ISBN: 3-540-65747-9
TITLE: Ion Sources
AUTHOR: Zhang, Huashun
TOC:

1 INTRODUCTION 1
1.1 Major Applications and Requirements 1
1.2 Performances and Research Subjects 1
1.3 Historical Development 8
2 GAS DISCHARGE FUNDAMENTALS 11
2.1 Thermionic Emission 11
2.2 Secondary Electron Emission 12
2.3 Surface Ionization 13
2.4 Elastic and Inelastic Collisions 16
2.4.1 Collision and Probability of Collision 16
2.4.2 Elastic Collision and Its Cross Section 18
2.4.3 Inelastic Collision 20
2.5 Ionization Cross Section 21
2.6 Recombination of Charged Particles 22
2.7 Mobility 23
2.8 Diffusion Coefficient 25
2.9 Particle Distribution in a Retardation Region 26
2.10 Ambipolar Diffusion 26
2.11 Magnetic Field Influence on Particle Motion 28
2.12 Fundamentals of a Hot-Cathode Arc Source 29
2.12.1 Stable Theory of the Cathode Double Sheath 29
1. Bipolar Flow 30
2. Cathode Double Sheath 31
2.12.2 Cathode Double Sheath Oscillations and Noise 34
2.12.3 Scattering of Primary Electrons 35
2.12.4 Beam-Plasma Interaction 36
2.12.5 Positive Column Plasma 38
2.12.6 Anode Region 44
2.12.7 Minimum Pressure 45
References 46
3 EXTRACTION SYSTEMS FOR ION SOURCES 47
3.1 Extraction Systems Requirements 47
3.2 Extraction System with a Solid Emitter 48
3.2.1 Space-Charge-Limited Flow for an Ideal Diode 48
1. Plane Diode 48
2. Cylindrical Diode 51
3. Spherical Diode 51
4. Some Universal Relationships 52
3.2.2 Space-Charge-Limited Flow with Multiple Ion Species 54
3.2.3 Pierce-Shape Extraction System 56
3.2.4 High-Perveance Electron Gun 57
3.3 Emittance and Brightness 58
3.3.1 Emittance 58
3.3.2 Brightness 60
3.3.3 Relation Between Brightness and Emittance 61
3.3.4 Effective Emittance 62
3.3.5 Emittance and Brightness of an Ion Source 63
3.4 Ion Extraction from a Plasma 65
3.4.1 Plasma-Sheath Equation and the Emitting Current from a Plasma 65
3.4.2 The "Extractable Flow" from an Extraction System 70
3.4.3 Adjustment of Ion Emissive Surface 71
3.4.4 Comparison between a Plasma Ion Source and an Electron Gun Extraction System 72
3.5 Geometry of Extraction Systems 73
3.5.1 Typical Types and Geometries 73
3.5.2 Probe Extraction Systems for Low Plasma Density 76
1. Principle and Analytical Model 76
2. Experimental Results 79
3.5.3 Aperture Extraction Systems for Medium Plasma Density 79
1. Analytical Model for a Two-Electrode System 80
2. Circular Three Electrode Extraction System 83
3. Slit Extraction System 86
4. Four Electrode Extraction System 89
3.5.4 Expansion Cup Extraction System for High Plasma Density 90
1. Some Properties of a Diffusing Plasma 90
2. Extraction System of a Duoplasmatron Source 92
3.5.5 Large-Area Multi-Aperture Extraction Systems 95
1. Multi-aperture Beam Focusing by Aperture Displacement 96
2. Power Loading of the Electrodes 100
3.5.6 Grid-controlled Extraction System 101
3.6 Research Methods of Extraction Systems 103
3.6.1 Experimental Research 103
3.6.2 Analytical Approaches to Beam Optics 103
3.6.3 Numerical Simulations 104
1. Physical Models 104
2. Physical Equations 106
3. Some Results 108
3.7 Some Other Problems 110
3.7.1 Transverse Magnetic Field Effects on Ion Extraction 110
3.7.2 Technological Problems of Extraction Systems 111
1. Suppression of Breakdown in the Lateral Extraction Ion Source 111
