Vyhodnocení vlivu vzdálenosti clonek u sekundárního detektoru na tlak v komoře scintilátoru s ohledem na kritické proudění pomocí systému FloWorks / Using Cosmos FloWorks for analyse the detector.

Hladík, Jaroslav

January 2010

This work follow up gas fluxion problems in detector chamber of enviromental scanning electron microscope. Describes basic electron microscopes characteristic and evaluation output signal. Basic focus of this work is proposal placing screening in detector in surroundings programme SolidWorks 2008. There is by the help of system COSMOS FloWorks effected analysis pumping gas with different pressure and mutual position which has significant influence in given fluxion conditions. Programmatic surroundings makes it possible to simulation 3D and evaluation fluxion method final capacities by setting fundamental conditions of solving, which would have been next to real behaviour of gas in real detector.

Measurement of Angle-Resolved Secondary Electron Spectra

Davies, Robert

01 May 1999

Theoretical formulations of secondary electron emission over the past 20 years have exceeded the confirming ability of available measurements. An instrument has been developed and tested for the purpose of obtaining simultaneous angle- and energy-resolved (AER) secondary and backscattered electron measurements for energetic electrons incident on conducting surfaces. The instrument is found to be in good working order and the data quality found to be excellent for nearly all angles and energies investigated. A representative set of AER measurements has been acquired for 1500 e V electrons normally incident on polycrystalline gold. The data have been used to construct angle-resolved (AR) spectra and energy-resolved (ER) angular distributions, which have been examined both as surface plots and cross sections. Analysis of the measurements strongly suggests that secondary electrons comprise the bulk of emitted electrons at energies much greater than the traditionally accepted maximum secondary electron energy of 50 eV. Additional evidence suggests the ability to investigate dominant secondary and backscattered electron production mechanisms in several energy domains.

electron spectra

secondary electron emission

backscatter

angular distribution

Physics

An Instrument for Experimental Secondary Electron Emission Investigations, with Application to the Spacecraft Charging Problem

Davies, Robert

01 May 1996

Secondary electron emission (SEE) and incident-particle backscattering are important processes accompanying the impact of energetic electrons and ions on surfaces. The phenomena play a key role in the buildup of electrical charge on spacecraft surfaces, and are therefore of particular interest to scientists attempting to model spacecraft charging. In response to a demonstrated need for data, techniques for determining total secondary electron (SE) and backscatter (BS) yields (del) and (neu), and associated scattering-angle-resolved,scattering-energy-resolved, and simultaneous angle-energy-resolved yields have been developed. Further, an apparatus capable of making the necessary measurements for experimental determination of these quantities---for conducting materials in an ultra-high vacuum environment-has been designed, constructed, and partially tested. The apparatus is found to be in working order, though in need of fine-tuning, and the measurement technique successful. Investigations using a 1-3 Kev beam of monoenergetic electrons normally incident on bulk AI have been undertaken with the new apparatus. Electron-stimulated desorption of surface contaminants has been observed, as has been beam-induced carbon deposition, and an empirical model describing the resulting dynamic evolution of (del)is presented. Totalb and 11 values obtained in the present investigation are found to be in qualitative agreement with the results of previously reported investigations, though quantitative disagreement of b-values is substantial. Specifically, evidence is presented suggesting that previously reported SE yields for clean AI under electron bombardment (in the 1-3 Kev energy range) are in error by as much as 30 %.

Spacecraft charging

secondary electron emission

backscatter

measurement

Physics

Emitting Wall Boundary Conditions in Continuum Kinetic Simulations: Unlocking the Effects of Energy-Dependent Material Emission on the Plasma Sheath

