Acta Polytechnica


Acta Polytechnica 53(2):134–137, 2013 © Czech Technical University in Prague, 2013
available online at http://ctn.cvut.cz/ap/

THE CONSTRUCTION OF THE FAST RESISTIVE BOLOMETER
FOR A SXR MEASUREMENT ON THE GIT-12 FACILITY

Jakub Cikhardta,∗, Daniel Klíra, Pavel Kubeša, Josef Kravárika,
Karel Řezáča, Ondřej Šílaa, Alexander V. Shishlovb,

Alexey Yu. Labetskyb

a Department of Physics, Faculty of Electrical Engineering, Czech Technical University in Prague, Czech Republic
b Institute of High Current Electronics, Siberian Branch of the Russian Academy of Sciences in Tomsk, Russian

Federation
∗ corresponding author: cikhajak@fel.cvut.cz

Abstract. A lot of kinds of instruments are used for the SXR measurement at pulsed power facilities,
but most of them are difficult to calibrate absolutely. For the determination of the energy of SXR
radiated by the discharge on Z-pinches, it is possible to use the bolometer which can be calibrated
analytically. The bolometer can be constructed with the sufficient sensitivity and, at the same time,
with the time resolution in the order of nanoseconds. This bolometer was designed and constructed
for the measurement on the 5 MA facility GIT-12 at the Institute of High Current Electronics (IHCE)
of the Siberian Branch Russian Academy of Sciences in Tomsk. The experiments on GIT-12 with
the neon and deuterium gas-puff load were diagnosed by the copper bolometer with the time resolution
of 4 ns and the sensitivity of 12 V cm2 J−1.

Keywords: bolometers, X-rays, Z-pinches, plasma diagnostics.

1. Introduction
The ohmic bolometer is based on the principle of trans-
formation of radiated energy into thermal energy.
It leads to the change of the resistance according
to the well known formula

R = R0 (1 + α∆ϑ) , (1)

where R0 is the initial resistance, α is the thermal
coefficient of the resistivity and ∆ϑ is the change
of the temperature. In the case of metallic bolome-
ters, the coefficient α can be considered as a posi-
tive constant, thus the dependence of the resistivity
on the temperature is linear.

The parameters and design are dependent on the ap-
plication of a bolometer. Bolometers are used
in microwave technology, pyrometry, astronomy and
in plasma diagnostics. The bolometer described in this
paper is designed for measurement of the pulses
of SXRs produced by a short lived plasma generated
by pulse power generators especially large Z-pinches.
The experiments with this bolometer were performed
with triple shell neon and deuterium gas-puffs. During
the stagnation of the dense neon gas-puff, the most
of kinetic energy of the Z-pinch is radiating in neon
K-shell lines (hν ∼= 0.9÷1.4 keV) [4]. In case of the deu-
terium, the main component of the radiation is the con-
tinuous bremsstrahlung.
In this case the sensitive element of the bolometer

is a very thin metal stripe. Dimensions and material
of the stripe were determined with regard to the re-
quirement for the bolometer:

• sufficient sensitivity which is constant on wide range
of the photon energy,

• time resolution in the order of nanoseconds,
• ability to work in environments with extreme elec-

tromagnetic noise.

2. Parameters determination
2.1. Sensitivity
The sensitivity s of this detector is determined as a ra-
tio between the change of the output voltage and
the fluence % at the point where the bolometer is
placed,

s =
∆U

∆Q/S
=

∆U
∆%

, (2)

where S is the surface of the bolometer sensitive el-
ement. Using Eq. 1 and another well known phys-
ical formulas we obtain the sensitivity determined
by the dimensions of the sensitive element, material
constants and bolometer current,

s = ρElα
1

d2Cρw
I, (3)

where ρE is resistivity, α is the thermal coefficient
of the resistivity, C is the specific heat, ρ is the density
of the material, l, d and w are length, thickness and
width of the sensitive element respectively and I is
the current of the bolometer.

2.2. Range of photon energies
The photon energies which can be measured with
the bolometer are determined by the radiation absorp-
tion. For our purpose the data from [3] were used.

134

http://ctn.cvut.cz/ap/


vol. 53 no. 2/2013 The Construction of the Fast Resistive Bolometer

Figure 1. The absorption characteristics of 2 micron
metal foils: a) aluminium foil, b) copper foil.

In the Fig. 1 the absorption characteristics of the alu-
minium and copper of 2 micron thickness are shown
as examples.
In Fig. 1a, the absorption of the aluminium foil

has a minimum at about 1.6 keV. This minimum cor-
responds to the K-shell edge of the aluminium [8].
If the bolometer is made of this foil, the detector will
be selective. The absorption characteristic of 2 micron
thick copper foil can be seen in the Fig. 1b. This
characteristic is much more “smooth” than the charac-
teristic of the aluminium. For our application, a non-
selective detector is needed in the range up to 2 keV,
therefore the copper foil was chosen. If the photon
energy range is considered as a region where the sensi-
tivity is not less than 1/

√
2 of the maximal sensitivity,

the energy range of the bolometer made of 2 micron
thick copper is up to 3 keV.

