لﺒﺎﺒ: ﺔﻌﻤﺎﺠﻝﺍ ﻕﺍﺮﻌﻟﺍ ﺔﻳﺭﻮﻬﲨ · 2013. 10. 7. · the...
TRANSCRIPT
))أ� ��رة ا���� ا� �ر��� ا������ ((
الاسم ���ء ��� ���� ر��
[email protected] البريد الالكتروني
اسم المادة!��ء � زم�"
مقرر الفصل ���ي
اهداف المادة
1- Definition the plasma. 2- To Classify of plasmas 3- Understanding classical electrodynamics . 4- Knowing Basic Plasma Characteristics. 5- Knowing the electron plasma frequency 6- Studying the Debye length 7- Studying Electrostatic plasma waves 8- Description Coulomb collisions 9- Understanding Motion of a Charged Particle in Magnetic Fields 10- Studying constant uniform magnetic field with non-magnetic forces 11- Studying guiding center motion in nonuniform magnetic fields 12- Description of cold Plasma 13- Description waves in a cold unmagnetized plasma 14- Description the dielectric tensor for a cold magnetized plasma 15- Studying waves in a cold magnetized plasma 16- Description Magnetohydrodynamic of Plasma 17- Knowing the MHD equations 18- Knowing General properties of the ideal MHD description 19- Knowing MHD equilibrium 20- Knowing MHD waves 21- Knowing MHD stability and 22- Knowing MHD shocks 23- Different between MHD waves and MHD shocks 24- Studying the Vlasov equation 25- Description connections to fluid theories 26- Understanding Vlasov theory of electrostatic plasma waves 27- Studying Landau damping 28- Studying the Fokker-Planck equation 29- Understanding binary Coulomb collisions
جمهورية العراق�وزא���א����� �א������وא���א����� �
����ز�א���א��وא����� �א����� �
� �
� �
� �
بابل :الجامعة التربية للعلوم الصرفة :الكلية
الفيزياء:القســم الثالثة :المرحلة
بهاء حسين صالح ربيع :اسم المحاضر الثلاثي استاذ :اللقب العلمي
دكتوراه :المؤهل العلمي معاون العميد للشؤون العلمية :مكان العمل والدراسات
التفاصيل الاساسية للمادة
Plasma physics is an important subject for a large number of research areas including space physics, astrophysics, controlled fusion research, high-power laser physics, plasma processing, accelerator physics, and many areas of experimental physics. The primary goal of this course is to present the basic principles and main equations of plasma physics at an introductory level, with emphasis on topics of broad applicability.
A plasma may be generally defined as any statistical collection of mobile charged particles. Thus statistical physics and electrodynamics provide the fundamental basis for the physics of plasmas. An undergraduate course in classical electrodynamics (such as PHYS 302) is the only prerequisite for the course; relevant aspects of statistical physics and mechanics are reviewed or introduced as needed.
The required text for the course is "Plasma Dynamics" by R. O. Dendy. This book is chosen because it contains a nice balance between mathematical formulations and physical principles, it is clearly written, and it uses an appealing logical organization of the subject which provides an excellent framework for a first course in plasma physics. The well-known text "Introduction to Plasma Physics and Controlled Fusion" by F. F. Chen is a recommended text for the course, and in many ways it complements and reinforces material covered in Dendy's book.
The course begins with a description of various types of plasmas and a discussion of some basic plasma parameters, such as the Debye length and the plasma frequency. Following a discussion of charged particle motion in electromagnetic fields, progressively more detailed models of plasmas are presented, starting with a dielectric description of cold plasma and moving on to the magnetohydrodynamic and kinetic descriptions. Additional topics may be added as time allows. Students are required to give a presentation to the class on a plasma physics topic related to the course.
Plasma physics is an important subject for a large number of research areas including space physics, astrophysics, controlled fusion research, high-power laser physics, plasma processing, accelerator physics, and many areas of experimental physics. The primary goal of this course is to present the basic principles and main equations of plasma physics at an introductory level, with emphasis on topics of broad applicability.
