Basic Quantum Mechanics for Electrical Engineering
Spexia, Stefano.
Basic Quantum Mechanics for Electrical Engineering - Ashland : Arcler Press, (c)2019. - 1 online resource (311 pages)
Chapter 12 Beam Propagation Management In A Fractional Schrödinger Equation
Includes bibliographies and index.
Cover; Half Title Page; Title Page; Copyright Page; Declaration; About the Editor; Table of Contents; List of Contributors; List of Abbreviations; Preface; SECTION I: BLACKBODY RADIATION, THE PHOTONS AND THE ELECTRONS; Chapter 1 Exact Research on the Theory of the Blackbody Thermal Radiation; Abstract; Introduction; Results; Discussion; References; Chapter 2 Describing Compton Scattering And Two-Quantum Positron Annihilation Based On Compton Profiles: Two Models Suited For The Monte Carlo Method; Abstract; Introduction; Modelling of Compton Scattering Modelling of Two-Quanta e+ e- AnnihilationConclusions; Acknowledgments; References; Chapter 3 Momentum Exchange In The Electron Double-Slit Experiment; Abstract; Introduction; Momentum Conservation in Double Slit Diffraction; Momentum Exchange Mechanisms; On The Possibility of Trajectory Explanations; The Role of The Vacuum Field; Acknowledgments; References; SECTION II: UNCERTAINTY PRINCIPLE AND MEASUREMENT IN QUANTUM MECHANICS; Chapter 4 Reformulating The Quantum Uncertainty Relation; Abstract; Introduction; Results; Discussion; Methods; References Chapter 5 Investigating and Improving Student Understanding of Quantum Mechanical Observables and Their Corresponding Operators In Dirac NotationAbstract; Introduction; Summary of Dirac Notation Formalism; Methodology For The Investigation of Student Difficulties; Student Difficulties; Quilt Development; Evaluation of The Quilt; Summary; Acknowledgments; References; Chapter 6 Linguistic Interpretation Of Quantum Mechanics; Projection Postulate; Abstract; The Linguistic Interpretation of Quantum Mechanics; The Wave Function Collapse (I.e., The Projection Postulate); Conclusions; References Chapter 7 Measuring Incompatible Observables by Exploiting Sequential Weak ValuesAbstract; Acknowledgements; References; SECTION III: OBSERVABLES AND THE RELATIONSHIP BETWEEN CLASSICAL MECHANICS AND QUANTUM MECHANICS; Chapter 8 Quantum Mechanics as Classical Statistical Mechanics With an Ontic Extension and an Epistemic Restriction; Abstract; Introduction; Results; Discussion; Methods; Acknowledgements; References; Chapter 9 Classical and Quantum-Mechanical Axioms With The Higher Time Derivative Formalism; Abstract; Introduction; How To Complete The Quantum-Mechanical Description? Corrected Bell Inequalities In Random Gravity-Inertial FieldsConclusions; References; SECTION IV: SCHRODINGER EQUATION AND THE TUNNEL EFFECT; Chapter 10 Exact Solutions Of The Position-Dependent- Effective Mass Schrödinger Equation; Abstract; Introduction; Method; Some Physical Examples; Conclusion; Acknowledgement; References; Chapter 11 Operator of Time and Generalized Schrödinger Equation; Abstract; Introduction; Operators Of Time And Energy And Schrödinger Equations; Concluding Remarks; Acknowledgments; References
9781773616353
Quantum theory.
Electricity.
Electrical engineering.
Electronic Books.
QC174 / .B375 2019
Basic Quantum Mechanics for Electrical Engineering - Ashland : Arcler Press, (c)2019. - 1 online resource (311 pages)
Chapter 12 Beam Propagation Management In A Fractional Schrödinger Equation
Includes bibliographies and index.
Cover; Half Title Page; Title Page; Copyright Page; Declaration; About the Editor; Table of Contents; List of Contributors; List of Abbreviations; Preface; SECTION I: BLACKBODY RADIATION, THE PHOTONS AND THE ELECTRONS; Chapter 1 Exact Research on the Theory of the Blackbody Thermal Radiation; Abstract; Introduction; Results; Discussion; References; Chapter 2 Describing Compton Scattering And Two-Quantum Positron Annihilation Based On Compton Profiles: Two Models Suited For The Monte Carlo Method; Abstract; Introduction; Modelling of Compton Scattering Modelling of Two-Quanta e+ e- AnnihilationConclusions; Acknowledgments; References; Chapter 3 Momentum Exchange In The Electron Double-Slit Experiment; Abstract; Introduction; Momentum Conservation in Double Slit Diffraction; Momentum Exchange Mechanisms; On The Possibility of Trajectory Explanations; The Role of The Vacuum Field; Acknowledgments; References; SECTION II: UNCERTAINTY PRINCIPLE AND MEASUREMENT IN QUANTUM MECHANICS; Chapter 4 Reformulating The Quantum Uncertainty Relation; Abstract; Introduction; Results; Discussion; Methods; References Chapter 5 Investigating and Improving Student Understanding of Quantum Mechanical Observables and Their Corresponding Operators In Dirac NotationAbstract; Introduction; Summary of Dirac Notation Formalism; Methodology For The Investigation of Student Difficulties; Student Difficulties; Quilt Development; Evaluation of The Quilt; Summary; Acknowledgments; References; Chapter 6 Linguistic Interpretation Of Quantum Mechanics; Projection Postulate; Abstract; The Linguistic Interpretation of Quantum Mechanics; The Wave Function Collapse (I.e., The Projection Postulate); Conclusions; References Chapter 7 Measuring Incompatible Observables by Exploiting Sequential Weak ValuesAbstract; Acknowledgements; References; SECTION III: OBSERVABLES AND THE RELATIONSHIP BETWEEN CLASSICAL MECHANICS AND QUANTUM MECHANICS; Chapter 8 Quantum Mechanics as Classical Statistical Mechanics With an Ontic Extension and an Epistemic Restriction; Abstract; Introduction; Results; Discussion; Methods; Acknowledgements; References; Chapter 9 Classical and Quantum-Mechanical Axioms With The Higher Time Derivative Formalism; Abstract; Introduction; How To Complete The Quantum-Mechanical Description? Corrected Bell Inequalities In Random Gravity-Inertial FieldsConclusions; References; SECTION IV: SCHRODINGER EQUATION AND THE TUNNEL EFFECT; Chapter 10 Exact Solutions Of The Position-Dependent- Effective Mass Schrödinger Equation; Abstract; Introduction; Method; Some Physical Examples; Conclusion; Acknowledgement; References; Chapter 11 Operator of Time and Generalized Schrödinger Equation; Abstract; Introduction; Operators Of Time And Energy And Schrödinger Equations; Concluding Remarks; Acknowledgments; References
9781773616353
Quantum theory.
Electricity.
Electrical engineering.
Electronic Books.
QC174 / .B375 2019