In particle physics, wave mechanics, and optics, momentum transfer is the amount of momentum that one particle gives to another particle. It is also called the scattering vector as it describes the transfer of wavevector in wave mechanics.
In the simplest example of scattering of two colliding particles with initial momenta
\vec{p}i1,\vec{p}i2
\vec{p}f1,\vec{p}f2
\vecq=\vec{p}i1-\vec{p}f1=\vec{p}f2-\vec{p}i2
\Deltax=\hbar/|q|
A wave has a momentum
p=\hbark
k=p/\hbar
k=2\pi/λ
Q=kf-ki
The momentum transfer plays an important role in the evaluation of neutron, X-ray, and electron diffraction for the investigation of condensed matter. Laue-Bragg diffraction occurs on the atomic crystal lattice, conserves the wave energy and thus is called elastic scattering, where the wave numbers final and incident particles,
kf
ki
G=Q=kf-ki
G=2\pi/d
The presentation in reciprocal space is generic and does not depend on the type of radiation and wavelength used but only on the sample system, which allows to compare results obtained from many different methods. Some established communities such as powder diffraction employ the diffraction angle
2\theta
\alpha
Q
Q=2k\sin\left(\theta\right)
with
k={2\pi}/{λ}
2\theta
Q