Proportional Counter in X-ray Fluorescence
Aksaray University
Journal of Science and Engineering
e-ISSN: 2587-1277
http://dergipark.gov.tr/asujse
http://asujse.aksaray.edu.tr
Aksaray J. Sci. Eng.
Volume 5, Issue 1, pp. 1-7.
doi: 10.29002/asujse.737686
Available online at
Research Article
Proportional Counter in X-Ray Fluorescence
Hiwa Mohammad Qadr*
Department of Physics, College of Science, University of Raparin, Sulaimanyah, Iraqi Kurdistan, Iraq
▪Received Date: May 15, 2020
▪Revised Date: Jan 28, 2021
▪Accepted Date: Feb 02, 2021
▪Published Online: Feb 03, 2021
Abstract
The purpose of this work is to investigate and quantify x-ray fluorescence, its production and
its spectroscopy. Characteristic x-ray with different energies was obtained from six various
elements using Am-241 source with 59.5 keV. It was found that x-ray energy and intensity
increase with increasing atomic number of material. X-ray spectroscopy was studied for such
elements in respect to their atomic number and intensity of K α using proportional counter.
Furthermore, x-ray fluorescence was produced from different thicknesses of copper foil using
different energies. It was found that there is no substantial difference in x-ray fluorescence yield
with higher thickness of the target.
Keywords
Characteristic x-ray, X-ray fluorescence, Various element, Radioactive sources
1. INTRODUCTION
Nowadays, X-ray is important in many section of life. It is invaluable in many applied fields of
science such as radiology, nuclear energy and radiation damage [1-6]. In 1895, W. Röntgen
discovered X-rays which are produced when a beam of electrons interacts a target [7]. X-ray
can also be produced by the interaction of energetic photons incident on a metallic target via
the photoelectric absorption. The subsequent de-excitation of the ions in the material creates a
characteristic x-ray spectrum of the material [8, 9]. This type of radiation has wave-particle
duality [10]. X-ray photons are less penetrating than gamma-ray photons, depending on the
*
Corresponding Author: ,
0000-0001-5585-3260
2017-2021©Published by Aksaray University
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�H. M. Qadr (2021). Aksaray University Journal of Science and Engineering, 5(1), 1-7.
energy [11, 12]. However, lead is still of choice for shielding of x-ray due to its high density
and atomic number.
Proportional counter is widely used in doing x-ray work as being a sensitive detector of
moderate energy resolution [13]. This detector consists of a cylinder and a thin wire containing
a gas at a given pressure. X-rays enter through a thin window and create ion-electron pair which
are separated by an applied bias. A proportional counter can be used for spectroscopy of a wide
range of radiation. Energy resolution of this type is typically a few percent, in a range of about
5 keV to 25 keV, peak energies can be determined to within 1 keV [14, 15]. However, it has a
lower detection efficiency and poorer energy resolution than other detectors [16]. In this work,
x-ray was used to excite atoms of different elements of low, medium and high atomic number.
2. EXPERIMENTAL METHODS
Fig. 1 shows the block diagram for the experimental system. In this paper, the characteristic xrays produced for six different target elements as shown in Table 1. A proportional counter
filled with xenon gas to detect x-rays from a number of different sources. The detector window
is made of very low atomic number material of Be (Z=4) which allows for low energy to
penetrate. The system was calibrated using two radioactive sources. Am-241 was used for its
gamma energy photon at 59.5 keV and characteristic x-ray at 17.75 keV. Also, Fe-55 was used
for characteristic x-ray at 5.89 keV. The calibrated was done to ensure a range of energy (5- 60
keV) which is covered. Thus, a characteristic x-ray of interest is identified. X-ray source was
placed close to the proportional counter and target elements which were rotated to obtain the
spectrum. These targets have different atomic numbers and variable energy. When the gamma
rays interact with electrons of the targets via the photoelectric effect, the rearrangement of the
electrons in the ionized atoms produce characteristic x-rays with energy that equal to the
difference in the electronic energy levels.
Table 1. Target elements used in obtaining characteristic x-ray.
Targets
Atomic number
Energy of Kα (keV)
Energy of Kβ (keV)
Cu
29
8.038
8.91
Rb
37
13.37
14.97
Mo
42
17.44
19.63
Ag
47
22.10
24.99
Ba
56
32.06
36.55
Tb
65
44.23
50.65
Aksaray J. Sci. Eng. 5:1 (2021) 1-7.
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�H. M. Qadr (2021). Aksaray University Journal of Science and Engineering, 5(1), 1-7.
X-ray fluorescence (XRF) was produced using copper foil. Different thicknesses were applied
with different energies to study any variation in intensity of x-ray produced. The direct beam
coming from the x-ray source was directed to hit the target Cu.
Lead Shield
Proportional
counter
Pre-Amp.
Amplifier
MCA
Computer
X-ray Source
Figure 1. A block diagram of the experimental setup.
3. RESULT AND DISCUSSION
The proportional counter should be calibrated before using in radiation detection to covert
channel number to energy scale. The calibration of the spectrum was carried out using three
energies, 17.75 keV and 59.5 keV from Am-241 and 5.89 keV from Fe-55 radioactive source.
These energies have different atomic numbers. The reason these two particular sources were
chosen simply because of the low energies. Fig. 2 shows the energy peaks used for calibration
of the spectrum. This spectrum was calibrated between 5.89 to 59.5 keV. So that, energies of
x-ray in this range can be identified.
Figure 2. Energy spectrum and calibrated for Fe-55 and Am-241 radioactive sources.
Aksaray J. Sci. Eng. 5:1 (2021) 1-7.
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�H. M. Qadr (2021). Aksaray University Journal of Science and Engineering, 5(1), 1-7.
The energy resolution is obtained from Full Width at Half Maximum (FWHM) of a single peak
using the following equation [17-19]:
𝑅%=
𝐹𝑊𝐻𝑀
𝑥 100
𝐸0
Where R is energy resolution and E0 is the related energy. It can be seen from Fig. 3 that the
FWHM value increase with increasing the energy value. Thus, the poor resolution obtained as
the energy of the photon increased.
Figure 3. Energy resolution of the proportional counter against x-ray energy.
In this work, the emission spectra of variable x-ray source was obtained. Characteristic x-ray is
characteristic of each element which results from transition of electron upon excitation of the
atom. The measured energy of Kα is displayed in Fig. 4 as a function of atomic number of the
target. It was found that characteristic x-ray energy increases with the high atomic number of
the target.
Fig. 5 can be shown that as the atomic number of the target increases, the x-ay yield increases
too. However, the last two points of the figure are questionable which the x-ray yield decreased
with atomic number of the target and then increases again. Thus, something must have gone
wrong during measured of th (...truncated)