2. Some Technological Problems 112
References 113
4 POSITIVE ION SOURCES 116
4.1 Classification of Ion Sources 116
4.2 Hot Cathodes 118
4.2.1 Requirements and Types of Hot Cathodes 118
4.2.2 Cathode Material and Lifetime 119
4.2.3 Effects of Discharge Current 122
4.2.4 Magnetic Field Effects of the Filament Current 122
4.2.5 Plasma Cathodes 123
4.3 Arc Source in a Uniform Magnetic Field 125
4.4 Hot-Cathode Penning Source 131
4.4.1 Simple Principle 131
4.4.2 Typical Structures 134
4.5 Duoplasmatron Ion Source 135
4.5.1 General Principle 135
4.5.2 Formation of the Constriction Double Sheath 137
4.5.3 Primary Parameters 138
4.5.4 Heavy Ion Duoplasmatron Source 141
4.6 Hot-Cathode "Freeman" Source 142
4.7 Broad Beam Ion Sources 144
4.8 Cold-Cathode PIG Source 148
4.8.1 Principles of a Cold-Cathode Penning Discharge 148
4.8.1 Cold-Cathode PIG Sources 149
4.9 Radio-Frequency Ion Source 153
4.9.1 Principle of an RF Discharge 153
4.9.2 Magnetic Field Effects and Structures 157
4.9.3 Heavy Ion RF Sources 159
1. Metallic Ion RF Sources 159
2. RF Ion Source for Ion Thrusters 161
3. RF Tritium Ion Source 162
4.9.4 Beam Current Modulation from RF Sources 162
4.10 Technology of Heavy Ion Sources 163
4.10.1 Special Requirements for Heavy Ion Sources 163
4.10.2 Types of Heavy Ion Sources 164
4.10.3 Surface Ionization and Thermionic Emission Source 165
4.10.4 High Field Ion Source 168
1. Gas Field Ionization Source 169
2. Liquid Metal Ion Source 170
4.10.5 Feed Material 174
4.10.6 Methods of Vapor Transport 176
4.10.7 Design and Operation of Heavy Ion Sources 179
References 182
5 GIANT ION SOURCES 187
5.1 DuoPIGatron Ion Source 188
5.1.1 Essential Principle 188
5.1.2 Improvement of the Plasma Uniformity 190
5.1.3 Typical Results 193
5.2 Periplasmatron Ion Source 196
5.3 Multifilament Ion Source 197
5.3.1 Essential Principle 197
5.3.2 Multifilaments and Multislot Extraction Electrode 199
5.3.3 Ionization Efficiency 200
5.3.4 Typical Results 201
5.4 Magnetic Multipole Ion Source 203
5.4.1 General Description 203
5.4.2 Magnetic Multipole (Multicusp) Field 204
1. Confinement Principle of a Cusped Field 204
2. Magnetic Field Configuration 206
3. Influence of Other Parameters 209
5.4.3 Typical Results and Applications 212
5.5 Hall Accelerator 213
5.6 Cluster Ion Source 216
5.7 Intense Pulsed Ion Source 218
5.7.1 Reflex Triode 219
5.7.2 Magnetically Insulated Ion Diode 220
5.7.3 Anode Plasma and Structure 222
References 225
6 MULTIPLY CHARGED ION SOURCES 229
6.1 Introduction 229
6.2 Formation of Multiply Charged Ions 231
6.2.1 Physical Definitions for Multiple Ionization 231
1. Ionization Potential 231
2. Total and Partial Ionization Cross Section 232
3. Distribution of Charge States and Average Charge State 233
6.2.2 Formation of Multiply Charged Ions 233
1. Multiple Ionization by Single Collisions 233
2. Stepwise Single Ionization of Ions 235
3. Stepwise Multiple Ionization of Ions 238
4. Ionization of Metastable Atoms or Ions 238
6.2.3 Loss Processes of Multiply Charged Ions 239
1. Loss by Charge Transfer 239
2. Loss by Recombination 240
3. Loss by Diffusion 241
6.2.4 Balance Equations for Ion Charge States 243
6.2.5 Multiply Charged Ion Generation by Stripping of Fast Ions 246
