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Hamiltonian matrix spin-rotation coupling

The CN radical in its 21 ground state shows fine and hyperfine structure of the rotational levels which is more conventional than that of CO+, in that the largest interaction is the electron spin rotation coupling../ is once more a good quantum number, and the effective Hamiltonian is that given in equation (10.45), with the addition of the nuclear electric quadrupole term given in chapter 9. The matrix elements in the conventional hyperfine-coupled case (b) basis set were derived in detail in chapter 9,... [Pg.750]

A simple, non-selective pulse starts the experiment. This rotates the equilibrium z magnetization onto the v axis. Note that neither the equilibrium state nor the effect of the pulse depend on the dynamics or the details of the spin Hamiltonian (chemical shifts and coupling constants). The equilibrium density matrix is proportional to F. After the pulse the density matrix is therefore given by and it will evolve as in equation (B2.4.27). If (B2.4.28) is substituted into (B2.4.30), the NMR signal as a fimction of time t, is given by (B2.4.32). In this equation there is a distinction between the sum of the operators weighted by the equilibrium populations, F, from the unweighted sum, 7. The detector sees each spin (but not each coherence ) equally well. [Pg.2100]

In the present treatment, we retain essentially all the diagonal matrix elements of X these are the first-order contributions to the effective electronic Hamiltonian. There are many possible off-diagonal matrix elements but we shall consider only those due to the terms in Xrot and X o here since these are the largest and provide readily observable effects. The appropriate part of the rotational Hamiltonian is —2hcB(R)(NxLx + NyLy). The matrix elements of this operator are comparatively sparse because they are subject to the selection rules AA = 1, A,Y=0 and AF=0. The spin-orbit coupling term, on the other hand, has a much more extensive set of matrix elements allowed... [Pg.318]

Consider first the case of parallel fields. The lowest magnetically trappable state of CaD is N = 0,Mj = Q Ms = ). Electric fields couple this state with the rota-tionally excited state N = 1,Ma = 0,Ms = which is in turn coupled with the spin-down state N = l,Mj = l Ms = — ) via the spin-rotation interaction. The matrix representation of Hamiltonian 4.2 in the basis of the three states is... [Pg.147]

See other pages where Hamiltonian matrix spin-rotation coupling is mentioned: [Pg.509]    [Pg.89]    [Pg.617]    [Pg.608]    [Pg.793]    [Pg.2100]    [Pg.243]    [Pg.1449]    [Pg.617]    [Pg.608]    [Pg.793]    [Pg.92]    [Pg.167]    [Pg.485]    [Pg.593]    [Pg.619]    [Pg.318]    [Pg.3]    [Pg.626]    [Pg.593]    [Pg.619]    [Pg.66]    [Pg.414]    [Pg.864]   
See also in sourсe #XX -- [ Pg.68 , Pg.69 ]



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Coupling Hamiltonians

Hamiltonian coupling

Hamiltonian rotation

Hamiltonian rotational

Matrix spinning

Rotation matrix

Rotational couplings

Rotational matrix

Spin Hamiltonian

Spin Hamiltonian Hamiltonians

Spin Hamiltonian matrix

Spin matrices

Spin rotation

Spin-rotation coupling

Spin-rotational Hamiltonian

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