ADVANCES INQUANTUM CHEMISTRY

THEORY OF THE INTERACTION OF SWIFT ION SWITH MATTER. PART 2

JOHN R. SABIN

ERKKI BRANDAS

Contributors

ix

Preface xi

Density Functional Theory-based Stopping Power for 3D and 2D Systems 1A. Sarasola, R . H. Ritchie, E . Zaremba and P . M. Echenique

1. Introduction

22. Linear theory of stopping power

43. Density functional theory

1 04. Final remarks and conclusions

26Acknowledgements

26References

27

Friction Force for Charged Particles at Large Distance sfrom Metal Surfaces

2 9

K. T6kesi, X .-M. Tong, C . Lemell and J . Burgdörfe r

1. Introduction

292. Theoretical background

3 23. Specular reflection model

3 64. Time dependent density functional theory

485. Comparison between SRM and TDDFT

5 66. Improvement of TDDFT at large distances

5 87. Conclusions

6 2Acknowledgements

6 2References

6 2

Resonant-Coherent Excitation of Channeled Ions

65F. J . Garcia de Abajo and V . H. Ponce

1. Introduction

6 62. Theoretical framework

7 23. Dynamical mixing of electronic states

7 64. Resonant-coherent excitation to the continuum

7 85. Full calculation and comparison with experiment

7 9Acknowledgements

8 3Appendix A . Coupled channel equations for the relevant bound states

8 3References

86

The Barkas-Effect Correction to Bethe-Bloch Stopping Power

9 1

L. E. Porter

1. Historical background

9 12. Overview and perspective

9 7References

11 6

Molecular Stopping Powers from the Target Oscillato rStrength Distribution

12 1

Remigio Cabrera-Trujillo, John R. Sabin and Jens Oddershed e

1. Introduction

12 22. Precis of oscillator strength based stopping theory

12 43. Oscillator strength distributions

12 64. The polarization propagator

13 25. Some examples

13 96. Remarks and conclusions

14 7Acknowledgements

14 9References

14 9

Chemical and Physical State Effects in Electronic Stopping

15 3

Peter Bauer and Dieter Semrad

1. Introduction

15 32. Bragg's rule

15 53. Definition of PSE and CSE

15 64. Phenomenological description of PSE and CSE

15 65. Velocity dependence of CSE and PSE

15 7References

16 2

Calculation of Cross-Sections for Proton and Antiproton Stoppingin Molecules

165

Lukäg Pichl, Robert J . Buenker and Mineo Kimur a

1. Introduction

16 62. Theoretical model

16 83. Results and discussions

17 44. Conclusion

19 1References

19 2

Advances in the Core-and-Bond Formalism for Proton Stoppin gin Molecular Targets

195

Salvador A. Cruz and Jacques Soullard

1. Introduction

19 52. The Cores-and-Bond formalism

19 73. Mean excitation energy and the LPA

20 34. Advances in CAB studies of molecular stopping

20 65. Conclusions

23 6References

237

Aspects of Relativistic Sum Rules

24 1

Scott M . Cohen

I . Introduction

24 12. Origin of sum rules

2443. Review of early work

2484. Recent advances

25 25. The trouble with relativity

2606. Conclusion

264Acknowledgements

264References

264

Stopping Power of an Electron Gas for Heavy Unit Charges :Models in the Kinetic Approximation

26 7

Istvdn Nagy and Barnabäs Apagyi

1. Introduction and motivations

2682. The target model

26 83. The microscopic model of stopping

2694. Screening

2735. Results

2776. Summary and remarks

28 8Acknowledgements

289References

290

High Z Ions in Hot, Dense Matter

29 3

James W. Dufty, Bernard Talin and Annette Calist i

1. Introduction

2932. Semi-classical statistical mechanics

2953. Green-Kubo relations at small velocities

2974. Impurity ion in an electron gas

2995. Summary and discussion

304Acknowledgements

304References

30 5

Interferences in Electron Emission from H 2 Inducedby Fast Ion Impact

307

N. Stolterfoht and B . Sulik

1. Introduction

3072. Bethe-Born approximation

31 03. Wave optical treatment

31 24. Quantum-mechanical treatment

31 75. Final remarks and conclusions

32 5Acknowledgements

32 6References

326

Thoughts About Nanodosimetry

329

Hans Bichse l

1. Introduction

32 92. Interactions of charged particles with matter

33 03. Calculated energy loss spectra (`straggling functions') f(A;x)

33 24. A simulated energy deposition spectrum g(A,x)

3345. Realistic relation of energy loss to radiation effect

33 56. Conclusions

337References

33 7

Index

339

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