6.3 Major Research of MCIS 246
6.4 Multiply Charged Electron Beam Ion Source 249
6.4.1 Electron Beam Ion Source 249
1. Typical Structure 249
2. Essential Principle and Results 251
6.4.2 Electron Beam Ion Trap 255
6.4.3 Time-of-Flight EBIS (TOFEBIS) 256
6.5 Conventional Multiply Charged Ion Sources 256
6.5.1 Penning Multicharged Ion Source 256
1. Introduction, Types, and Typical Structures 256
2. The Essential Principle of Generating Multiply Charged Ions in a PIG Source 257
3. Experimental Results 258
6.5.2 Duoplasmatron MCIS 261
6.5.3 Other Plasma Discharge MCIS 263
1. Radio-Frequency Ion Source 263
2. Electrostatic Oscillating Electron Ion Source 263
3. Trapped Ion Source 264
6.6 Microwave Ion Sources 264
6.6.1 Electron Cyclotron Resonance Multiply Charged Ion Source 264
1. Development and Typical Structure 264
2. Essential Principles and Results 268
6.6.2 High Intensity Microwave Ion Source 277
1. Cavity Type Microwave Ion Source 277
2. Antenna Type Microwave Ion Source 281
3. High-intensity Microwave Proton Source 282
6.6.3 Hot Electron Layer Ion Source (HELIOS) 284
6.6.4 Beam-Plasma Ion Source 285
6.7 High Density Plasma Sources 286
6.7.1 Laser Multiply Charged Ion Source 286
6.7.2 Metal Vapor Vacuum Arc Ion Sources 292
6.7.3 Vacuum Spark Ion Source 297
References 297
7 MASS AND ENERGY SPECTRA OF ION SOURCES 304
7.1 Mass Spectra of a Hydrogen Ion Source 304
7.1.1 Physical Processes Effecting the Mass Spectra 305
7.1.2 Particle Balance Equations for Determining the Mass Spectra 310
7.1.3 Proton Content of an RF Ion Source 313
7.1.4 Mass Spectra of a Magnetic Multipole Ion Source 314
7.1.5 Mass Spectra of a Duoplasmatron Ion Source 315
7.1.6 Mass Spectra of a Hot-Cathode PIG Ion Source 316
7.1.7 Mass Spectra of a Cold-Cathode PIG Ion Source 317
7.2 Energy Spectra of Ion Sources 318
7.2.1 Physical Cause of the Energy Spread 318
7.2.2 Energy Spectra of an RF Ion Source 319
7.2.3 Energy Spectra of Other Ion Sources 322
References 323
8 NEGATIVE ION SOURCES 325
8.1 Introduction 325
8.1.1 Electron Affinity 325
8.1.2 Historical Development 326
8.2 Negative Ion Formation Processes 327
8.3 Volume Formation of Negative Ions 328
8.3.1 H^- Formation by Electron Impact 328
8.3.2 Negative Ion Formation by Multiple Charge-Transfer 332
8.4 Surface Formation of Negative Ions 338
8.4.1 Work-function of Surfaces 338
8.4.2 Surface Sputtering 342
1. Essential Principle 343
2. Distributions of Sputtered Particles 347
8.4.3 Particle Reflection from a Solid Surface 348
1. Essential Principles 348
2. Parameter Dependence of Reflection 349
3. Distribution of Reflected Particles 350
8.4.4 Secondary Ion Emission 352
1. General Principles 352
2. H^- Ion Formation by Particle and Surface Interaction 355
3. Other Negative Ions Formed by Sputtering 356
8.4.5 Negative Surface Ionization 357
8.5 Destruction of Negative Ions 358
8.5.1 Destruction Processes of Negative Ions 358
8.5.2 Cross-Sections of H^- Destruction 359
8.6 Volume H^- Ion Source 361
8.6.1 Duoplasmatron Negative Ion Sources 361
8.6.2 Penning Negative Ion Sources 363
8.6.3 Magnetically Filtered Multicusp Volume Sources 364
1. Essential Principle 364
2. Magnetic Filter 364
3. Dependence on Various Parameters 366
