Unifying physics of accelerators, lasers and plasma. (2015)
- Record Type:
- Book
- Title:
- Unifying physics of accelerators, lasers and plasma. (2015)
- Main Title:
- Unifying physics of accelerators, lasers and plasma
- Further Information:
- Note: Andrei Seryi.
- Authors:
- Seryi, Andrei
- Contents:
- Foreword Preface Author Basics of Accelerators and of the Art of Inventiveness Accelerators and society Acceleration of what and how Uses, actions and the evolution of accelerators Livingston plot and competition of technologies Accelerators and inventions How to invent How to invent — evolution of the methods TRIZ method TRIZ in action — examples TRIZ method for science AS-TRIZ Creativity Transverse Dynamics Maxwell equations and units Simplest accelerator Equations of motion Motion of charged particles in EM fields Drift in crossedxfields Motion in quadrupole fields Linear betatron equations of motion Matrix formalism Pseudo-harmonic oscillations Principal trajectories Examples of transfer matrices Matrix formalism for transfer lines Analogy with geometric optics An example of a FODO lattice Twiss functions and matrix formalism Stability of betatron motion Stability of a FODO lattice Propagation of optics functions Phase space Phase space ellipse and Courant–Snyder invariant Dispersion and tunes Dispersion Betatron tunes and resonances Aberrations and coupling Chromaticity Coupling Higher orders Synchrotron Radiation SR on the back of an envelope SR power loss Cooling time Cooling time and partition SR photon energy SR — number of photons SR effects on the beam SR-induced energy spread SR-induced emittance growth Equilibrium emittance SR features Emittance of single radiated photon SR spectrum Brightness or brilliance Ultimate brightness Wiggler and undulator radiation SRForeword Preface Author Basics of Accelerators and of the Art of Inventiveness Accelerators and society Acceleration of what and how Uses, actions and the evolution of accelerators Livingston plot and competition of technologies Accelerators and inventions How to invent How to invent — evolution of the methods TRIZ method TRIZ in action — examples TRIZ method for science AS-TRIZ Creativity Transverse Dynamics Maxwell equations and units Simplest accelerator Equations of motion Motion of charged particles in EM fields Drift in crossedxfields Motion in quadrupole fields Linear betatron equations of motion Matrix formalism Pseudo-harmonic oscillations Principal trajectories Examples of transfer matrices Matrix formalism for transfer lines Analogy with geometric optics An example of a FODO lattice Twiss functions and matrix formalism Stability of betatron motion Stability of a FODO lattice Propagation of optics functions Phase space Phase space ellipse and Courant–Snyder invariant Dispersion and tunes Dispersion Betatron tunes and resonances Aberrations and coupling Chromaticity Coupling Higher orders Synchrotron Radiation SR on the back of an envelope SR power loss Cooling time Cooling time and partition SR photon energy SR — number of photons SR effects on the beam SR-induced energy spread SR-induced emittance growth Equilibrium emittance SR features Emittance of single radiated photon SR spectrum Brightness or brilliance Ultimate brightness Wiggler and undulator radiation SR quantum regime Synergies between Accelerators, Lasers and Plasma Create Beam sources Lasers Plasma generation Energize Beam acceleration Laser amplifiers Laser repetition rate and efficiency Fiber lasers and slab lasers CPA — chirped pulse amplification OPCPA — optical parametric CPA Plasma oscillations Critical density and surface Manipulate Beam and laser focusing Weak and strong focusing Aberrations for light and beam Compression of beam and laser pulses Beam cooling Optical stochastic cooling Interact Conventional Acceleration Historical introduction Electrostatic accelerators Synchrotrons and linacs Wideröe linear accelerator Alvarez drift tube linac Phase focusing Synchrotron oscillations Waveguides Waves in free space Conducting surfaces Group velocity Dispersion diagram for a waveguide Iris-loaded structures Cavities Waves in resonant cavities Pill-box cavity Quality factor of a resonator Shunt impedance — Rs Energy gain and transit-time factor Kilpatrick limit Power sources IOT — inductive output tubes Klystron Magnetron Powering the accelerating structure Longitudinal dynamics Acceleration in RF structures Longitudinal dynamics in a travelling wave Longitudinal dynamics in a synchrotron RF potential — nonlinearity and adiabaticity Synchrotron tune and betatron tune Accelerator technologies and applications Plasma Acceleration Motivations Maximum field in plasma Early steps of plasma acceleration Laser intensity and ionization Laser pulse intensity Atomic intensity Progress in laser peak intensity Types of ionization Barrier suppression ionization Normalized vector potential Laser contrast ratio Schwinger intensity limit The concept of laser acceleration Ponderomotive force Laser plasma acceleration in nonlinear regime Wave breaking Importance of laser guidance Betatron radiation sources Transverse fields in the bubble Estimations of betatron radiation parameters Glimpse into the future Laser plasma acceleration — rapid progress Compact radiation sources Evolution of computers and light sources Plasma acceleration aiming at TeV Multi-stage laser plasma acceleration Beam-driven plasma acceleration Laser-plasma and protons Light Sources SR properties and history Electromagnetic spectrum Brief history of synchrotron radiation Evolution and parameters of SR sources Generations of synchrotron radiation sources Basic SR properties and parameters of SR sources SR source layouts and experiments Layout of a synchrotron radiation source Experiments using SR Compton and Thomson scattering of photons Thomson scattering Compton scattering Compton scattering approximation Compton scattering characteristics Compton light sources Free Electron Lasers FEL history SR from bends, wigglers and undulators Radiation from sequence of bends SR spectra from wiggler and undulator Motion and radiation in sine-like field Basics of FEL operation Average longitudinal velocity in an undulator Particle and field energy exchange Resonance condition Microbunching conceptually FEL types Multi-pass FEL Single-pass FEL Microbunching and gain Details of microbunching FEL low-gain curve High-gain FELs FEL designs and properties FEL beam emittance requirements FEL and laser comparison FEL radiation properties Typical FEL design and accelerator challenges Beyond the fourth-generation light sources Proton and Ion Laser Plasma Acceleration Bragg peak DNA response to radiation Conventional proton therapy facilities Beam generation and handling at proton facilities Beam injectors in proton facilities Plasma acceleration of protons and ions — motivation Regimes of proton laser plasma acceleration Sheath acceleration regime Hole-boring radiation pressure acceleration regime Light-sail radiation pressure acceleration regime Emerging mechanisms of acceleration Glimpse into the future </P&g … (more)
- Edition:
- 1st
- Publisher Details:
- Boca Raton : CRC Press
- Publication Date:
- 2015
- Extent:
- 1 online resource, illustrations (black and white)
- Subjects:
- 539.73
Particle accelerators
Lasers
Plasma (Ionized gases) - Languages:
- English
- ISBNs:
- 9781482240597
- Related ISBNs:
- 9781482240580
- Notes:
- Note: Includes bibliographical references and index.
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- British Library HMNTS - ELD.DS.140646
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