Difference: BoutisNmrCourse (1 vs. 3)

Revision 315 Dec 2011 - Main.MichaelGoger

 
META TOPICPARENT name="NmrEducation"
Contents

Changed:
<
<		Course Syllabus
CHEMISTRY 86905
Magnetic Resonance Spectroscopy
Spring 2011
>
>		Course Syllabus
CHEMISTRY 86905
Magnetic Resonance Spectroscopy
Spring or Fall 2013
 
Type Time Days Where Date Range
Changed:
<
<
Class 4:05 pm - 5:25 pm Tuesday and Thursday Graduate Center - 365 5th Ave Room 3306 Jan 28, 2011 - May 27, 2011
>
>
Class 4:05 pm - 5:25 pm Tuesday and Thursday Graduate Center - 365 5th Ave Room 3306  
 

Lecturer: G. S. Boutis Email: gboutis@brooklyn.cuny.edu Phone: (718)951-5000 x 2873

Description: This course will provide students of varying backgrounds, including physicists, material scientists, chemists, and biologists with an introduction to the physics of nuclear magnetic resonance. The course will supplement other already existing nuclear magnetic resonance courses offered at the graduate center and structural biology center.

Course requirements: A course in undergraduate quantum mechanics or physical chemistry should suffice.

Recommended Texts: C. P. Slichter “Principles of Magnetic Resonance” Springer-Verlag, 1996 J. Cavannagh “Protein NMR Spectroscopy: Principles and Practice” Academic Press, 1996 M. Levitt, “Spin Dynamics: Basics of Nuclear Magnetic Resonance” Wiley, 2001

Grading Homework Assignments: 100%

Course Outline

1. Introduction to Nuclear Magnetic Resonance

  1. Classical description, Bloch equations, relaxation, rotating frame, pulse and Fourier transform NMR, relaxation in the rotating frame
  2. Some simple pulse experiments (T1 and T2 experiments, the Hahn Echo)
  3. NMR spectroscopy
2. The NMR spectrometer
  1. The Magnet
  2. The probe
  3. The transmitter components
  4. The receiver components
3. Quantum Mechanics of NMR & the density matrix
  1. Review of quantum mechanics
  2. Angular momentum, spin ½
  3. The Schrödinger description
  4. The density matrix for spin ½
  5. The Von Neumann Equation
  6. Exponential operators
  7. Quantum mechanical description of pulses
  8. The product operator formalism
4. The internal Hamiltonians of NMR
  1. Zeeman interaction
  2. Dipole-Dipole Interactions
  3. Chemical shift
  4. Indirect nuclear-nuclear interactions
  5. The Quadrupolar Interaction
5. Spin ½ - the case of uncoupled spins
  1. Single spin dynamics
  2. Ensemble of spins
  3. Experiments on non-interacting spins
6. Spin ½ - coupled spin ½ systems
  1. Homonuclear A-X spin systems
  2. Mutiple quantum coherence
  3. Experiments on A-X spin systems: COSY, INEPT, INADEQUATE,
  4. Multiple spin ½ systems: Quantum coherence, TOCSY
  5. Exponential Approximations, Multiple pulse NMR and Average Hamiltonian Theory
  6. Pulsed decoupling
  7. Magic Angle Spinning
7. Motion and Relaxation in NMR
  1. Types of Relaxation
  2. Random Field Relaxation, BPP theory
  3. Motion: Processes, timescales and effects
  4. Dipole Dipole Relaxation
  5. NOESY, ROESY, Cross Correlated Relaxation
8. The generalized k-space formalism for describing:
  1. Imaging & Diffusion
  2. Multiple quantum coherence pathway selection

  • Set ALLOWTOPICVIEW =

-- MichaelGoger - 20 Dec 2010

Added:
>
>

Revision 207 Feb 2011 - Main.MichaelGoger

 
META TOPICPARENT name="NmrEducation"
Contents

Course Syllabus
CHEMISTRY 86905
Magnetic Resonance Spectroscopy
Spring 2011

Added:
>
>
Type Time Days Where Date Range
Class 4:05 pm - 5:25 pm Tuesday and Thursday Graduate Center - 365 5th Ave Room 3306 Jan 28, 2011 - May 27, 2011
 

Lecturer: G. S. Boutis Email: gboutis@brooklyn.cuny.edu Phone: (718)951-5000 x 2873

Description: This course will provide students of varying backgrounds, including physicists, material scientists, chemists, and biologists with an introduction to the physics of nuclear magnetic resonance. The course will supplement other already existing nuclear magnetic resonance courses offered at the graduate center and structural biology center.

Course requirements: A course in undergraduate quantum mechanics or physical chemistry should suffice.

