Electron Beam Emission from a Diamond-Amplifier Cathode

Chang, X.; Wu, Qiong; Ben‐Zvi, I.; Burrill, A.; Kewisch, J.; Rao, T.; Smedley, J.; Wang, Erdong; Muller, Edward N.; Busby, R.; Dimitrov, Dimitre

doi:10.1103/physrevlett.105.164801

Cited by 36 publications

(22 citation statements)

References 12 publications

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“…Among the numerous ongoing R&D activities on cathodes, the use of diamond crystals as charge amplifiers [60], and of layers of materials such as CsBr to enhance the QE in metal cathodes [61], are showing promising results. Interesting results, with potential for future applications in high-brightness electron sources, are also coming from 'plasmonic' cathodes, where superficial plasma waves are excited on a metal cathode surface to enhance photoemission [62].…”

Section: Thermionic and Other Cathodesmentioning

confidence: 99%

Schemes and challenges for electron injectors operating in high repetition rate X-ray FELs

Sannibale

Filippetto

Papadopoulos

2011

Journal of Modern Optics

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Requirements and challenges for high-brightness electron injectors operating in a high-repetition-rate X-ray FEL are described. Schemes presently under development or study are reviewed, and their advantages and limitations are compared. Beam dynamics and engineering/technological aspects are addressed, with a particular emphasis placed on how the high-repetition-rate requirement impacts the choice of cathodes and of gun/accelerator technologies, and on how those choices consequently impact beam dynamics.

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Section: Thermionic and Other Cathodesmentioning

confidence: 99%

Schemes and challenges for electron injectors operating in high repetition rate X-ray FELs

Sannibale

Filippetto

Papadopoulos

2011

Journal of Modern Optics

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“…In our earlier transmission-mode experiment, we terminated both diamond surfaces with metal. Then, the measured transmission gain depends only on the primary electrons' energy and diamond's internal electric field [2]. The model of secondary-electron generation and transmission in the diamond are discussed in Ref.…”

Section: Transmission Gainmentioning

confidence: 99%

“…Hence, the field inside the diamond changes with time, resulting in a transmitted charge, and thereby an emitted charge, both of which are time dependent. Our previous experiments show that this shielding takes place over $1 s, a relatively slow process [2]. It is important to assess precisely the probability of the emission of an electron that reaches the emission surface, and to understand the mechanism responsible for its trapping and its dependence on external conditions.…”

Section: Introductionmentioning

confidence: 99%

Secondary-electron emission from hydrogen-terminated diamond: Experiments and model

Wang

Ben‐Zvi

Rao

et al. 2011

Phys. Rev. ST Accel. Beams

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A hydrogen-terminated diamond is a proven efficient electron emitter that can support emission of high average current. Several factors dictate the amplifier's gain: the number of secondary electrons created at their point of entry into the diamond, the fraction of created electrons transmitted to the emitting face, and the fraction of transmitted electrons emitted. In this paper, we present a model detailing the impact of charge trapping at the surface on the instantaneous electric field inside the diamond, and its effect on the transmission gain. The ratio of instantaneous emitted electrons to the transmitted electrons depends on the electron's energy distribution and the surface barrier. We calculated the latter by evaluating the magnitude of the negative-electron affinity that is modified by the Schottky effect due to the presence of the external applied field. The instantaneous values then were time integrated to yield the time-averaged ratio of the number of emitted electrons to the transmitted ones. The findings from the model agree very well with our experimental measurements. As an application of the model, we estimate the energy spread of the electrons inside the diamond from the measured secondary-electron emission.

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“…1 The resulting electron yield is orders of magnitude higher than materials with a positive electron affinity, 2,3 and hence diamond is the material of choice for many emerging electron emission applications in both vacuum 4,5 and solution. 6 The electron affinity of diamond is controlled by the surface termination.…”

Section: Introductionmentioning

confidence: 99%

Extremely high negative electron affinity of diamond via magnesium adsorption

et al. 2015

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We report large negative electron affinity (NEA) on diamond (100) using magnesium adsorption on a previously oxygen-terminated surface. The measured NEA is up to (−2.01 ± 0.05) eV, the largest reported negative electron affinity to date. Despite the expected close relationship between the surface chemistry of Mg and Li species on oxygen-terminated diamond, we observe differences in the adsorption properties between the two. Most importantly, a high-temperature annealing step is not required to activate the Mg-adsorbed surface to a state of negative electron affinity. Diamond surfaces prepared by this procedure continue to possess negative electron affinity after exposure to high temperatures, air and even immersion in water.

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Electron Beam Emission from a Diamond-Amplifier Cathode

Cited by 36 publications

References 12 publications

Schemes and challenges for electron injectors operating in high repetition rate X-ray FELs

Schemes and challenges for electron injectors operating in high repetition rate X-ray FELs

Secondary-electron emission from hydrogen-terminated diamond: Experiments and model

Extremely high negative electron affinity of diamond via magnesium adsorption

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