A plasma may be generally defined as any statistical collection of mobile charged particles. Thus statistical physics and electrodynamics provide the fundamental basis for the physics of plasmas. An undergraduate course in classical electrodynamics (such
as PHYS 302) is the only prerequisite for the course; relevant aspects of statistical physics and mechanics are reviewed or introduced as needed.
The required text for the course is "Plasma Dynamics" by R. O. Dendy. This book is chosen because it contains a nice balance between mathematical formulations and physical principles, it is clearly written, and it uses an appealing logical organization of the subject which provides an excellent framework for a first course in plasma physics. The well-known text "Introduction to Plasma Physics and Controlled Fusion" by F. F. Chen is a recommended text for the course, and in many ways it complements and reinforces material covered in Dendy's book.
The course begins with a description of various types of plasmas and a discussion of some basic plasma parameters, such as the Debye length and the plasma frequency. Following a discussion of charged particle motion in electromagnetic fields, progressively more detailed models of plasmas are presented, starting with a dielectric description of cold plasma and moving on to the magnetohydrodynamic and kinetic descriptions. Additional topics may be added as time allows. Students are required to give a presentation to the class on a plasma physics topic related to the course.
الكتب المنهجية
�ء ا���ز�� �� � � ���� رب�� . ����� د//ا�����ت ���ب��ء
Chen, F. F. Introduction to Plasma Physics. 2nd ed. New York, NY:
Springer, 1984. ISBN: 9780306413322.
See also:
المصادر الخارجية
Shohet, J. L. The Plasma State. San Diego, CA: Academic Press Inc.,
1971. ISBN: 9780126405507.
Tanenbaum, B. S. Plasma Physics. New York, NY: McGraw-Hill, 1967. ISBN: 9780070628120.
Intermediate:
Hazeltine, R. D., and F. L. Waelbroeck. The Framework of Plasma
Physics. Boulder, CO: Westview Press, 2004. ISBN: 9780813342139.
Goldston, R. J., and P. H. Rutherford. Introduction to Plasma
Physics. Philadelphia, PA: IOP Publishing, 1995. ISBN: 9780750301831.
See also:
Clemmow, P. C., and J. P. Dougherty. Electrodynamics of Particles and Plasmas. New York, NY: Perseus Books, 1989. ISBN: 9780201515008.
Spitzer, Lyman, Jr. Physics of Fully Ionized Gases. 2nd ed. Hoboken, NJ: Wiley, 1962.
Schmidt, G. Physics of High Temperature Plasmas. 2nd ed. San Diego, CA: Academic Press, 1979. ISBN: 9780126266603.
(Recommended for theory of particle orbits.)
Boyd, T. J. M., and J. J. Sanderson. Plasma Dynamics. New York,
NY: Barnes and Noble, 1969. (Recommended for the statistical mechanics description of plasmas.)
Dendy, R., ed. Plasma Physics. Cambridge, UK: Cambridge University Press, 1995. ISBN: 9780521484527. (Recommended for specific chapters on space and plasmas and on industrial plasmas.)
Advanced:
Krall, N. A., and A. W. Trivelpiece. Principles of Plasma Physics. Berkeley, CA: San Francisco Press, 1986. ISBN: 9780911302585.
See also:
Ichimaru, S. Principles of Plasma Physics - A Statistical Approach.
Boston, MA: Addison Wesley Publishing Company, 1973. ISBN: 9780805387520.
MHD
J. P. Freidberg. Ideal Magnetohydrodynamics. New York, NY: Springer, 1987. ISBN: 9780306425127.
Plasma Waves
Stix, T. H. Waves in Plasmas. New York, NY: Springer, 1992. ISBN:
9780883188590.
Plasma Diagnostics
Huddlestone, R. H., and S. L. Leonard. Plasma Diagnostic
Techniques. San Diego, CA: Academic Press, 1965.
Hutchinson, I. H. Principles of Plasma Diagnostics. Cambridge, UK: Cambridge University Press, 2005. ISBN: 9780521675741.
Magnetic Confinement Fusion
Rose, D. J., and M. Clark, Jr. Plasmas and Controlled Fusion.
Cambridge, MA: MIT Press, 1961. ISBN: 9780262180061.