4. Cesium Seeded Multicusp H^- Source 368
5. Giant H^- Ion Sources 368
8.6.4 Other Volume Production Negative Ion Sources 371
8.6.5 H^- Ion Extraction and Electron Suppression 372
8.7 Surface-Plasma H^- Ion Sources 374
8.7.1 Magnetron H^- Ion Sources 374
8.7.2 Penning Surface-Plasma H^- Ion Sources 377
8.7.3 Magnetic Cusped Surface-Plasma H^- Sources 381
8.7.4 Hollow Discharge Duoplasmatron H^- Sources 382
8.8 Charge-Transfer Negative Ion Sources 384
8.8.1 Exchange Target 384
8.8.2 Charge-Transfer H^- Ion Sources 385
1. Radio Frequency Negative Ion Source 385
2. Powerful Charge-Transfer H^- Ion Sources 386
8.8.3 He^- Ion Source 387
8.8.4 Other Charge-Transfer Heavy Negative Ion Sources 387
8.9 Cesium Sputter Negative Ion Sources 388
8.9.1 Middleton Cesium Sputter Source (UNIS) 388
8.9.2 Cesiated Plasma Sputter Negative Ion Sources 391
1. Radial Extraction Sputtering Penning Negative Ion Source 391
2. Self-Extraction Plasma-Sputtering Negative Ion Source 392
8.9.3 Universal High Intensity Cesium Sputter Negative Ion Sources 395
8.10 Dissociative Source by Positive Ion Impact 397
8.11 Surface Negative Ionization Ion Sources 397
References 398
9 SELF-NEUTRALIZATION OF BEAM SPACE CHARGE 404
9.1 Self-Neutralization of Positive Beams 404
9.2 Dynamic Decompensation of the Beam Space Charge 410
References 415
10 BEAM DIAGNOSTICS FOR ION SOURCES 416
10.1 Introduction 416
10.2 Beam Current Measurements 417
10.2.1 Electric Methods Intercepting the Beam 417
1. DC Current Measurement by a Faraday Cup 417
2. Pulsed Current Measurement by a Faraday Cup 420
10.2.2 Calorimetric Methods 421
1. Essential Principles of Calorimetric Methods 421
2. Flow Calorimeter 422
3. Stem Calorimeter 423
4. Calorimeter in an Isothermal Mode 424
10.2.3 Magnetic-Conduction Probe for Pulsed Beams 424
10.2.4 Residual Gas Ionization Chamber 425
10.3 Beam Density Profile Measurements 425
10.3.1 Mechanical Beam Profile Scanner 427
10.3.2 Segmented Wire (or Target) 429
10.3.3 Electric or Magnetic Scanner 431
10.3.4 Other Methods 431
10.4 Beam Emittance Measurements 432
10.4.1 Physical Concept of Beam Emittance Measurement 432
10.4.2 Principle and Errors of Emittance Measurement 436
10.4.3 Various Emittance Devices 440
1. "Pepper-Pot" Emittance Probe 440
2. Mechanical Scanner 441
3. Electric (Magnetic) Scanner 442
4. Slit-Multiple Collector Device 444
5. "Three Beam Widths" Method 444
10.5 Ion Energy Spectra Measurements 446
10.5.1 Cylindrical Electrostatic Energy Analyzer 447
10.5.2 Retarding Field Energy Analyzer 449
10.6 Mass or Charge Spectra Measurements 452
10.6.1 Umform Magnetic Field Analyzer 453
10.6.2 E  B Mass Separator 454
10.6.3 Time-of-Flight Spectrometer 457
References 459
APPENDIX 462
A1. Physical Constants 462
A2. Common Usits and Conversion Factors 463
A3. Densities, Melting Points, Boiling Points, Vapor Pressure, Some Source Feed Compounds 464
A4. Work-function, First and Stepwise Ionization Potential, Electron Affinity of the Elements 468
A5. The Calculated Values of the Stepwise Ionization Potential of Noble Gases 472
A6. The Minimum Workfunctions of Amorphous Surfaces with Adsorbate Materials at Optimum Layer 472
A7. Solution of the Plasma-Sheath Equation 473
INDEX 474
END
