Field enhancement factor and field emission from a hemi-ellipsoidal metallic needle

Pogorelov, Evgeny G.; Zhbanov, A. I.; Chang, Yia‐Chung

doi:10.1016/j.ultramic.2009.01.006

Cited by 57 publications

(37 citation statements)

References 38 publications

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“…This value for k is very close to the usual value of 3 valid for a metallic half-sphere. 30 In Fig. 6, the main differences between the model and the experiment are at the very top of the tip.…”

Section: Interpretation Of Experimental Resultsmentioning

confidence: 97%

“…[24][25][26][27][28][29] A simpler derivation of the same result can be obtained by considering the field that is generated by a linear distribution of charges, whose density increases linearly along its length. 24,30 The electron-optical phase shift can also be calculated easily in this case. It is useful to outline this derivation, starting from the electrostatic potential of two opposite point charges 6dq located at the variable coordinates (0, 6t, 0) in a Cartesian system (x, y, z), with the z-axis parallel to and in the same direction as the electron beam, in the form…”

Section: Theoretical Modelmentioning

confidence: 99%

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Towards quantitative off-axis electron holographic mapping of the electric field around the tip of a sharp biased metallic needle

Beleggia

Kasama

Larson

et al. 2014

Journal of Applied Physics

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We apply off-axis electron holography and Lorentz microscopy in the transmission electron microscope to map the electric field generated by a sharp biased metallic tip. A combination of experimental data and modelling provides quantitative information about the potential and the field around the tip. Close to the tip apex, we measure a maximum field intensity of 82 MV/m, corresponding to a field k factor of 2.5, in excellent agreement with theory. In order to verify the validity of the measurements, we use the inferred charge density distribution in the tip region to generate simulated phase maps and Fresnel (out-of-focus) images for comparison with experimental measurements. While the overall agreement is excellent, the simulations also highlight the presence of an unexpected astigmatic contribution to the intensity in a highly defocused Fresnel image, which is thought to result from the geometry of the applied field.

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Section: Interpretation Of Experimental Resultsmentioning

confidence: 97%

Section: Theoretical Modelmentioning

confidence: 99%

Towards quantitative off-axis electron holographic mapping of the electric field around the tip of a sharp biased metallic needle

Beleggia

Kasama

Larson

et al. 2014

Journal of Applied Physics

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“…As for the theoretical models of field emission, most of the models have been established for carbon nanotubes (such as floating spheres18 and cylinders19) and metallic nanostructures (such as pyramids20, hemi-ellipsoidal21 and semi-infinite electrodes22). However, little has been reported on the semiconducting nano-emitters due to the complication mainly induced by the electric field penetration into the emitters and the surface states232425.…”

Section: Resultsmentioning

confidence: 99%

Enhanced Cold Field Emission of Large-area Arrays of Vertically Aligned ZnO-nanotapers via Sharpening: Experiment and Theory

Zhang

Meng

et al. 2014

Sci Rep

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Large-area arrays of vertically aligned ZnO-nanotapers with tailored taper angle and height are electrodeposited on planar Zn-plate via continuously tuning the Zn(NH3)4(NO3)2 concentration in the electrolyte. Experimental measurements reveal that the field-emission performance of the ZnO-nanotaper arrays is enhanced with the sharpness and height of the ZnO-nanotapers. Theoretically, the ZnO-nanotaper is simplified to a “charge disc” model, based on which the characteristic macroscopic field enhancement factor (γC) is quantified. The theoretically calculated γC values are in good agreement with the experimental ones measured from arrays of ZnO-nanotapers with a series of geometrical parameters. The ZnO-nanotaper arrays have promising potentials in field-emission. The electrochemical synthetic strategy we developed may be extended to nanotaper arrays of other materials that are amenable to electrodeposition, and the “charge disc” model can be used for quasi-one-dimensional field emitters of other materials with nano-sized diameters.

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“…5(b)) was considered in many papers (for example Refs. (Forbes et al, 2003;Wang et al, 2004;Pogorelov et al, 2009) …”

Section: Hemisphere On a Planementioning

confidence: 99%

“…We can replace the spheroid by a linearly charged thread as we show in our recent paper (Pogorelov et al, 2009). The thread is a green line in Fig.…”

Section: Hemi-ellipsoid On a Planementioning

confidence: 99%

Carbon Nanotube Field Emitters

Zhbanov¹,

Pogorelov²,

Chang³

2010

Carbon Nanotubes

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Field enhancement factor and field emission from a hemi-ellipsoidal metallic needle

Cited by 57 publications

References 38 publications

Towards quantitative off-axis electron holographic mapping of the electric field around the tip of a sharp biased metallic needle

Towards quantitative off-axis electron holographic mapping of the electric field around the tip of a sharp biased metallic needle

Enhanced Cold Field Emission of Large-area Arrays of Vertically Aligned ZnO-nanotapers via Sharpening: Experiment and Theory

Carbon Nanotube Field Emitters

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