Miyamoto, K. Plasma Physics for Nuclear Fusion. Cambridge, MA:
MIT Press, 1989. ISBN: 9780262631174.
Wesson, J. Tokamaks. 3rd ed. Oxford, UK: Oxford University Press,
2004. ISBN: 9780198509226.
Plasma Astrophysics
Tajima, T., and K. Shibata. Plasma Astrophysics. Boulder, CO:
Westview Press, 2002. ISBN: 9780813339962.
الامتحانات المختبر الفصل الدراسي
اليومية
الامتحان النهائي المشروع تقديرات الفصل
%٤٠مثلاً - %١٠مثلاً %١٥مثلا %٣٥مثلاً
معلومات اضافية
جدول الدروس
الاسبوعي
�ع��ا�
ا �����ت ا ��دة ا ����� ا ��دة ا ���� ا ��ر�
١ 1. Introduction
٢ o Definition of a plasma
٣ o Classification of plasmas, the n-T diagram
٤ 1. A brief review of classical electrodynamics
٥ DPF and TOKOMAK
٦ vector calculus
٧ 2. Basic Plasma Characteristics
٨ 1. The electron plasma frequency
٩ o The Debye length
١٠ o Electrostatic plasma waves
١١ o Coulomb
جمهورية العراق�وزא���א����� �א������وא���א����� �
����ز�א���א��وא����� �א����� �
� �
� �
� �
ابل ب: الجامعة التربية للعلوم الصرفة :الكلية
الفيزياء :القســم المرحلة الثالثة :المرحلة
بهاء حسين صالح ربيع :اسم المحاضر الثلاثي استاذ :اللقب العلمي
دكتوراه :المؤهل العلمي معاون العميد للشؤون العلمية :مكان العمل والدراسات
collisions
١٢ o Motion of a Charged Particle in Magnetic Fields
١٣ o Constant uniform magnetic field
١٤ o Constant uniform magnetic field with non-magnetic forces
١٥ o ر�١-أ���-
١٦ �1�2 ن/. ا����
١٧ o Guiding center motion in nonuniform magnetic fields
١٨ 1. Dielectric Description of Cold Plasma
١٩ o General properties
٢٠ o Waves in a cold unmagnetized plasma
٢١ o The dielectric tensor for a cold magnetized plasma
٢٢ Waves in a cold magnetized plasma
٢٣ 1. Magnetohydrodynamic Description of Plasma
٢٤ o The MHD
equations
٢٥ o General
properties of the ideal MHD description
٢٦ o MHD equilibrium
٢٧ MHD waves ٢٨ o MHD stability
٢٩ MHD shocks ٣٠ 1. Kinetic Description of
Plasma
٣١ The Vlasov equation ا��7ن6 5خ �3را ٣٢
���ء ��� ���� ر�� :ا;� �ذت�8� � :ت�8� ا�=�
Course Weekly Outline
Course Instructor Bahaa Hussien Salih Rabee E_mail [email protected]
Title Plasma Physics Course Coordinator Yearly Course Objective
30- Definition the plasma. 31- To Classify of plasmas 32- Understanding classical electrodynamics . 33- Knowing Basic Plasma Characteristics. 34- Knowing the electron plasma frequency 35- Studying the Debye length 36- Studying Electrostatic plasma waves 37- Description Coulomb collisions 38- Understanding Motion of a Charged Particle in Magnetic Fields 39- Studying constant uniform magnetic field with non-magnetic forces 40- Studying guiding center motion in nonuniform magnetic fields 41- Description of cold Plasma 42- Description waves in a cold unmagnetized plasma 43- Description the dielectric tensor for a cold magnetized plasma 44- Studying waves in a cold magnetized plasma 45- Description Magnetohydrodynamic of Plasma 46- Knowing the MHD equations 47- Knowing General properties of the ideal MHD description 48- Knowing MHD equilibrium 49- Knowing MHD waves 50- Knowing MHD stability and 51- Knowing MHD shocks 52- Different between MHD waves and MHD shocks 53- Studying the Vlasov equation 54- Description connections to fluid theories 55- Understanding Vlasov theory of electrostatic plasma waves 56- Studying Landau damping 57- Studying the Fokker-Planck equation 58- Understanding binary Coulomb collisions
University: College: Department: Stage: Lecturer name: Bahaa Hussien Salih Rabee Academic Status: Qualification: Place of work:
� �
Republic of Iraq The Ministry of Higher Education & Scientific Research
Course Description
Plasma physics is an important subject for a large number of research areas including space physics, astrophysics, controlled fusion research, high-power laser physics, plasma processing, accelerator physics, and many areas of experimental physics. The primary goal of this course is to present the basic principles and main equations of plasma physics at an introductory level, with emphasis on topics of broad applicability.
