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Skip - LabLogic
DOC 413-003
Application note
Version 1.0
HIDEX 300 SL
OPTIMIZATION OF ALPHA BETA SEPARATION IN 300 SL TDCR LSC
Alpha and beta separation is one of the strongest features of Hidex 300 SL liquid scintillation counter.
Sample preparation is the first step for achieving good Alpha beta separation. Some of the important
factors include:
Type of sample: Aqueous or Organic. Organic samples give the best AB separation.
Cocktail type : The recommended cocktails are Aqualight for Aqueous samples and Maxilight for
Organic samples. Please note that some cocktails are not compatible with alpha beta separation.
Water content in the sample: Water increases quench and is one of the most important factors
affecting AB.
Sample Volume: Optimum sample volume depends on amount of water in the sample, sample
preparation & total activity in the sample.
Sample Preparation: The acidity of the sample & salt content etc. is influenced by the sample
preparation. Variations in acidity or salt concentration can affect quench and alpha beta separation.
Sample to cocktail ratio: Generally, the lower the sample to cocktail ratio, the better the alpha beta
separation quality.
Activity: High beta activity of > 100,000 DPM adversely affects the separation as 2 successive betas
could be counted as Alpha pulse. High active samples should be diluted when the activity is high and
is adversely affecting the separation.
Glass vials: Frosted Glass vials improve alpha beta separation by reducing the amount of internally
reflected light from the sample. Note that glass can contain some alpha background.
Plastic vials: Optimal ones are Teflon coated plastic vials. In normal plastic vials, slight diffusion of
cocktail into plastic wall can cause gradually increasing alpha background. This is due to cosmic
particles causing alpha like pulses in cocktail impregnated plastic.
Principle of alpha beta separation
In Hidex 300 SL the alpha beta separation is based on pulse length index discrimination. A highly
useful 2-dimensional graph is produced to analyze and verify the alpha beta separation.
The exponential decay of a LSC pulse has 2 decay components.
Prompt component, typically < 20 ns
Delayed component, typically < 100 ns.
Betas have more prompt component & alphas have more delayed component.
Because of more delayed component Alphas are said to produce "longer" pulses than betas.
For a/b separation, Hidex 300 SL starts to analyze the pulse after "alpha delay time" (default near 40
ns) so that it collects mainly the delayed component. This is much bigger in alpha pulses than in beta
pulses. Therefore alphas have greater y-component in the 2D graph.
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DOC 413-003
Application note
Version 1.0
HIDEX 300 SL
3D plot of Rn222 with Hidex 300SL
260
250
240
230
220
210
200
190
180
170
160
150
130
Counts 140
120
110
100
90
80
70
60
50
40
30
20
10
0
Alpha
emitters
0
48
96
144
192
240
288
336
384
432
480
528
576
624
672
720
768
816
864
912
960
1008
PLI
discriminator
26
13
0
PLI
MCA Channel
Beta
emitters
Figure 1 shows a 3 dimensional graph of an Rn-222 sample. The Beta emitters are sprad over
a wider energy range in the MCA. Alpha peaks are clearly separated due to higher PLI
number.
Workflow: Alpha delay time followed by Y Gain & PLI should be used for optimization of separation,
as visualized in 2 Dimensional Spectrum. The Alpha beta counting should be started with the settings
found in factory calibration, they can be found in the instrument Quality Assurance sheet.
Alpha Delay Time: Is the Starting time for analyzing delayed component. Increase in Alpha delay time
decreases both Alpha & Beta counts, while the ratio between Alphas & Betas is maintained.
Y Gain: Shifts the 2D spectrum up or down, clearer optical resolution. Ensure that the entire spectrum
is located in the middle. Ensure that the Alpha peak does not touch the top or limiting portion of the
Axis.
Alpha Tail Offset time: Is used for adjusting the beta band horizontality. To be maintained at 1 or 2.
Increasing this would compress the entire spectrum downwards.
Ensure that the spectrum is not compressed.
ROI: Choose Region of Interest depending on the peaks of choice.
Pulse Length Index: Discrimination line in the 2D plot for classification of Alpha pulses from Beta
pulses. Choose appropriate PLI depending on the spectrum or depending on Figure of Merit.
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DOC 413-003
Application note
Version 1.0
HIDEX 300 SL
Alpha
Beta
Po-218
140
25
Po-214
120
20
100
Pb-214, Bi-214
15
80
10
60
Rn-222
40
5
20
0
0
0
200
400
600
800
0
1000
200
400
600
800
1000
28
24
20
16
12
8
960
0
1008
912
864
816
768
720
672
624
576
528
480
432
384
336
288
240
192
144
96
48
0
4
Figure 2 shows the same Rn-222 sample as in figure 1.The individual beta and alpha spectra are as
they appear in the Report Render spectral analysis macro. From the 2-dimensional plot the optimal
PLI value can be set at 14.
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DOC 413-003
Application note
Version 1.0
HIDEX 300 SL
Procedure for Optimizing Pulse Length Index :
Count known activity of Alpha emitter and optimize the Counting parameters.
With the same counting conditions, count Blank for 60 minutes or more.
Alpha CPM
Counting
Efficiency %
Bg CPM
FOM ( CE % X
CE% / Bg )
PLI 1
PLI 2
PLI 3
PLI 4 etc
Choose the PLI which gives max. FOM value.
Known activity of beta emitter can be used for Background calculations for a given alpha beta mixture.
Note:
PMTs & the associated electronics have some time constants so that they don't reproduce the pulse
shape absolutely.
Because of inherent uncertainty in decay, photon emission, collection etc.. it is difficult to reproduce
the same 2D spectrum even for repeat counts.
Instrument counting parameters can be optimized for a given type of sample, its volume & type of
sample preparation & activity.
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