Recommended Texts: C. P. Slichter “Principles of Magnetic Resonance” Springer-Verlag, 1996 J. Cavannagh “Protein NMR Spectroscopy: Principles and Practice” Academic Press, 1996 M. Levitt, “Spin Dynamics: Basics of Nuclear Magnetic Resonance” Wiley, 2001

Grading Homework Assignments: 100%

Course Outline

1. Introduction to Nuclear Magnetic Resonance

  1. Classical description, Bloch equations, relaxation, rotating frame, pulse and Fourier transform NMR, relaxation in the rotating frame
  2. Some simple pulse experiments (T1 and T2 experiments, the Hahn Echo)
  3. NMR spectroscopy
2. The NMR spectrometer
  1. The Magnet
  2. The probe
  3. The transmitter components
  4. The receiver components
3. Quantum Mechanics of NMR & the density matrix
  1. Review of quantum mechanics
  2. Angular momentum, spin ½
  3. The Schrödinger description
  4. The density matrix for spin ½
  5. The Von Neumann Equation
  6. Exponential operators
  7. Quantum mechanical description of pulses
  8. The product operator formalism
4. The internal Hamiltonians of NMR
  1. Zeeman interaction
  2. Dipole-Dipole Interactions
  3. Chemical shift
  4. Indirect nuclear-nuclear interactions
  5. The Quadrupolar Interaction
5. Spin ½ - the case of uncoupled spins
  1. Single spin dynamics
  2. Ensemble of spins
  3. Experiments on non-interacting spins
6. Spin ½ - coupled spin ½ systems
  1. Homonuclear A-X spin systems
  2. Mutiple quantum coherence
  3. Experiments on A-X spin systems: COSY, INEPT, INADEQUATE,
  4. Multiple spin ½ systems: Quantum coherence, TOCSY
  5. Exponential Approximations, Multiple pulse NMR and Average Hamiltonian Theory
  6. Pulsed decoupling
  7. Magic Angle Spinning
7. Motion and Relaxation in NMR
  1. Types of Relaxation
  2. Random Field Relaxation, BPP theory
  3. Motion: Processes, timescales and effects
  4. Dipole Dipole Relaxation
  5. NOESY, ROESY, Cross Correlated Relaxation
8. The generalized k-space formalism for describing:
  1. Imaging & Diffusion
  2. Multiple quantum coherence pathway selection

  • Set ALLOWTOPICVIEW =

-- MichaelGoger - 20 Dec 2010

Revision 120 Dec 2010 - Main.MichaelGoger

 
META TOPICPARENT name="NmrEducation"
Contents

Course Syllabus
CHEMISTRY 86905
Magnetic Resonance Spectroscopy
Spring 2011

Lecturer: G. S. Boutis Email: gboutis@brooklyn.cuny.edu Phone: (718)951-5000 x 2873

Description: This course will provide students of varying backgrounds, including physicists, material scientists, chemists, and biologists with an introduction to the physics of nuclear magnetic resonance. The course will supplement other already existing nuclear magnetic resonance courses offered at the graduate center and structural biology center.

Course requirements: A course in undergraduate quantum mechanics or physical chemistry should suffice.

Recommended Texts: C. P. Slichter “Principles of Magnetic Resonance” Springer-Verlag, 1996 J. Cavannagh “Protein NMR Spectroscopy: Principles and Practice” Academic Press, 1996 M. Levitt, “Spin Dynamics: Basics of Nuclear Magnetic Resonance” Wiley, 2001

Grading Homework Assignments: 100%

Course Outline

1. Introduction to Nuclear Magnetic Resonance

  1. Classical description, Bloch equations, relaxation, rotating frame, pulse and Fourier transform NMR, relaxation in the rotating frame
  2. Some simple pulse experiments (T1 and T2 experiments, the Hahn Echo)
  3. NMR spectroscopy
2. The NMR spectrometer
  1. The Magnet
  2. The probe
  3. The transmitter components
  4. The receiver components
3. Quantum Mechanics of NMR & the density matrix
  1. Review of quantum mechanics
  2. Angular momentum, spin ½
  3. The Schrödinger description
  4. The density matrix for spin ½
  5. The Von Neumann Equation
  6. Exponential operators
  7. Quantum mechanical description of pulses
  8. The product operator formalism
4. The internal Hamiltonians of NMR
  1. Zeeman interaction
  2. Dipole-Dipole Interactions
  3. Chemical shift
  4. Indirect nuclear-nuclear interactions
  5. The Quadrupolar Interaction
5. Spin ½ - the case of uncoupled spins
  1. Single spin dynamics
  2. Ensemble of spins
  3. Experiments on non-interacting spins
6. Spin ½ - coupled spin ½ systems
  1. Homonuclear A-X spin systems
  2. Mutiple quantum coherence
  3. Experiments on A-X spin systems: COSY, INEPT, INADEQUATE,
  4. Multiple spin ½ systems: Quantum coherence, TOCSY
  5. Exponential Approximations, Multiple pulse NMR and Average Hamiltonian Theory
  6. Pulsed decoupling
  7. Magic Angle Spinning
7. Motion and Relaxation in NMR
  1. Types of Relaxation
  2. Random Field Relaxation, BPP theory
  3. Motion: Processes, timescales and effects
  4. Dipole Dipole Relaxation
  5. NOESY, ROESY, Cross Correlated Relaxation
8. The generalized k-space formalism for describing:
  1. Imaging & Diffusion
  2. Multiple quantum coherence pathway selection

  • Set ALLOWTOPICVIEW =

-- MichaelGoger - 20 Dec 2010

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