamless interface

Riyajuddin

Kumar²,

Soni³

et al. 2019

Nanotechnology

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“…В последние годы одним из перспективных направлений развития исследований в области графен-УНТ соединений является получение композитных материалов с улучшенными эмиссионными характеристиками для последующего применения в качестве наноэмиттеров [49][50][51][52][53][54]. Одним из последних достижений в этой области стало экспериментальное получение методом электрофоретического осаждения гибридных пленок ОУНТ/графен, демонстрирующих максимальный эмиссионный ток величиной 80 mA с соответствующей плотностью тока 160 mA/cm 2 при напряженности электрического поля 9.6 V/µm [54].…”

Section: Introductionunclassified

Графен/Нанотрубные Квази-1d-Структуры В Сильных Электрических Полях

Глухова¹,

Слепченков²

2022

Физика Твердого Тела

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In silico studies of the behavior of graphene/nanotube quasi-one-dimensional (1D) structures with covalent bonded graphene and nanotube in strong electric fields with a strength of 10^7–10^8 V/cm have been carried out. The atomic structure, band structure, electron transmission function, electrical conductivity, and regularity of the electronic structure changes in strong fields have been studied. It is found that the electron transmission function of quasi-1D structures has an intensity peak at the Fermi level in contrast to nanotubes and graphene. As a result of quantum molecular dynamics modeling, the regularities of deformation of the atomic framework and its destruction under the action of ponderomotive force have been established. We have found a critical value of the strength at which the electric field detaches the graphene from the tube. It is ~ 2 ∙ 10^8 V/cm. A further increase leads to the detachment of graphene from the tube with its simultaneous destruction.

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“…In recent years, one of the promising areas of graphene-CNT research included production of composite materials with improved emission characteristics for further use as nano-emitters [49][50][51][52][53][54]. One of the latest achievements in this area was the experimental electrophoretic deposition of SWCNT/graphene hybrid films demonstrating the maximum emission current of 80 mA with the corresponding current density of 160 mA/cm 2 at an electric field strength of 9.6 V/µm [54].…”

Section: Introductionmentioning

confidence: 99%

Graphene/nanotube quasi-1D structures in strong electric fields

Glukhova

Слепченков

2022

Physics of the Solid State

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In silico studies of the behavior of graphene/nanotube quasi-one-dimensional (1D) structures with covalent bonded graphene and nanotube in strong electric fields with a strength of 10^7-108 V/cm have been carried out. The atomic structure, band structure, electron transmission function, electrical conductivity, and regularity of the electronic structure changes in strong fields have been studied. It is found that the electron transmission function of quasi-1D structures has an intensity peak at the Fermi level in contrast to nanotubes and graphene. As a result of quantum molecular dynamics modeling, the regularities of deformation of the atomic framework and its destruction under the action of ponderomotive force have been established. We have found a critical value of the strength at which the electric field detaches the graphene from the tube. It is ~2·108 V/cm. A further increase leads to the detachment of graphene from the tube with its simultaneous destruction. Keywords: graphene/nanotube structures, electrical conductivity, ponderomotive force, strong electric fields.

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Water-processed carbon nanotube/graphene hybrids with enhanced field emission properties

Cited by 22 publications

References 20 publications

Study of field emission properties of pure graphene-CNT heterostructures connected via seamless interface

Study of field emission properties of pure graphene-CNT heterostructures connected via seamless interface

Графен/Нанотрубные Квази-1d-Структуры В Сильных Электрических Полях

Graphene/nanotube quasi-1D structures in strong electric fields

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