A plasma may be generally defined as any statistical collection of mobile charged particles. Thus statistical physics and electrodynamics provide the fundamental basis for the physics of plasmas. An undergraduate course in classical electrodynamics (such as PHYS 302) is the only prerequisite for the course; relevant aspects of statistical physics and mechanics are reviewed or introduced as needed.
The required text for the course is "Plasma Dynamics" by R. O. Dendy. This book is chosen because it contains a nice balance between mathematical formulations and physical principles, it is clearly written, and it uses an appealing logical organization of the subject which provides an excellent framework for a first course in plasma physics. The well-known text "Introduction to Plasma Physics and Controlled Fusion" by F. F. Chen is a recommended text for the course, and in many ways it complements and reinforces material covered in Dendy's book.
The course begins with a description of various types of plasmas and a discussion of some basic plasma parameters, such as the Debye length and the plasma frequency. Following a discussion of charged particle motion in electromagnetic fields, progressively more detailed models of plasmas are presented, starting with a dielectric description of cold plasma and moving on to the magnetohydrodynamic and kinetic descriptions. Additional topics may be added as time allows. Students are required to give a presentation to the class on a plasma physics topic related to the course.
Plasma physics is an important subject for a large number of research areas including space physics, astrophysics, controlled fusion research, high-power laser physics, plasma processing, accelerator physics, and many areas of experimental physics. The primary goal of this course is to present the basic principles and main equations of plasma physics at an introductory level, with emphasis on topics of broad applicability.
A plasma may be generally defined as any statistical collection of mobile charged particles. Thus statistical physics and electrodynamics provide the fundamental basis for the physics of plasmas. An undergraduate course in classical electrodynamics (such as PHYS 302) is the only prerequisite for the course; relevant aspects of statistical physics and mechanics are reviewed or introduced as needed.
The required text for the course is "Plasma Dynamics" by R. O. Dendy. This book is chosen because it contains a nice balance between mathematical formulations and physical principles, it is clearly written, and it uses an appealing logical organization of the subject which provides an excellent framework for a first course in plasma physics. The well-known text "Introduction to Plasma Physics and Controlled Fusion" by F. F. Chen is a recommended text for the course, and in many ways it complements and reinforces material covered in Dendy's book.
The course begins with a description of various types of plasmas and a discussion of some basic plasma parameters, such as the Debye length and the plasma frequency. Following a discussion of charged particle motion in electromagnetic fields, progressively more detailed models of plasmas are presented, starting with a dielectric description of cold plasma and moving on to the magnetohydrodynamic and kinetic descriptions. Additional topics may be added as time allows. Students are required to give a presentation to the class on a plasma physics topic related to the course.
Textbook
Fundamentals of Plasma Physics \\ Bahaa Hussien Salih Rabee
Chen, F. F. Introduction to Plasma Physics. 2nd ed. New York, NY:
Springer, 1984. ISBN: 9780306413322.
See also:
References
Shohet, J. L. The Plasma State. San Diego, CA: Academic Press Inc., 1971. ISBN: 9780126405507.
Tanenbaum, B. S. Plasma Physics. New York, NY: McGraw-Hill, 1967. ISBN: 9780070628120.
Intermediate:
Hazeltine, R. D., and F. L. Waelbroeck. The Framework of Plasma Physics. Boulder, CO: Westview Press, 2004. ISBN: 9780813342139.
Goldston, R. J., and P. H. Rutherford. Introduction to Plasma Physics. Philadelphia, PA: IOP Publishing, 1995. ISBN: 9780750301831.
