Counting efficiency

The counting efficiency is the ratio between the number of particles or photons counted with a radiation counter and the number of particles or photons of the same type and energy emitted by the radiation source.^[1]

Factors

Several factors affect the counting efficiency:

The distance from the source of radiation
The absorption or scattering particles by the medieum (such as air) between the source and the surface of the detector
The detector efficiency in counting all radiation photons and particles that reach the surface of the detector

The accompanying diagram shows this graphically.

Scintillation Counters

Counting efficiency varies for different isotopes, sample compositions and scintillation counters scinitillation counters Poor counting efficiency can be caused by an extremely low energy to light conversion rate, (scintillation efficiency) which, even optimally, will be a small value. It has been calculated that only some 4% of the energy from a β emission event is converted to light by even the most efficient scintillation cocktails.^[2]

Gaseous counter

Proportional counters and end-window Geiger-Muller tubes have a very high efficiency for all ionising particles that reach the fill gas. Nearly every initial ionising event in the gas will result in Townsend avalanches, and thereby an output signal. However the overall detector efficiency is largely affected by the attentuation due to the window or tube body through which particles have to pass.

In the case of gamma photons the efficiency is more dependent upon the fill gas. Low enery photons will interact more with the fill gas, than high energy photons.

References

^ IUPAC Compendium of Chemical Terminology (2nd ed.). 1997.
^ "Counting efficiency and quenching". National Diagnostics. 2011. Retrieved April 6, 2013.

SI photon units
v
t
e
Quantity		Unit		Dimension	Notes
Name	Symbol^{[nb 1]}	Name	Symbol	Dimension	Notes
photon energy	$n$			1	count of photons $n$ with energy $Q p = h c / λ$ .^{[nb 2]}
photon flux	$Φ q$	count per second	s⁻¹	T⁻¹	photons per unit time, $d n /d t$ with $n$ = photon number. also called photon power
photon intensity	$I$	count per steradian per second	sr⁻¹⋅s⁻¹	T⁻¹	$d n /d ω$
photon radiance	$L q$	count per square metre per steradian per second	m⁻²⋅sr⁻¹⋅s⁻¹	L⁻²‍T⁻¹	$d 2 n /(d A cos(θ) d ω)$
photon irradiance	$E q$	count per square metre per second	m⁻²⋅s⁻¹	L⁻²‍T⁻¹	$d n /d A$
photon exitance	$M$	count per square metre per second	m⁻²⋅s⁻¹	L⁻²‍T⁻¹	$d n /d A$
See also: Photon counting SI Radiometry Photometry

^ Standards organizations recommend that photon quantities be denoted with a suffix "q" (for "quantum") to avoid confusion with radiometric and photometric quantities.
^ The energy of a single photon at wavelength $λ$ is $Q p = hc / λ$ with $h$ = Planck constant and $c$ = velocity of light.

[1] IUPAC Compendium of Chemical Terminology (2nd ed.). 1997.

[test-2] "Counting efficiency and quenching". National Diagnostics. 2011. Retrieved April 6, 2013.

[note-suffix-q-3] Standards organizations recommend that photon quantities be denoted with a suffix "q" (for "quantum") to avoid confusion with radiometric and photometric quantities.

[note-photon-energy-4] The energy of a single photon at wavelength $λ$ is $Q p = hc / λ$ with $h$ = Planck constant and $c$ = velocity of light.

[1]

[2]

[nb 1]

[nb 2]

Factors

Scintillation Counters

Gaseous counter

See also

References