jaxrts.hnc_potentials.PauliClassicalMap

class jaxrts.hnc_potentials.PauliClassicalMap[source]

Calculates the Pauli potential from the exact non-interacting UEG pair distribution function by inverting the Hyper-Netted-Chain calculations:cite:DharmaWardana.2012.

Sets include_electrons to "SpinSeparated", automatically.

Methods

`T`(plasma_state)	The mass_weighted temperature average of a pair, according to [Schwarz et al., 2007].
`__init__`()	Sets `include_electrons` to `"SpinSeparated"`, automatically.
`alpha`(plasma_state)
`check`(plasma_state)	Test if the HNCPotential is applicable to the PlasmaState.
`citation`([style, comment])	Return bibliographic information for the Model used.
`full_k`(plasma_state, k)
`full_r`(plasma_state, r)
`lambda_ab`(plasma_state)
`long_k`(plasma_state, k)	The Foutier transform of `short_k()`.
`long_r`(plasma_state, r)	This is the long-range part of `full_r()`:
`mu`(plasma_state)	The geometric mean of two masses (or reciprocal sum)
`prepare`(plasma_state, key)
`q2`(plasma_state)	This is \(q^2\)!
`r_cut`(plasma_state)	This casts `jaxrts.PlasmaState.ion_core_radius` in the form required to be used with an :py:class:~.HNCPotential`.
`short_k`(plasma_state, k)	The Fourier transform of `short_r()`.
`short_r`(plasma_state, r)	This is the short-range part of `full_r()`:

Attributes

`allowed_keys`	A list of keys where this Potential is adequate for.
`cite_keys`	A list of bibtex keys.
`include_electrons`	If "SpinAveraged", the electrons are added as the n+1th ion species to the potential.