Calculating Particle Energy Loss in Gases: Where to Start?

md123
Messages
3
Reaction score
0
Hey guys,

Im currently looking for a way to calculate the energy loss of a particle in a gas. This will help me to understand deposition processes better. The particles I am looking at are heavy, uncharged ones (e.g. metal atoms). Stopping power is not a viable concept without charge, and Bethe Bloch seems to only work for higher energies (>0.5MeV), whereas the energies I am looking at are in the order of eV, or some few keV at most.
I can't find a good solution for my problem, maybe you can give me a hint where to start, a theory, a formula... anything? Id sure appreciate any form of help!

So long,
md
 
Physics news on Phys.org
Particles of the order of eV are nearly thermal, they will stop within some small multiple of the mean free path in the gas, where the prefactor depends on the mass ratio between stopped particle and the gas molecules (or atoms at higher energy).
At higher energies, chemical processes and ionization get possible, where I don't know how to describe that.
 
Since its Ar-gas, its monoatomic and perfectly inert, so i don't have to think about the distinction of molecular and atomic scattering or chemical processes. I guess i could just run a simulation using simple mechanics, scattering factors and angular distributions, and use random numbers to get a result...
 
Probably. Ionization will be a possible source of energy loss, so elastic collisions give an upper estimate on the distances and timescales involved.
 
Thanks for the input and encouragement. How do people say? "Aint nothing to in but to do it". I will try!
 

Thread 'Toponium Discovered'

Toponium is a hadron which is the bound state of a valance top quark and a valance antitop quark. Oversimplified presentations often state that top quarks don't form hadrons, because they decay to bottom quarks extremely rapidly after they are created, leaving no time to form a hadron. And, the vast majority of the time, this is true. But, the lifetime of a top quark is only an average lifetime. Sometimes it decays faster and sometimes it decays slower. In the highly improbable case that...
View full post »

Thread 'Dirac-Delta from Normalization of Continuous Eigenfunctions'

I'm following this paper by Kitaev on SL(2,R) representations and I'm having a problem in the normalization of the continuous eigenfunctions (eqs. (67)-(70)), which satisfy \langle f_s | f_{s'} \rangle = \int_{0}^{1} \frac{2}{(1-u)^2} f_s(u)^* f_{s'}(u) \, du. \tag{67} The singular contribution of the integral arises at the endpoint u=1 of the integral, and in the limit u \to 1, the function f_s(u) takes on the form f_s(u) \approx a_s (1-u)^{1/2 + i s} + a_s^* (1-u)^{1/2 - i s}. \tag{70}...
View full post »

Similar threads

A Calculate the energy-loss straggling of particles using LISE++
Replies
0
Views
3K
A Influence on Neutron spectrum due to energy loss of beam
Replies
8
Views
2K
I Calculate Muon Energy Loss with Bethe-Bloch Calculator
Replies
4
Views
6K
Bethe-Bloch : energy loss to a single electron?
Replies
1
Views
8K
A Relativistic Effects on Particles and Gases
Replies
18
Views
3K
A What is wrong with particle acceleration based fusion?
Replies
5
Views
2K
B Energy seems to disappear when gas is compressed?
Replies
3
Views
2K
A Calculating Primary Ionizations of Cosmic Muons in a Detector
Replies
8
Views
2K
I Differential number of particles in Fermi gas model
Replies
1
Views
2K
DeltaG and DeltaA calculation for heating a gas at constant volume
Replies
3
Views
2K

Hot Threads

Recent Insights

Back
Top