Note that while
PGOPHER can model complex state
dependent widths and related effects, if all that is required is a
constant width for all lines, (whether instrumental or molecular) then
the
Gaussian (Doppler and
instrumental effects) and
Lorentzian (for lifetime
effects) in the main window should be used. (If both of these are set a
Voigt profile is used.) These are added to any additional widths set as
described below. Note also:
- A state dependent width can make the
calculation slower.
- The number of points the spectrum is calculated (nDF)
at
can have a significant effect on the appearance; increase this
parameter until the spectrum does not change. This is because the
lineshape is only calculated on the grid points implied by nDF,
and
misleading results can be obtained if the grid spacing is
comparable to the linewidth. In particular, if the width of a peak is
less than 3*(Fmax-Fmin)/nDF, then the peak is plotted
as a stick, rather than a full lineshape. This
can give significant artifacts in the appearance of the spectrum.
State Dependent Widths
Each state has a
Width
parameter which determines the natural linewidth for that state.
Currently
symmetric and
asymmetric tops have additional
parameters (
wK,
wKa,
wKb ...) which can be used to
give a rotational state dependence to the widths; more may be added in
future but for the moment a rotational state dependent width must be
modeled for other systems by mixing the state of interest with a state
with a non zero
Width;
PGOPHER will evaluate:
Σ ci2wi
for each state where
ci
is the coefficient of the wavefunction for each basis state
i and
wi is the width
associated with that (basis) state. The width associated with a
transition is
then calculated by adding the width of the upper and lower states in
the transition.
The LifeModel setting
The use made of the calculated width associated with a transition
depends on the
LifeModel
setting at the
Simulation level; for some
of these an additional parameter is used,
RefWidth (also at the
Simulation level):
lmNone |
Simply ignore the calculated
width from the simulation.
|
lmWidth |
Include width in simulation, but
do not scale the peak area. (The normalized lineshape used means that
the peak height will scale as 1/Width)
|
lmProductWidth |
Include width in simulation, and
scale peak area as width/(width
+ RefWidth). This models the case where
the result of a predissociation or other process is being detected,
with a rate proportional to the given width, so that no width implies
zero rate so no signal. In this case RefWidth is a measure of the
strength of any competing process. As a special case, A RefWidth of 0
gives a peak area proportional to width.
|
lmProduct |
Discard width from simulation
but scale peak area as width/(width
+
RefWidth) or just width
if RefWidth=0. This will
give results
the same as lmProductWidth
if the molecular widths are rather smaller than the instrumental
resolution, but can be rather faster to calculate. |
lmParentWidth |
Include width in simulation, and
scale peak area as 1/(width +
RefWidth). This models the case where
predissociation or other process results in loss of the species being
detected, so the larger the width (=rate) the smaller the signal. In
this case RefWidth is the
linewidth in the absence of the loss process.
|
lmParent |
Discard width from simulation
but scale peak area as 1/(width
+ RefWidth). This will give results the
same as lmParentWidth if
the molecular widths are rather smaller than the instrumental
resolution, but can be rather faster to calculate. |
lmGateWidth
|
Include width in simulation, and
scale peak area as exp(-width *
RefWidth). This models detecting
fluorescence excited by a short pulse, where the integration (=gate)
time is less than the duration of the fluorescence. Only a fraction of
the florescence is then detected from states with a long lifetime (and
thus small width), so transitions involving these states appear
relatively weakly. In this case RefWidth
is proportional to the gate
width.
|
lmGate |
Discard width from simulation
but scale peak area as exp(-width
*
RefWidth). This will give results the
same as lmGateWidth if
the molecular widths are rather smaller than the instrumental
resolution, but can be rather faster to calculate. |