Difference between revisions of "EPR Simulations with EasySpin"
Line 142: | Line 142: | ||
EasySpin can handle this fairly well, by simply defining a second Spin System: | EasySpin can handle this fairly well, by simply defining a second Spin System: | ||
− | + | ''Sys1.g = 2;'' | |
− | + | ''Sys1.lwpp = 1;'' | |
− | + | ''Sys1.weight = 2;'' | |
− | + | ''Sys2.g = 2.1;'' | |
− | + | ''Sys2.lwpp = 0.8;'' | |
− | + | ''Sys2.weight = 1;'' | |
− | + | ''Exp.mwFreq = 9.5;'' | |
− | + | ''Exp.Range = [300 360];'' | |
− | + | ''garlic({Sys1,Sys2},Exp);'' |
Revision as of 20:25, 7 February 2019
Overview
This page serves as a resource to assist those trying to simulate EPR spectra with the EasySpin MATLAB package.
Importing Data
EasySpin has a function for doing this, called eprload(). The method used to import your data depends on the format in which your experimental data is saved:
- For Modern Bruker Spectrometer Data:
[B,spc] = eprload('mydata');
- For Older Bruker Spectrometer Data:
[B,spc] = eprload('myolddata.spc'); [B,spc] = eprload('myolddata.par');
The function changes when you are trying to load a text file of data:
- For Data Stored in Text Files:
[B,spc] = textread('mydata.txt','%f %f');
- Text Files with Header Information:
[B,spc] = textread('mydata.txt','%f %f','headerlines',17)
Creating a Simulation
The central concept to constructing a simulation with EasySpin is defining a Spin System (Sys) and Experimental Parameters (Exp).
Spin System
There are a variety of components that factor into a Spin System.
Electron and Nuclear Spins
The spins can be defined with Sys.S() according to the following:
Sys.S = 1/2; % one electron spin with S=1/2 Sys.S = 5/2; % an S=5/2 spin Sys.S = [1/2, 1/2]; % two S=1/2 spins Sys.S = [1, 1, 1/2]; % two S=1 spins and one S=1/2 spin
If this is not specified, the default value is S = 1/2.
The Nuclei can be specified using Sys.Nucs() according to the following:
Sys.Nucs = '1H'; % one hydrogen Sys.Nucs = '63Cu'; % a 63Cu nucleus Sys.Nucs = '59Co,14N,14N'; % a 59Co and two 14N nuclei
You can specify an arbitrary number of nuclei for this system. In order to specify the number of each type of nucleus, you must use Sys.n() :
Sys.Nucs = '1H,13C'; % one class of 1H and one class of 13C Sys.n = [2 3]; % 2 protons and 3 carbon-13 spins
G-value
As you're on this page, you are probably aware that there are some considerations to be made about the kind of system (isotropic vs. anisotropic) we are simulating when specifying the g-value. For all purposes here, we will assume that it will always be isotropic. To specify this you must use Sys.g():
Sys.g = 2.0023;
This actually is not necessary, since the default is set to 2.0023... for all inputs. Still worth mentioning!
Hyperfine Coupling Constants and Number of Equivalent Nuclei
These are specified in MHz in EasySpin. No worries, though because EasySpin has a function that allows us to convert mT (or Gauss) into MHz:
A_MHz = mt2mhz(A_mT); % mT -> MHz conversion A_MHz = mt2mhz(A_G/10); % G -> MHz conversion (1 G = 0.1 mT)
Consider the following system, in which you have a hydrogen atom with a 10 MHz coupling to the unpaired electron and a 13C atom with a 12 MHz coupling:
Sys.Nucs = '1H,13C'; % Defines the Hydrogen nucleus and the Carbon-13 nucleus Sys.A = [10 12]; % MHz... Defines the HFCC
To specify the number of equivalent nuclei, Sys.n() is used, as shown in the following examples:
For a single proton:
Sys.Nucs = '1H'; Sys.n = 1; Sys.A = 5.3;
For two equivalent protons (with identical hyperfine coupling constants):
Sys.Nucs = '1H'; Sys.n = 2; Sys.A = 5.3;
For something more complex (such as the naphthalene radical anion, which contains two sets of 4 equivalent nuclei):
Sys.Nucs = '1H,1H'; Sys.n = [4 4]; Sys.A = [-14 -5];
Line Width
To specify the line width, EasySpin uses Sys.lwpp(). This gives the peak-to-peak line width. It should be noted here that the unit used for Line Widths is mT!!! For peak-to-peak line widths:
Sys.lwpp = [0 0.03]; % Gaussian and Lorentzian peak-to-peak line width, mT
There is another option Sys.lw():
Sys.lw = [0 0.05]; % Gaussian (1st input) and Lorentzian (2nd input) FWHM (full width at half height), mT
Experiment Parameters
There are a variety of fields that you can/must specify before you can get your simulated spectrum.
Microwave Frequency
The microwave frequency must be given in units of GHz. This can easily be defined with the following:
Exp.mwFreq = 9.385; % X-band
Field Range/Sweep Width
This is an optional step. If omitted, EasySpin will attempt to determine a Sweep Width large enough to accommodate the entire spectrum, but this can fail.
There are two ways to enter the magnetic field sweep width. Either give the center field and the sweep width (in mT) in Exp.CenterSweep():
Exp.CenterSweep = [340 80]; % in mT
As an alternative, you can specify the lower and upper limit of the sweep range (again in mT) in Exp.Range():
Exp.Range = [300 380]; % in mT
Number of Points
Again, an optional step. It is not required to be a power of 2 for EasySpin.
Exp.nPoints = 5001;
Harmonic
You can set the harmonic that EasySpin will calculate, meaning either the Absorption or a derivative. This is specified with Exp.Harmonic():
Exp.Harmonic = 0; % absorption spectrum, direct detection Exp.Harmonic = 1; % first harmonic (default)
Multiple Species in one Simulation
EasySpin can handle this fairly well, by simply defining a second Spin System:
Sys1.g = 2; Sys1.lwpp = 1; Sys1.weight = 2; Sys2.g = 2.1; Sys2.lwpp = 0.8; Sys2.weight = 1;
Exp.mwFreq = 9.5; Exp.Range = [300 360];
garlic({Sys1,Sys2},Exp);