Difference between revisions of "Nuclear Magnetic Resonance"

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(Basic Theory)
 
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The magnetic moment of a nucleon is sometimes expressed in terms of its g-factor (a dimensionless scalar) as <math>\mu=\frac{g\mu_{_N}}{\hbar}I</math>, where <math>\mu</math> is an intrinsic magnetic moment, <math>\mu_{_N}</math> is the nuclear magneton and is given by <math>\mu_{_N}=\frac{e \hbar}{2 m}</math>, <math>g</math> is the nucleon's g-factor, <math>I</math> is the nucleon's spin angular momentum number and <math>m</math> is the nucleon's mass. The <math>^1H</math> Hydrogen/Proton Gyromagnetic Ratio, <math>\gamma_{_P}</math>, is equal to <math>\frac{g_{_P} \mu_{_N}}{\hbar}</math>.<br>
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The magnetic moment of a nucleon is sometimes expressed in terms of its g-factor (a dimensionless scalar) as <math>\mu=\tfrac{g\mu_{_N}}{\hbar}I</math>, where <math>\mu</math> is an intrinsic magnetic moment, <math>\mu_{_N}</math> is the nuclear magneton and is given by <math>\mu_{_N}=\tfrac{e \hbar}{2 m}</math>, <math>g</math> is the nucleon's g-factor, <math>I</math> is the nucleon's spin angular momentum number and <math>m</math> is the nucleon's mass. The <math>^1H</math> Hydrogen/Proton Gyromagnetic Ratio, <math>\gamma_{_P}</math>, is equal to <math>\tfrac{g_{_P} \mu_{_N}}{\hbar}</math>.<br>
  
 
<math>g_{_P}=5.585\; 694\; 702(17) </math> The proton's g-factor<br><br>
 
<math>g_{_P}=5.585\; 694\; 702(17) </math> The proton's g-factor<br><br>
 
<math>\frac{\mu_{_N}}{\hbar}= 7.622\; 593\; 285(47)\text{ MHZ/T}</math> <br>
 
<math>\frac{\mu_{_N}}{\hbar}= 7.622\; 593\; 285(47)\text{ MHZ/T}</math> <br>
  
So, <math>\gamma_{_P}=42.577\; 478\; 92(29)\text{MHz/T}</math>
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So, <math>\gamma_{_P}=42.577\; 478\; 92(29)\text{MHz/T}</math><br>
  
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Larmor Frequency: <math>\omega_{_0}=\gamma H_{_0}</math>
  
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Our magnet will produce fields up to ~ 0.7T. This allows for transverse field frequencies up to ~ 30MHz. We employ a bridged-tee detector (Waring - 1952) to observe the NMR signal.
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----
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===Basic Theory===
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(for more detailed explanations see ''Nuclear Magnetic Resonance - Andrew'')
  
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[[- The Resonance Condition]]
  
[[Media:Uo_advanced_projects_lab_NMR.mp4 | NMR Video]]
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[[- Spin-Lattice Relaxation Time]]
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[[- Spin-Spin Interactions]]
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[[- Saturation]]
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[[- Magnetic Susceptibilities]]
  
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[[- Conditions for Observation of NMR Absorption]]
  
Links and Info:
 
  
[[Media:A_Bridged_Tee_Detector_for_NMR_-_Waring.pdf | - A Bridged Tee Detector for MNR - Waring]]
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[[Media:Uo_advanced_projects_lab_NMR.mp4 | NMR Video]]
  
  
----
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Links and Info:
  
Our magnet will produce fields up to ~ 0.7T.
+
[[Media:A_Bridged_Tee_Detector_for_NMR_-_Waring.pdf | - A Bridged Tee Detector for NMR - Waring]]

Latest revision as of 18:41, 18 February 2019

Nuclear Magnetic Resonance Project

The magnetic moment of a nucleon is sometimes expressed in terms of its g-factor (a dimensionless scalar) as , where is an intrinsic magnetic moment, is the nuclear magneton and is given by , is the nucleon's g-factor, is the nucleon's spin angular momentum number and is the nucleon's mass. The Hydrogen/Proton Gyromagnetic Ratio, , is equal to .

The proton's g-factor


So,

Larmor Frequency:

Our magnet will produce fields up to ~ 0.7T. This allows for transverse field frequencies up to ~ 30MHz. We employ a bridged-tee detector (Waring - 1952) to observe the NMR signal.


Basic Theory

(for more detailed explanations see Nuclear Magnetic Resonance - Andrew)

- The Resonance Condition

- Spin-Lattice Relaxation Time

- Spin-Spin Interactions

- Saturation

- Magnetic Susceptibilities

- Conditions for Observation of NMR Absorption


NMR Video


Links and Info:

- A Bridged Tee Detector for NMR - Waring