Bradshaw, Kolter Austen

23 February 2024

In a wide variety of applications such as the Hall thruster and the tokamak, understanding the plasma-material interactions which take place at the wall is important for improving performance and preventing failure due to material degradation. In the region near a surface, the plasma sheath forms and regulates the electron and ion fluxes into the material. Emission from the material has the potential to change sheath structure drastically, and must be modeled rigorously to produce accurate predictions of the fluxes into the wall. Continuum kinetic codes offer significant advantages for the modeling of sheath physics, but the complexity of emission physics makes it difficult to implement accurately. This difficulty results in major simplifications which often neglect important energy-dependent physics. A focus of the work is on proper simulation of the sheath. The implementation of source and collision terms is discussed, alongside a brief study of the Weibel instability in the sheath demonstrating the necessity of proper collision implementation to avoid missing relevant physics. A novel implementation of semi-empirical models for electron-impact secondary electron emission into the boundary conditions of a continuum kinetic code is presented here. The features of both high and low energy regimes of emission are represented self-consistently, and the underlying algorithms are flexible and can be easily extended to other emission mechanisms, such as ion-impact secondary electron emission. The models are applied to simulations of oxidized and clean lithium for fusion-relevant plasma regimes. Oxidized lithium has a high emission coefficent and the sheath transitions into space-charge limited and inverse modes for different parameters. The breakdown of the classical sheath results in an increase of energy fluxes to the surface, with potential ramification for applications. / Doctor of Philosophy / Great advances are being made in a variety of promising applications of plasma physics, such as the development of spacecraft thrusters and fusion devices. Many of these devices constrain the flow of plasma within a material channel, leading degradation of the wall due to particle impact to be a serious concern for durability and lifespan. The plasma sheath is a region next to these material surfaces where ions are accelerated towards the wall, while electrons are repelled. As particles from the sheath impact the material, they cause the emission of secondary particles back into the sheath. This can drastically change the expected fluxes into the material and consequently the degradation expected to occur. Continuum kinetic simulations are a valuable tool for predicting and modeling the evolution of the sheath, but they are limited in their ability to rigorously do material emission physics by their inability to directly represent particle interactions with the surface. As such, past treatments of material emission in continuum kinetics tend to sacrifice valuable energy-dependent physics for simplified models.par To facilitate better understanding of the effects of emission on the sheath and the ramifications it might have for applications, the work here seeks to develop a framework for capturing the entire range of energy-dependent emission physics within a continuum kinetic framework. The implementation relies on semi-empirical models of beam emission data, focusing on simplicity and flexibility while still capturing the separate emission mechanisms which dominate in different energy regimes. The model is applied to simulations of lithium, an important material for fusion applications. Oxidized lithium has significantly enhanced emission properties over clean lithium, and is found to undergo a shift to non-monotonic sheath modes. The results show that the fundamental changes in the sheath structure due to the increased emission lead to greater energy fluxes into the surface. In this work, only secondary electron emission from the impact of electrons on a surface is examined. However, the underlying algorithms are easily extended to other energy-dependent energy mechanisms, such as ion-impact secondary electron emission.

Plasma Sheath

Plasma-Material Interactions

Secondary Electron Emission

Influence of Surface Charges on Impulse Flashover Characteristics of Alumina Dielectrics in Vacuum

Tsuchiya, Kenji, Okubo, Hitoshi, Ishida, Tsugunari, Kato, Hidenori, Kato, Katsumi

28 December 2009

No description available.

secondary electron emission avalanche

electric field

alumina insulator

surface charge

surface flashover

Vacuum

Interaction cross sections needed for simulation of secondary electron emission spectra from thin metal foils after fast proton impact

Travia, Anderson. Dingfelder, Michael.

January 2009

Thesis (M.S.)--East Carolina University, 2009. / Presented to the faculty of the Department of Physics. Advisor: Michael Dingfelder. Title from PDF t.p. (viewed Apr. 23, 2010). Includes bibliographical references.

Secondary Electron Production and Transport Mechanisms By Measurement of Angle-Energy Resolved Cross Sections of Secondary and Backscattered Electron Emission from Gold

Kite, Jason T.

01 May 2006

This work provides information about interactions that produce emitted electrons from polycrystalline Au. Emission energy- angle- dependent electron spectra from a polycrystalline Au surface have been measured at several incident electron beam energies. The range of incident energies (~100 eV to 2500 eV) extends from below the first crossover energy, through Emaxo, to above the second crossover energy. The conventional distinction between secondary electrons (SE) (50 eV) is found to be crude for the investigation of electron yields using these energy- angle- resolved measurements. A more realistic boundary occurs at the local minima of the emission spectra; this feature is studied as a function of incident energy and emission angle. In addition, deviations observed in the angular resolved emission spectra from isotropic behavior suggests that residual signatures exist in the emission spectra resulting from the anisotropic SE production mechanisms. Based on the disparity between our observations and recent modeling of the emission spectra, the most recent theory and simulation studies may overestimate the occurrence of randomizing collisions of scattered secondary electrons in the model of the transport mechanism. Finally, description of extensive modification to instrumental and analysis methods are described, and their effectiveness is evaluated.