See also:
Clemmow, P. C., and J. P. Dougherty. Electrodynamics of Particles and
Plasmas. New York, NY: Perseus Books, 1989. ISBN: 9780201515008.
Spitzer, Lyman, Jr. Physics of Fully Ionized Gases. 2nd ed. Hoboken, NJ: Wiley, 1962.
Schmidt, G. Physics of High Temperature Plasmas. 2nd ed. San Diego, CA: Academic Press, 1979. ISBN: 9780126266603. (Recommended for theory of particle orbits.)
Boyd, T. J. M., and J. J. Sanderson. Plasma Dynamics. New York, NY: Barnes and Noble, 1969. (Recommended for the statistical mechanics
description of plasmas.)
Dendy, R., ed. Plasma Physics. Cambridge, UK: Cambridge University
Press, 1995. ISBN: 9780521484527. (Recommended for specific chapters on space and plasmas and on industrial plasmas.)
Advanced:
Krall, N. A., and A. W. Trivelpiece. Principles of Plasma Physics.
Berkeley, CA: San Francisco Press, 1986. ISBN: 9780911302585.
See also:
Ichimaru, S. Principles of Plasma Physics - A Statistical Approach. Boston, MA: Addison Wesley Publishing Company, 1973. ISBN:
9780805387520.
MHD
J. P. Freidberg. Ideal Magnetohydrodynamics. New York, NY: Springer,
1987. ISBN: 9780306425127.
Plasma Waves
Stix, T. H. Waves in Plasmas. New York, NY: Springer, 1992. ISBN: 9780883188590.
Plasma Diagnostics
Huddlestone, R. H., and S. L. Leonard. Plasma Diagnostic Techniques.
San Diego, CA: Academic Press, 1965.
Hutchinson, I. H. Principles of Plasma Diagnostics. Cambridge, UK:
Cambridge University Press, 2005. ISBN: 9780521675741.
Magnetic Confinement Fusion
Rose, D. J., and M. Clark, Jr. Plasmas and Controlled Fusion. Cambridge, MA: MIT Press, 1961. ISBN: 9780262180061.
Miyamoto, K. Plasma Physics for Nuclear Fusion. Cambridge, MA: MIT Press, 1989. ISBN: 9780262631174.
Wesson, J. Tokamaks. 3rd ed. Oxford, UK: Oxford University Press, 2004. ISBN: 9780198509226.
Plasma Astrophysics
Tajima, T., and K. Shibata. Plasma Astrophysics. Boulder, CO: Westview
Press, 2002. ISBN: 9780813339962.
Term Tests Laboratory Quizzes Project Final Exam
Course Assessment As (35%) As (15%) As (10%) ---- As (40%)
General Notes
Type here general notes regarding the course
Course weekly Outline week Date Topics Covered Lab. Experiment
Assignments Notes
1 2. Introduction
2 o Definition of a plasma
3 o Classification of plasmas, the n-T diagram
4 3. A brief review of classical electrodynamics
5 DPF and TOKOMAK
6 vector calculus
7 4. Basic Plasma Characteristics
8 2. The electron plasma frequency
9 o The Debye length
10 o Electrostatic plasma waves
11 o Coulomb
University: College: Department: Stage: Lecturer name: Bahaa Hussien Salih Rabee Academic Status: Qualification:
Republic of Iraq The Ministry of Higher Education
& Scientific Research
collisions
12 o Motion of a Charged Particle in Magnetic Fields
13 o Constant uniform magnetic field
14 o Constant uniform magnetic field with non-magnetic forces
15
16 Half-year Break
17 o Guiding center motion in nonuniform magnetic fields
18 2. Dielectric Description of Cold Plasma
19 o General properties
20 o Waves in a cold unmagnetized plasma
21 o The dielectric tensor for a cold magnetized plasma
22 Waves in a cold magnetized plasma
23 2. Magnetohydrodynamic Description of Plasma
24 o The MHD
equations
25 o General properties of the ideal MHD description
26 o MHD equilibrium
27 MHD waves 28 o MHD stability
29 MHD shocks 30 2. Kinetic Description of
Plasma
31 The Vlasov equation 32
Instructor Signature: Dean Signature: Bahaa Hussien Salih Rabee