h2. Dynamics
{latex}
$s(t)=e^{-t/T_{2}}\int P(r)e^{-i\int^{t}_{0}\omega(r,t')dt'}dr$
{latex}
\\
ω(r,t') = resonant frequency
P(r) = probability distribution
* Coherent - when ω is not a function of r (There are no interesting dynamics)
* Stationary - when ω is not a function of time (the system can be refocused by a π pulse for any time)
* Incoherent - stationary and not coherent, explicitly ω is a function of r (interesting question is the distribution of ω(r)
* Decoherent - when ω is a function of time and r, and the t dependence is stochastic/Marchovian (interesting dynamics: distribution of ω(r), spectral density of ω(r)
* Periodic - ω is a simple function of time (interesting dynamics: distribution of ω(r) at the characteristic frequency)
Periodic
<PIC>
Frequency that an arbitrary location will see
\\
{latex}
$\omega(t) = \gamma r \frac{\partial B_{z}}{\partial x} cos(\omega _{s} t + \phi)$
{latex}
\\
{latex}
$exp(i\int^{t}_{0}\omega(t')dt'=exp(i[\gamma \frac{\partial B_{z}/\partial x}{\omega_{s}}r sin(\omega_{s}t+\phi])$
{latex}
\\
{latex}
$exp^{iRsin\alpha}=\sum J_{k}(R)e^{ik\alpha}$
{latex}
for one location in the sample
\\
h4. Problem 1
- Show that for average over φ, we get absorptive line-shape, and for isochromat, φ in general has dispersive line-shape. Show the response in cylindrical coordinate ??
- Normal shim (x,y). If terms x^2-y^2, xy, then the sideband show up at twice Ω
- Calculate the FID and the spectrum, then plot them on top of each other
Nuclear Spin
- Zeeman interaction
- Chemical shift : ppm variation due to chemistry \-> transform as a tensor (orientation of the molecule matter)
{latex}$H_{z}=\omega _{0}I_{z}${latex} , {latex}$H_{cs}=-\omega _{0}\sigma I_{z}${latex}
<PIC>
PAS (Principle axis system) = coordinate system that leave the molecule in diagonal ??
<MATRIX>
{latex}$\sigma _{z} \sigma _{z}${latex}
= secular part of the chemical shift, lead to small rotation in x-y direction
<PIC>
h4. Problem 2
- Show that
{latex}
$\sigma = \sigma_{iso} + (\frac{\sigma}{2})(3 cos^{2}\theta -1)- \frac{\delta^{eta}}{4}sin^{2}\theta(e^{i2\phi}+e^{-i2\phi})$
{latex}
\\
{latex}
$\sigma_{iso}=(\sigma_{xx}+\sigma_{yy}+\sigma_{zz})/3$
{latex}
\\
{latex}
$\delta=\frac{2}{3}\sigma_{zz}-\frac{1}{3}(\sigma_{xx}+\sigma_{yy})$
{latex}
\\
{latex}
$\eta=3(\sigma_{yy}-\sigma_{xx})/2(\sigma_{zz}-\sigma_{xx}-\sigma_{yy})$
{latex}
\\
- Under random rapid motion spins
{latex}$< \sigma > = \sigma _{iso}${latex}
- When η = 0 \-> < 3cos(θ)^2 \-1 > = 0, average over sphere
- η = 0 ; calculate the line-shape for static powder, η ≠ 0 ; reduce to a summation over η
- Find σ(θ,φ), powder distribution of the sample
<PIC>
Decoherence
Bloc = field that a test spin would see (every spin averagely see the same distribution of B)
<PIC>
average vector still pointing along y => \|Bloc> of time or ensemble = 0
<EQUATIONS>
h4. Problem 3
- Find the correlation time
Carl-Purcell Sequence
<PIC>
<EQ>
h4. Problem 4
- Look at diffusive attenuation of water rotate in magnetic field gradient. (The faster you rotate it, you get closer to having the real T2 effect
- Is the underly process is truly stochastic
Chemical Exchange
let <EQ>
<PIC>
h4. Problem 5
- Show plot
Slow Exchange
<PIC>
h4. Problem 6
<EQ>
- Show that by collect this terms
<EQ>
then do phase cycle and collect data set
<EQ>
Then we get pure absorptive line-shape |