secondary electron

production

transport mechanism

angle energy

cross section

backscattered electron emission

gold

Physics

Pr$_{1-x}$Ca$_x$MnO$_x$ for Catalytic Water Splitting - Optical Properties and In Situ ETEM Investigations

Mildner, Stephanie

05 August 2015

Gegenstand der vorliegenden Dissertation ist die Untersuchung von Ca-dotierten PrMnO3 (PCMO) als Katalysator für die (photo)elektrochemische Wasseroxidation. Im Fokus der Untersuchungen stehen die folgenden elementaren Schritte des Gesamtprozesses: i) Die optische Absorption in PCMO wird zunächst als Funktion der Ca-Dotierung und der Temperatur untersucht mit dem Ziel, den Einfluß von Korrelationseffekten auf die optischen Eigenschaften zu verstehen. Die präsentierten Ergebnisse zeigen, dass die Bildung kleiner Polaronen im PCMO als Folge starker Korrelationswechselwirkungen in breites Absorptionsmaximum im Nah-Infrarot bis sichtbarem Energiebereich verursacht, welches im Rahmen eines Photonen-assistierten Polaronenhüpfprozesses und einer Anregung zwischen Jahn-Teller-aufgespaltenen Zuständen diskutiert wird. Weiterhin legt die Dotierungsabhängigkeit der Spektren nahe, dass O 2p und Mn 3d Hybridzustände die Fermienergie-nahe elektronische Struktur bestimmen, wobei der relative Anteil von O 2p mit der Ca-Dotierung variiert. ii) Der aktive Zustand von PCMO in Kontakt mit Wasser bzw. Wasserdampf wird mit Hilfe von Zyklovoltammetrie und in situ ‚environmental‘ Transmissionselektronenmikroskopie (ETEM) für verschiedene Dotierlevels untersucht. Die Ergebnisse beider Methoden ergeben, dass die katalysierte Wasseroxidation gemäß $2\text{H}_2\text{O} \rightarrow \text{O}_2 + 4 \text{H}^+$ mit einem Korrosionsprozess in Form einer Pr/Ca Verarmung und Amorphisierung der PCMO-Elektrode konkurriert. Die höchste katalytische Aktivität sowie Korrosionsstabilität werden im mittleren Dotierungsbereich gefunden. Auf Basis der in situ ETEM Ergebnisse wird außerdem gezeigt, dass durch Zufügen von Monosilan zu Wasserdampf-basierten Elektrolyten im ETEM eine Elektronenstrahl-induzierte Wasseroxidation an aktiven PCMO Oberflächen über die Sekundärreaktion $\text{SiH}_4+2\text{O}_2\rightarrow\text{SiO}_2+2\text{H}_2\text{O}$ nachgewiesen werden kann. Elektronenenergieverlustspektroskopie von PCMO vor und nach der Reaktion in Wasserdampf ergeben, dass der aktive Zustand von PCMO die Bildung und Ausheilung von Sauerstoffleerstellen im Rahmen einer Interkalation des bei der Wasseroxidation freiwerdenden Sauerstoffs beinhaltet. Die Rolle des Elektronenstrahls als Triebkraft für die Wasseroxidation im ETEM wird mithilfe von Elektronenholographie und elektrischen Experimenten sowie theoretischer Modellierung basierend auf Sekundärelektronenemissionen als ein positives Elektronenstrahl-induziertes elektrisches Potential identifiziert.

