Direct observation of electron emission from the grain boundaries of chemical vapour deposition diamond films by tunneling atomic force microscopy

Chatterjee, Vijay; Harniman, Robert L.; May, Paul; Barhai, P.K.

doi:10.1063/1.4875059

Cited by 31 publications

(24 citation statements)

References 21 publications

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“…This work has provided direct evidence that electron field emission from diamond surfaces originate preferentially from the diamond grain boundaries in doped-UNCD surfaces and not from the diamond grains or other topographical features. This is consistent with the model for electron field emission based on lowering of the emission threshold due to a reduction of the electron affinity of the diamond surface surrounding graphitic structures on the surface [47] and corroborates the findings of other groups [29,30,49,50,51]. As long as the grain boundaries remain relatively conducting compared to the bulk grains, electrons can travel from the contact at the reverse side of the Si substrate into the base of the film, then up to the grain boundaries and be emitted from the surface.…”

Section: Discussionsupporting

confidence: 92%

“…However, the data from only one sample with 400×400 nm scale, it is hard to point out whether the diamond grains or grain boundaries were the actual conducting/emitting sites. Recently Harniman et al, [29] and V. Chatterjee et al [30] showed that the grain boundaries are the prominent electron emission sites for polycrystalline diamond films by using PeakForce-controlled tunneling atomic force microscopy (PF-TUNA) in ambient conditions, where the topographic and tunneling current information were collected under PeakForce feedback. However, in ambient conditions, the surface deformation mediated by surface contaminations and surface conducting layers, drastically affect the tunneling current and hence for the real detection of the electron emission sites [29,31].…”

Section: Introductionmentioning

confidence: 99%

“…However, in ambient conditions, the surface deformation mediated by surface contaminations and surface conducting layers, drastically affect the tunneling current and hence for the real detection of the electron emission sites [29,31]. Moreover, from the PF-TUNA experiments in ambient conditions, it is very hard to find out whether the nanometer sized diamond grain boundaries were the real emission sites [29,30]. Therefore, it is important to carry out the measurements in ultra-high vacuum (UHV) conditions to avoid the effect of surface contaminants and surface conducting layers present in ambient conditions on the tunneling current and hence to detect the real conducting/emitting sites.…”

Section: Introductionmentioning

confidence: 99%

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Straight imaging and mechanism behind grain boundary electron emission in Pt-doped ultrananocrystalline diamond films

Panda

Inami

Sugimoto

et al. 2017

Carbon

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A detailed scanning tunneling microscopic (STM) investigation is carried out to directly image and understand the mechanism behind enhanced conductivity and electron field emission (EFE) properties for platinum (Pt) ion doped/post-annealed ultrananocrystalline diamond (UNCD) films. Straight imaging of conducting/nonconducting sites is mapped by dynamic scanning tunneling microscopy (D-STM). Energy dissipation mapping and the local current-voltage measurements illustrate that grain boundaries are the conducting/emitting sites. Further, this fact is supported by the high resolution current imaging tunneling spectroscopy (CITS). The formation of abundant conducting sp 2 nanographitic phases along the diamond grain boundaries, confirmed from transmission electron microscopic examinations, is believed to be the genuine factor that helps for the easy transport of electrons and hence enhanced the conductivity/emission properties. The fabrication of these films with high conductivity and superior EFE properties is a direct and simple approach which opens up new prospects in flat panel displays and high brightness electron sources. Moreover, we expect the energy dissipation associated with assisted tunneling process of electrons from the tip of STM to sample surface, can be a very useful technique for imaging heterostructured semiconducting surfaces due to their electrical conductivity differences in nanometer scale, which can explain many physical and chemical properties.

