Plasmon Enhanced Photoemission

Polyakov, Aleksandr N.

doi:10.2172/1182733

Cited by 4 publications

(4 citation statements)

References 74 publications

(123 reference statements)

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“…with x µ (τ ) on a geodesic parametrized by an invariant parameter τ . The propagator in flat space (37) has indeed the form…”

Section: Appendix E: Symmetriesmentioning

confidence: 99%

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Cosmic fluctuations from a quantum effective action

Wetterich

2015

Phys. Rev. D

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Does the observable spectrum of cosmic fluctuations depend on detailed initial conditions? This addresses the question if the general inflationary paradigm is sufficient to predict within a given model the spectrum and amplitude of cosmic fluctuations, or if additional particular assumptions about the initial conditions are needed. The answer depends on the number of e-foldings Nin between the beginning of inflation and horizon crossing of the observable fluctuations. We discuss an interacting inflaton field in an arbitrary homogeneous and isotropic geometry, employing the quantum effective action Γ. An exact time evolution equation for the correlation function involves the second functional derivative Γ (2) . The operator formalism and quantum vacua for interacting fields are not needed. Use of the effective action also allows one to address the change of frames by field transformations (field relativity). Within the approximation of a derivative expansion for the effective action we find the most general solution for the correlation function, including mixed quantum states. For not too large Nin the memory of the initial conditions is preserved. In this case the cosmic microwave background cannot disentangle between the initial spectrum and its processing at horizon crossing. The inflaton potential cannot be reconstructed without assumptions about the initial state of the universe. We argue that for very large Nin a universal scaling form of the correlation function is reached for the range of observable modes. This can be due to symmetrization and equilibration effects, not yet contained in our approximation, which drive the short distance tail of the correlation function towards the Lorentz invariant propagator in flat space.

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“…with x µ (τ ) on a geodesic parametrized by an invariant parameter τ . The propagator in flat space (37) has indeed the form…”

Section: Appendix E: Symmetriesmentioning

confidence: 99%

“…(investigations of the effects of interactions in a non-flat geometry can be found in refs. [27,[30][31][32][33][34][35][36][37][38][39][40][41].) In our simple approximation interactions appear in the form of the inflaton potential.…”

Section: Introductionmentioning

confidence: 99%

Cosmic fluctuations from a quantum effective action

Wetterich

2015

Phys. Rev. D

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“…refs. [41][42][43][44][45][46][47][48][49][50][51][52][53][54]. The issue is similar to the understanding of thermalization of arbitrary initial correlation functions in flat space, for which powerful functional methods have been developed [55][56][57][58][59][60][61][62][63][64][65].…”

Section: General Solution For Graviton Correlationmentioning

confidence: 99%

Primordial cosmic fluctuations for variable gravity

Wetterich

2016

J. Cosmol. Astropart. Phys.

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The observability of primordial cosmic fluctuations does not require a geometric horizon H −1 , which is exceeded temporarily by the wavelength of fluctuations. The primordial information can be protected against later thermal washout even if all relevant wavelengths remain smaller than H −1 . This is demonstrated by formulating the equations governing the cosmic fluctuations in a form that is manifestly invariant under conformal field transformations of the metric. Beyond the field equations this holds for the defining equation for the correlation function, as expressed by the inverse of the second functional derivative of the quantum effective action. An observable almost scale invariant spectrum does not need an expanding geometry. For a variable Planck mass it can even arise in flat Minkowski space.

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“…The metal photocathode has been researched for a long time and used in many facilities, due to its virtue of high brightness, long lifetime, and low cost. And it has been indicated that it holds great promise to eject a uniform 3D ellipsoid electron bunch with only linear internal space charge fields because of its ultrafast response characteristic, which is an ideal distribution for a high-brightness FEL operation [4][5][6]. But, in order to ensure a high photoemission yield, the metal photocathode usually needs to be pumped by high power ultraviolent laser, which undoubtedly increases the demand and cost for the drive laser [7].In recent years, the plasmon-enhanced photocathode (PEP) attracts more attentions, which introduces the surface plasmon polarizations (SPPs) to enhance the interaction between laser and materials [8].…”

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confidence: 99%

Effect of plasmonic near field on the emittance of plasmon-enhanced photocathode

Jiang

Huang

et al. 2018

Nuclear Instruments and Methods in Physics Research Section A:

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The introduction of the surface plasmon polarizations makes the emittance of the photocathode complicated. In this paper, the emittance of plasmon-enhanced photocathode is analyzed. It is first demonstrated that the plasmonic near field can increase the emittance of the plasmon-enhanced photocathode. A simulation method has been used to estimate the emittance caused by plasmonic near field, and the suppression method also has been discussed, both of which are significant for the design of high performance plasmon-enhanced photocathode. IntroductionWith the virtue of prompt response (ps-fs), high brightness, and low emittance etc., the photocathode has becomes a significant enabling technology for the 4 th generation light sources and advanced accelerator and electron microscopy technology, such as X-ray free electron laser, inverse Compton scattering sources, energy recovery linac, and dynamic transmission electron microscopy etc [1-3]. The metal photocathode has been researched for a long time and used in many facilities, due to its virtue of high brightness, long lifetime, and low cost. And it has been indicated that it holds great promise to eject a uniform 3D ellipsoid electron bunch with only linear internal space charge fields because of its ultrafast response characteristic, which is an ideal distribution for a high-brightness FEL operation [4][5][6]. But, in order to ensure a high photoemission yield, the metal photocathode usually needs to be pumped by high power ultraviolent laser, which undoubtedly increases the demand and cost for the drive laser [7].In recent years, the plasmon-enhanced photocathode (PEP) attracts more attentions, which introduces the surface plasmon polarizations (SPPs) to enhance the interaction between laser and materials [8]. With the help of SPPs, this kind of photocathode has the potential to yield much more electrons than traditional metal photocathode [9-11], and it can operate with longer wavelength laser, which reduces the demand of drive laser system [7,12]. Moreover, it has longer lifetime, lower vacuum requirement, and relatively more mature preparation technology than some high quantum efficiency semiconductor photocathodes.However, emittance is also a vital parameter for the usefulness of electron sources in many applications [13][14][15][16][17][18]. When the surface plasmon polarizations (SPPs) are introduced into the photocathode, the emittance of the bunch increases [12], and the mechanism of which becomes complicated and unknown. All of these will restrict the development of high performance plasmon-enhanced photocathode [19].In this paper, based on the theory of SPPs, we research the influence of SPPs on the emittance of PEP. And a plasmon-enhanced photocathode excited with square hole array has been designed to operate at 532nm. Using this PEP, we demonstrate and research the influence of plasmonic near field on the emittance. Characteristics of Plasmon-enhanced photocathodeThe process of photoemission can be broken up into three steps: (1) photon absorption and...

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Plasmon Enhanced Photoemission

Cited by 4 publications

References 74 publications

Cosmic fluctuations from a quantum effective action

Cosmic fluctuations from a quantum effective action

Primordial cosmic fluctuations for variable gravity

Effect of plasmonic near field on the emittance of plasmon-enhanced photocathode

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