530

Physik (PPN621336750)

water oxidation

in situ electrochemistry

Environmental TEM

perovskite

manganite

polaron

optical conductivity

electron beam induced potential

secondary electron yield

water oxidation

in situ electrochemistry

Environmental TEM

perovskite

manganite

polaron

optical conductivity

electron beam induced potential

secondary electron yield

Secondary electron yield measurements of anti-multipacting surfaces for accelerators

Wang, Sihui

January 2016

Electron cloud is an unwanted effect limiting the performance of particle accelerators with positively charged particle beams of high-intensity and short bunch spacing. However, electron cloud caused by beam induced multipacting can be sufficiently suppressed if the secondary electron yield (SEY) of accelerator chamber surface is lower than unity. Usually, the SEY is reduced by two ways: modification of surface chemistry and engineering the surface roughness. The objective of this PhD project is a systematic study of SEY as a function of various surface related parameters such as surface chemistry and surface morphology, as well as an effect of such common treatments for particle accelerators as beam pipe bakeout and surface conditioning with a beam, ultimately aiming to engineer the surfaces with low SEY for the electron cloud mitigation. In this work, transition metals and their coatings and laser treated surface were studied as a function of annealing treatment and electron bombardment. The transition metal thin films have been prepared by DC magnetron sputtering for further test. In the first two Chapter of this thesis, the literature review on electron emission effect is introduced, which includes the process of the electron emission, the influence factor and examples of low SEY materials. In the third Chapter, the experimental methods for SEY measurements and surface investigation used in this work are described. In Chapter 4, the SEY measurement setup which is built by myself are introduced in detail. In Chapter 5 transition metals and their coatings and non-evaporable getter (NEG) coatings have been studied. All the samples have been characterized by SEY measurements, their surface morphology was analysed with Scanning Electron Microscopy (SEM) and their chemistry was studied with X-ray Photoelectron Spectroscopy (XPS). Different surface treatments such as conditioning by electron beam, thermal treatment under vacuum on the sample surfaces have been investigated. For example, the maximum SEY (δmax) of as-received Ti, Zr, V and Hf were 2.30, 2.31, 1.72 and 2.45, respectively. After a dose of 7.9x10-3 C mm-2, δmax of Ti drops to 1.19. δmax for Zr, V and Hf drop to 1.27, 1.48 and 1.40 after doses of 6.4x10-3 C mm-2, 1.3x10-3 and 5.2x10-3 C mm-2, respectively. After heating to 350 °C for 2.5 hours, the SEY of bulk Ti has dropped to 1.21 and 1.40, respectively. As the all bulk samples have a flat surface, there are no difference of morphology. So this reduction of SEY is believed to be a consequence of the growth of a thin graphitic film on the surface after electron bombardment and the removal of the contaminations on the surface after annealing. Chapter 6 of this thesis is about the laser treated surface. Laser irradiation can transform highly reflective metals to black or dark coloured metal. From SEM results, metal surfaces modified by a nanosecond pulsed laser irradiation form a highly organised pyramid surface microstructures, which increase the surface roughness. Due to this reason, δmax of as-received laser treated surface could be lower than 1, which can avoid the electron cloud phenomenon. In this Chapter, the influence of different laser treatment parameters, such as power, hatch distance, different atmospheres on SEY has been investigated. Meanwhile, different surface treatments such as electron conditioning and thermal treatments are studied on the laser treated surface with the investigation of XPS. For example, the δmax of as-received type I with hatch distance 50, 60 and 80 μm in Air are 0.75, 0.75 and 0.80, respectively. After heating to 250 °C for 2 hours, in all case the δmax drop to 0.59, 0.60, 0.62, respectively. The SEYs of all as-received samples are lower than 1 due to the increasing the roughness on the surface by the special pyramid structure. After thermal treatment, the SEY reduces even further. This is caused by removing the contaminations on the surfaces. In conclusion, the present study has largely improved the knowledge of the electron cloud mitigation techniques by surface engineering of vacuum chambers. On the one hand, the surface treatments can modify the surface chemistry, such as the produce the graphic carbon layer on the surface by electron condition and the removal the contamination layer on the top of the surface by thermal treatment. On the other hand, the SEY could be critically low by engineering the surface roughness. Both methods allow reaching δmax less than unity. The efficiency of laser treated surface for e-cloud was demonstrated for a first time leading to a great interest to this new technology application for existing and future particle accelerators.

539.7

Physics of High-Power Vacuum Electronic Systems Based on Carbon Nanotube Fiber Field Emitters

Ludwick, Jonathan

January 2020

No description available.

Electrical Engineering

Field Emission

Carbon Nanotube Fiber

Fowler-Nordheim Tunneling

Secondary Electron Yield

Multipactor Effect

Microporous Surface