boltz.inp

pic 模拟程序！面向对象

boltz.inp
{
demonstration of hybrid Boltzmann solver
}
Variables
{
   L = 0.1 // length in m
   R = 0.1 // outer radius in m
   I = 0.001 // current in A
   p = 0.1 // pressure in Torr
   n0 = 3e12 // initial density
   dt = 1e-10 // timestep in sec
   np2c = 1e5 // physical/computer particle ratio
}
Region
{
Species
{
	name = electrons
	m = 9.11E-31
	q = -1.6E-19
	collisionModel=electron
}
Species
{
   name = argon
   m = 6.67e-26
   q = 1.6E-19
	collisionModel=ion
}
Grid
{
	J = 64
	x1s = 0.0
	x1f = L
	n1 = 1.0
	K = 64
	x2s = 0.0
	x2f = R
	n2 = 1.0
}
Control
{
	dt = dt
	ElectrostaticFlag = 4
	BoltzmannFlag = 1
	BoltzmannTemp = 1
	BoltzmannDensity = n0
	BoltzmannCharge = -1
	BoltzmannChargeRatio = 1
	BoltzSpecies = electrons
	BoltzmannEBFlag = 0
}
MCC
{
	gas = Ar
	pressure = p   
	eSpecies = electrons
	iSpecies = argon
}
Conductor
{
	A1 = L
	A2 = 0
	B1 = L
	B2 = R
	name = Cathode
	normal = -1
	Secondary
	{
		secondary = 0.2
		secSpecies = electrons
		iSpecies = argon
	}
}
Equipotential
{
	C = 0.0
	phase = 0
	A1 = 0
	A2 = 0
	B1 = 0
	B2 = R
	name = Anode
	normal = 1
	Secondary
	{
		secondary = 0.2
		secSpecies = electrons
		iSpecies = argon
	}
	nxbins=60
	nenergybins=60
	nthetabins = 30
	energy_min = 0
	energy_max = 200
}
Dielectric
{
	er = 1.0
	A1 = 0
	A2 = R
	B1 = L
	B2 = R
	name = OuterWall
	normal = -1
	Secondary
	{
		secondary = 0
		secSpecies = electrons
		iSpecies = argon
	}
}
CylindricalAxis
{
	A1 = 0
	A2 = 0
	B1 = L
	B2 = 0
	normal = 1
}
//Load
//{
//	x1MinMKS = 0
//	x1MaxMKS = L
//	x2MinMKS = 0
//	x2MaxMKS = R
//	speciesName = electrons
//	density = n0
//	np2c = np2c
//	LoadMethodFlag =1
//  units = EV
//	temperature = 4
//}
Load
{
	x1MinMKS = 0
	x1MaxMKS = L
	x2MinMKS = 0
	x2MaxMKS = R
	speciesName = argon
	density = n0
	np2c = np2c
	LoadMethodFlag=1
   units = EV
	temperature = 0.025
}
}