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Section: Discussionsupporting

confidence: 92%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Straight imaging and mechanism behind grain boundary electron emission in Pt-doped ultrananocrystalline diamond films

Panda

Inami

Sugimoto

et al. 2017

Carbon

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confidence: 83%

Scanning probe microscopy and field emission schemes for studying electron emission from polycrystalline diamond

Chubenko

Baturin

Baryshev

2016

Applied Physics Letters

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The letter introduces a diagram that rationalizes tunneling atomic force microscopy (TUNA) observations of electron emission from polycrystalline diamonds as described in recent publications [1,2]. The direct observations of electron emission from grain boundary sites by TUNA could indeed be evidence of electrons originating from grain boundaries under external electric fields. At the same time, from the diagram it follows that TUNA and field emission schemes are complimentary rather than equivalent for results interpretation. It is further proposed that TUNA could provide better insights into emission mechanisms by measuring the detailed structure of the potential barrier on the surface of polycrystalline diamonds.The question is yet to be answered of why synthetic polycrystalline diamonds (micro-, nano-, or ultra-nanocrystalline diamond, abbreviated MCD, NCD, UNCD) containing a large amount of the carbon sp 2 phase are such excellent electron field emitters. These diamonds have a low threshold (turn-on) electric field ∼10 MV/m and yield significant current densities. A powerful approach, called the graphitic patch model, to explain this behavior was attempted by Cui, Ristein and Ley [3]. It first originated to plausibly explain sub-bandgap photoelectric emission in single-crystal diamond. The main idea was that the surface always has small carbonic (graphitic) phase patches (electron emitters). The work function (4.6 eV) is reduced when the property of negative electron affinity (NEA, which can be as low as −1.3 eV) is induced on the surrounding diamond host surface. Experimentally, the potential barrier [4] of a patch can be as low as 3.0 eV. The model showed excellent agreement with experiments. While the existence of carbon patches on the surface of a single-crystal diamond could be questioned (signatures seen from indirect spectroscopic measurements), in polycrystalline diamonds the carbon sp 2 phase is a separation interlayer between diamond micro-or nano-crystallites (or grains), and can be directly imaged by transmission electron microscopy in large amounts. The carbon interlayer is also called the grain boundary (GB). Recent observations [1,2] have demonstrated that tunneling electron emission originates from GBs. The observations were made by a specialty atomic force microscope equipped with tunneling current measurement capability, abbreviated as TUNA. The authors hypothesized that TUNA measurements should be representative in the conventional field emission case, meaning that GBs emitting in the TUNA scheme should be emitting sites in a field emitter based on a polycrystalline diamond. Nevertheless, they did not provide a straightforward explanation how exactly TUNA represents the field emission mechanism. In this letter, we present a diagram bridging the TUNA scheme results and the conventional field emission scheme. The diagram is based on the graphitic patch model and the usual electrostatics.Panel (a) in the figure illustrates a case in which a GB of a lateral size of 1 nm is brought in contact ...

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“…Eletrodos formados por filmes de diamante dopado com boro (DDB) têm sido alvo das atenções de muitos pesquisadores ao longo dos anos (1)(2)(3)(4)(5)(6)(7) devido a vantagens que incluem alta resistência à corrosão; ampla faixa de potencial de trabalho para a maioria dos solventes e eletrólitos; alta inércia química e eletroquímica; baixa sensibilidade ao oxigênio dissolvido; correntes residuais ou de fundo pequenas e estáveis, o que resulta numa excelente razão sinal/ruído; atividade eletroquímica reprodutível e alta condutividade elétrica (8) . O diamante em seu estado natural é um dos melhores isolantes presentes na natureza, podendo, porém, ter sua condutividade sensivelmente melhorada pela adição de dopantes (B, N, O, S) na rede cristalina deste material.…”

Section: Introductionunclassified

Diamante dopado com boro obtido pela técnica HFcVD para detecção eletroanalítica de metai

Braga

Ferreira

Baldan

et al. 2015

RBAV

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Direct observation of electron emission from the grain boundaries of chemical vapour deposition diamond films by tunneling atomic force microscopy

Cited by 31 publications

References 21 publications

Straight imaging and mechanism behind grain boundary electron emission in Pt-doped ultrananocrystalline diamond films

Straight imaging and mechanism behind grain boundary electron emission in Pt-doped ultrananocrystalline diamond films

Scanning probe microscopy and field emission schemes for studying electron emission from polycrystalline diamond

Diamante dopado com boro obtido pela técnica HFcVD para detecção eletroanalítica de metai

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