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Units

Units
Dimensionless units
Converting to SI units
- Example

Units

W-SLDA Toolkit uses natural units:

m=1 - mass of particle,
\hbar=1 - Plank's constant divide by 2\pi,
k_B=1 - Boltzmann constant,
dx=a - lattice spacing.

The lattice spacing is defined through predefines.h

#define DX 1.0

It is recommended to work with lattice spacing DX=1, however, the code allows to use of other values, in order to support the functionality of automatic interpolations.

Dimensionless units

When reporting values, it is convenient to use dimensionless units. See here for the definition of reference scales.

quantity	dimensionless units	interpretation
energy	`E/E_{\textrm{ffg}}`	In literature it is called (generalized) Bertsch parameter `\xi`.
distance	`xk_F`	Fermi momentum `k_F` defines the average distance between particles. Thus `xk_F=1` means a distance of the order of interparticle distance.
time	`t\varepsilon_F`	In time interval `t\varepsilon_F=1` particles at Fermi level pass distance of the order of average interparticle distance. In literature this time scale is also called interaction time scale, meaning typical time scale for scattering events.

Converting to SI units

To compare with experimental data typically one needs to convert results to SI units. In order to do this, one needs to provide SI standards for mass, length, and time.

standard	standard type	SI	code
mass	explicit: mass of particle	`m\,\left[\textrm{kg}\right]`	1
length	explicit: distance between two lattice points	`l\,\left[\textrm{m}\right]`	1 (*)
time	implicit: time units is defined through requirement that `\hbar=1`	`\left[\textrm{s}\right]`	1

(*) It is assumed that in predefines.h DX=1. If not, and DX=a, one needs to rescale l\rightarrow l/a.

Below we provide conversion factors:

qunatity	symbol	code value	SI value
wave-vector	`k`	1	`\frac{1}{l}\,\left[\frac{\textrm{1}}{\textrm{m}}\right]`
momentum	`p=\hbar k`	1	`\frac{\hbar}{l}\,\left[\frac{\textrm{kg m}}{\textrm{s}}\right]`
energy	`E=\frac{p^2}{2m}`	1	`\frac{\hbar^2}{ml^2}\,\left[J\right]`
velocity	`v=\frac{p}{m}`	1	`\frac{\hbar}{ml}\,\left[\frac{\textrm{m}}{\textrm{s}}\right]`
time	`t=\frac{l}{v}`	1	`\frac{ml^2}{\hbar}\,\left[\textrm{s}\right]`

Example

Consider gas of {}^{6}\textrm{Li}. Moreover, let us assume that lattice spacing is 0.1\,\mu\textrm{m}. Then we have

standard	value
`m`	`9.988\times 10^{-27}\,\textrm{kg}`
`l`	`0.1\,\mu\textrm{m}`
`\hbar`	`1.055\times 10^{-34}\,\textrm{J s}`
code value	SI value
`v=1`	`0.106\,\frac{\textrm{m}}{\textrm{s}}`
`t=1`	`0.947\,\mu\textrm{s}`