Engineering the interface characteristics on the enhancement of field electron emission properties of vertically aligned hexagonal boron nitride nanowalls

Sankaran, Kamatchi Jothiramalingam; Hoang, Duc‐Quang; Srinivasu, K.; Korneychuk, Svetlana; Turner, Stuart; Drijkoningen, Sien; Pobedinskas, Paulius; Verbeeck, Johan; Leou, Keh Chyang; Lin, I‐Nan; Haenen, Ken

doi:10.1002/pssa.201600233

Cited by 6 publications

(10 citation statements)

References 37 publications

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“…The growth of diamond thin films, especially at low temperatures, is attracting increasingly more interest due to its suitability for a wide variety of applications, such as biosensing, lubricity, or corrosion protective layers. In addition, diamond nanostructures are being considered for nanoapplications; i.e., diamond nanowires, plates, or needles are promising materials for applications, such as field and thermionic emitters, , nanophotonics, and drug delivery systems . Despite interesting properties, such as high hardness, good thermal conductivity, biocompatibility, chemical hardness, and doping possibility, control over the morphology and crystal orientation remains challenging.…”

Section: Introductionmentioning

confidence: 99%

On the Origin of Diamond Plates Deposited at Low Temperature

Drijkoningen

Pobedinskas

Korneychuk

et al. 2017

Crystal Growth & Design

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KEYWORDS low temperature diamond deposition, diamond plates, LA MW PE CVD The crucial requirement for diamond growth at low temperatures, enabling a wide range of new applications, is a high plasma density at a low gas pressure, which leads to a low thermal load onto sensitive substrate materials. While these conditions are not within reach for resonance cavity plasma systems, linear antenna microwave delivery systems allow the deposition of high quality diamond films at temperatures around 400°C and at pressures below 1 mbar. In this work the co-deposition of high quality plates and octahedral diamond grains in nanocrystalline films is reported. In contrast to previous reports claiming the need of high temperatures (T ≥ 850 °C), low temperatures (320 °C ≤ T ≤ 410 °C) were sufficient to deposit diamond plate structures. Cross-sectional high resolution transmission electron microscopy studies show that these plates are faulty cubic diamond terminated by large {111} surface facets with very little sp 2 bonded carbon in the grain boundaries. Raman and electron energy loss spectroscopy confirm a high diamond quality, above 93 % sp 3 carbon content. Three potential mechanisms, that can account for the initial development of the observed plates rich with stacking faults, and are based on the presence of impurities, are proposed.

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Section: Introductionmentioning

confidence: 99%

On the Origin of Diamond Plates Deposited at Low Temperature

Drijkoningen

Pobedinskas

Korneychuk

et al. 2017

Crystal Growth & Design

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“…The formation of these phases is largely dependent on the density of defects that may be created during fabrication. The tBN and aBN phases have also been studied quite meticulously in our studies [35][36][37][38][39]. Meanwhile, the hard phases of BN are formed by sp 3 bonding and have a higher density compared to the soft ones.…”

Section: Introductionmentioning

confidence: 82%

“…These parameters directly affect the nucleation and growth of BN materials on the substrate surface. Because of that we fixed the above parameters, in order to stabilize the hBN sample fabrication conditions [35][36][37][38][39]. At the same time, we changed the external conditions such as the distance from the substrate surface to the BN target (d), substrate temperature (T sub ), tilting substrate surface in respect of the virtual line from the BN target center to the substrate (α) and the substrate materials (Si, NCD, Cr/ Au) for the purpose of creating hBN has the desired quality and orientation.…”

Section: Unbalanced Radio Frequency Sputteringmentioning

confidence: 99%

Growth mechanisms of hBN crystalline nanostructures with rf sputtering deposition: challenges, opportunities, and future perspectives

Hoang¹,

VU²,

NGUYEN³

et al. 2023

Phys. Scr.

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Most hBN nanostructures were fabricated using the chemical method. However, growing by the physical method also has many advantages, they are easy to synthesize this material on a large area with up-scaling setups. Even two-dimensional hexagonal boron nitride is similar to graphene structure, however there is a little work referring to the fabrication process of this material. Hence, a sufficiently detailed report on physically fabricated hBN materials is essential. This review analyzes the results that we have studied over the past ten years with the synthesis and fabrication of this material using physical vapor deposition – RF sputtering, incorporation with other techniques, strongly emphasized on growth mechanisms of this material.

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“…[5] Nevertheless, carbon nanomaterials such as nanotubes, nanoflakes, or even graphene have been used as extraordinary electron sources. [6] Their FEE characteristics are superior, [7] but they show poor stability and a short lifetime, [8] which prevents them from becoming a practical material for device applications. Basically, the FEE process involves two steps including the electron transporting into the emitting sites and the electron tunneling into vacuum from Superior field electron emission (FEE) characteristics are achieved in edge-rich diamond-enhanced carbon nanowalls (D-ECNWs) grown in a single-step chemical vapor deposition process co-doped with boron and nitrogen.…”

Section: Introductionmentioning

confidence: 99%

Stable Field Electron Emission and Plasma Illumination from Boron and Nitrogen Co‐Doped Edge‐Rich Diamond‐Enhanced Carbon Nanowalls

Ficek

Dec

Sankaran

et al. 2021

Adv Materials Inter

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Superior field electron emission (FEE) characteristics are achieved in edge‐rich diamond‐enhanced carbon nanowalls (D‐ECNWs) grown in a single‐step chemical vapor deposition process co‐doped with boron and nitrogen. The structure consists of sharp, highly conductive graphene edges supplied by a solid, diamond‐rich bottom. The Raman and transmission electron microscopy studies reveal a hybrid nature of sp3‐diamond and sp2‐graphene in these nanowalls. The ab‐initio calculations were carried out to support the experimental observations of diamond‐graphene hybrid structure. Finally, this hybrid D‐ECNWs is employed as a cathode in an FEE device resulting in a low turn‐on field of 3.1 V µm−1, a large field enhancement factor, a high FEE Je of 2.6 mA cm−2, and long lifetime stability of 438 min. Such an enhancement in the FEE originates from the unique materials combination, resulting in good electron transport from the graphene phases and efficient FEE of electrons from the sharp edges on the nanowalls. The prospective application of these materials is displayed by employing these hybrids as cathodes in a microplasma device ensuing a low threshold voltage of 160 V and high plasma stability of 140 min, which confirms the role of these hybrid structured nanowalls in the enhancement of electron emission.

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Engineering the interface characteristics on the enhancement of field electron emission properties of vertically aligned hexagonal boron nitride nanowalls

Cited by 6 publications

References 37 publications

On the Origin of Diamond Plates Deposited at Low Temperature

On the Origin of Diamond Plates Deposited at Low Temperature

Growth mechanisms of hBN crystalline nanostructures with rf sputtering deposition: challenges, opportunities, and future perspectives

Stable Field Electron Emission and Plasma Illumination from Boron and Nitrogen Co‐Doped Edge‐Rich Diamond‐Enhanced Carbon Nanowalls

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