同类推荐
-
-
粒子加速器真空系统
-
¥108.00
-
-
粒子加速器高频技术与微波仿真
-
¥86.00
-
-
静电加速器:一个多功能工具:a versatile t…
-
¥58.00
-
-
同步辐射中的振动散射能谱学:原理及其在生物化学研究中的…
-
¥168.00
-
-
同步辐射:从发现到科学应用:from discover…
-
¥88.00
-
-
回旋加速器原理及新进展
-
¥148.00
-
-
高能粒子加速器关键技术
-
¥248.00
-
-
高压型加速器技术及其应用
-
¥228.00
-
-
质子治疗加速器原理与关键技术
-
¥129.00
-
-
超级显微镜
-
¥58.00
|
|
图书信息
|
|
|
加速器动力学导论
|
ISBN: | 9787301314050 |
定价: | ¥49.00 |
作者: | (美)史蒂芬·佩格斯(Stephen Peggs),(美)托德·萨托加塔(Todd Satogata)著 |
出版社: | 北京大学出版社 |
出版时间: | 2020年08月 |
版次: | 影印版 |
开本: | 23cm |
页数: | 10,206页 |
装祯: | 平装 |
中图法: | TL5 |
相关供货商
供货商名称
|
库存量
|
库区
|
更新日期
|
北京人天书店有限公司
|
2
|
库区2-1/库区7
|
2024-04-19
|
其它供货商库存合计
|
975
|
|
2024-04-19
|
图书简介 | 本书是国际上非常新的加速器物理方面的专著。对于大型强子对撞机LHC,兆瓦级直线型加速器,以及小型加速器的原理以及其上所做的实验都有很详细的介绍。是加速器领域、粒子物理领域非常有价值的图书。自上世纪以来,加速器获得了很大发展,并对物理学的进展起到了巨大的推动作用。本书目的在于说明加速器是如何工作的。入手处是单粒子在加速器中运动的动力学。本书内容包含了粒子物理、加速原理、对撞和束流动力学,以及工程上的考虑。 |
编辑推荐 | ;;;;《Introduction to Accelerator Dynamics(加速器动力学导论)(影印版)》系统讨论了加速器动力学,对高能物理工作者具有参考价值。 |
目录 | Preface page xi r r 1 Introduction 1 r r 1.1 Differences or Differentials? 1 r r 1.2 Phase Space Co-ordinates 3 r r 1.3 Iterations, Ancient and Modern 5 r r 1.4 Accelerator History: The Two Golden Ages 6 r r Exercises 10 r r 2 Linear Motion 13 r r 2.1 Stable Oscillations 13 r r 2.2 Transverse Motion through Mags 16 r r 2.3 Matrix Equations of Motion 19 r r Exercises 22 r r 3 Strong Focusing Transverse Optics 24 r r 3.1 Linear Stability and Twiss Functions 25 r r 3.2 Turn-by-Turn Motion in Phase Space 27 r r 3.3 Propagation across a Fraction of a Turn 29 r r 3.4 Continuous Propagation 30 r r 3.5 FODO Cell Optics 32 r r Exercises 35 r r 4 Longitudinal and Off-Momentum Motion 37 r r 4.1 Constant Momentum Offset: Transverse Motion 37 r r 4.2 The Dispersion Function 39 r r 4.3 Oscillating Momentum: Longitudinal Motion 41 r r 4.4 The Standard Map 45 r r Exercises 48 r r 5 Action and Emittance – One Particle or Many? 50 r r 5.1 Transverse Action-Angle Co-ordinates 50 r r 5.2 Unnormalised Emittances and Beam Sizes 52 r r 5.3 Tune Spread and Filamentation 54 r r 5.4 Linac (Phase Space Area) Emittances 56 r r 5.5 Normalised Emittance and Adiabatic Damping 58 r r 5.6 Longitudinal Phase Space Parameters 60 r r Exercises 61 r r 6 Mags 63 r r 6.1 Normal and Skew Multipole Mags 63 r r 6.2 Iron-Dominated Mags 65 r r 6.3 Conductor-Dominated Mags 66 r r 6.4 Field Quality and Errors 67 r r Exercises 69 r r 7 RF Cavities 73 r r 7.1 Waveguides 73 r r 7.2 Transverse Modes 74 r r 7.3 Cylindrical Resonant Cavities – Pill-Boxes 76 r r 7.4 Cavity Performance Limits 79 r r Exercises 81 r r 8 Linear Errors and Their Correction 83 r r 8.1 Trajectory and Closed Orbit Errors 83 r r 8.2 Linear Coupling 88 r r 8.3 Tune Shifts and β-Waves 89 r r Exercises 92 r r 9 Sextupoles, Chromaticity and the Hénon Map 94 r r 9.1 Chromaticity in a FODO Lattice 94 r r 9.2 Chromaticity Correction 96 r r 9.3 The Hénon Map – A Unit Strength Sextupole in 1-D 98 r r 9.4 A Taxonomy of 1-D Motion 100 r r 9.5 Dynamic Aperture 103 r r Exercises 104 r r 10 Octupoles, Detuning and Slow Extraction 107 r r 10.1 Single Octupole Lattice 107 r r 10.2 Discrete Motion in Action-Angle Space, (J, φ) 109 r r 10.3 Two-Turn Motion with Q ≈ 1/2 110 r r 10.4 Slow Extraction near the Half-Integer 111 r r Exercises 113 r r 11 Synchrotron Radiation – Classical Damping 116 r r 11.1 Spectrum and Distribution Pattern 116 r r 11.2 Energy Loss Per Turn and Longitudinal Damping 119 r r 11.3 Continuous Acceleration 124 r r 11.4 Transverse Damping and Partition Numbers 126 r r Exercises 128 r r 12 Synchrotron Radiation – Quantum Excitation 131 r r 12.1 Energy Spread 132 r r 12.2 Horizontal Emittance 134 r r 12.3 Vertical Emittance 138 r r Exercises 139 r r 13 Linacs – Protons and Ions 141 r r 13.1 Time Structures 142 r r 13.2 Multi-Cell Synchronism 145 r r 13.3 Linear Motion 147 r r 13.4 Radio Frequency Quadrupoles 153 r r 13.5 Beam Losses and Haloes 157 r r Exercises 158 r r 14 Linacs – Electrons 159 r r 14.1 Longitudinal and Transverse Focusing 159 r r 14.2 RF Capture 161 r r 14.3 Bunch Compression 162 r r 14.4 Recirculating and Energy Recovery Linacs 164 r r 14.5 Beam Breakup 166 r r Exercises 169 r r 15 The Beam–Beam Interaction and 1-D Resonances 170 r r 15.1 Round Beam-Beam Interaction 170 r r 15.2 First-Order Theory of 1-D Resonances 174 r r 15.3 Resonance Island Tunes and Widths 176 r r Exercises 180 r r 16 Routes to Chaos 181 r r 16.1 Resonance Overlap 182 r r 16.2 Tune Modulation 184 r r 16.3 Dynamical Zones in Tune Modulation Space 187 r r Exercises 190 r r Appendix A Selected Formulae for Accelerator Design 191 r r A.1 Matrices for Linear Motion through Accelerator Elements 191 r r A.2 Propagation of Twiss Functions 196 r r References 198 r r Index 201 |
|