2.3. Time resolution
The time resolution of bolometers is defined by
the characteristic time needed to equilibration of
the temperature in the sensitive element. If the front
side of the metal foil is irradiated by a short SXR
pulse, the absorbed energy will have the exponential
dependence on the depth inside the foil [1]. The energy
of SXR absorbed in the material is transformed into
the thermal energy. Therefore we can consider that
the dependence of temperature on the depth inside
the metal foil is also exponential,

ϑ (x, 0) = ϑ (0, 0) e−γρx, (4)

where x is the distance from the irradiated surface
of the foil and γ is the absorption coefficient of mate-
rial. We also consider that there is no heat transfer

Figure 2. The time dependence of the temperature
difference of the sides of the 2 microns copper foil.

between the sensitive element and surroundings be-
cause in our detector it is usually placed in vacuum.
Therefore we can write

∂ϑ (0, t)
∂x

=
∂ϑ (d,t)
∂x

= 0. (5)

Using the conditions Eq. 4 and Eq. 5 in the one-
dimensional heat transfer equation [6]

∂2ϑ (x,t)
∂x2

=
1
χ

∂ϑ (x,t)
∂t

(6)

we obtain solution

ϑ (x,t) =
ϑ0
γρd

(
1 − e−γρd

)
+

+
2ϑ0
d

∞∑
n=1

1 − (−1) e−γρd(
πn
γρd

)2
+ 1

cos
(πnx

d

)
e−(

πn
d )

2
χt,

(7)

where ϑ0 = ϑ(0, 0) and χ is thermal diffusivity.
For determination of the characteristic time, it is
useful to study the thermal difference between both
sides of the foil: ϑ(0, t) − ϑ(d,t). The characteris-
tic time of bolometer can be defined as the time
at which the temperature difference drops at 1/e
of the maximum of value. If this exponential pro-
cess is equal to 1/e we consider that temperature
in the foil is equilibrated. This temperature difference
is plotted in the Fig. 2.
The characteristic time of the bolometer with sen-

sitivity element made of 2 microns copper foil is 4 ns.
The most important properties of the designed

bolometer are shown in the Tab. 1.

3. Construction
3.1. Bolometric detector
Cross-section of the bolometric detector is shown
in the Fig. 3.
The foil is fixed by mechanical clamps. Because

the resistance of the foil is low (R0 = 0.126 Ω) the four-
clamp method was used for connection to the electric
circuit. Structure of the sensitive element and the sur-
rounding circuits is symmetrical in order to achieve

135



Jakub Cikhardt et al. Acta Polytechnica

Property Value
Material copper
Thickness 2 microns
Width 2 mm
Length 30 mm

Initial resistance (0.126 Ω)
Time resolution 4 ns

Sensitivity 12.43 V cm2 J−1

Table 1. The properties of the designed bolometer.

Figure 3. Cross-section of the bolometric detector.

a lower inductance. The screen with aperture is placed
above the sensitive element. This screen protects
the passive parts of the detectors against the irradia-
tion and it allows to place a filter between the sensitive
element and the source of radiation.

3.2. Power supply
To achieve the required sensitivity, it is necessary
to supply the bolometer with a current of least
10 A. To avoid melting of the thin foil it is nec-
essary to supply the bolometer with a short cur-
rent pulse and at the same time the power supply
pulse must be longer than the duration of the SXR
pulse. We choose 10 µs length of the supply pulse.
The bolometer changes resistance because of temper-
ature change. Therefore we need to know bolome-
ter voltage and at the same time the bolometer cur-
rent. We constructed MOS-FET pulsed power supply
with a defined output current, thus we need to reg-
ister the bolometer output voltage only. The com-
parison of the measured and simulated dependence
of the power supply current on the load resistance is
shown in the Fig. 4.

4. Experiments on GIT-12 facility
The bolometer was used during Z-pinch experiments
on the GIT-12 facility at the Institute of High Cur-
rent Electronics (IHCE) of the Siberian Branch Rus-
sian Academy of Sciences in Tomsk. The GIT-12 is
large pulsed power generator with 12 Marx genera-
tors. The peak current of this facility reaches 5 MA,
the rise time is 200 ns with plasma opening switches

Figure 4. The comparison of the measured and
simulated dependence of the power supply current
on the load resistance.

(POS) and 1400 ns without POS, total energy stored
in capacitors is 2.6 MJ.
The load of these experiments was a triple shell

gas-puff of 160 mm, 80 mm and 30 mm diameters
of the individual nozzles. Neon, deuterium (D2), ar-
gon and their combination of this were used as filling
gases for the gas-puff. The typical length of the gas
column during these experiments was about 2 cm.
The bolometer was placed in 2 m distance from the dis-
charge without any filter.

The typical detector output signal, namely the shot
with neon (see shot no. 1 in Tab. 2) is plotted in
the Fig. 5. The signal without a SXR pulse is plotted
also for the comparison. The power supply current
of the bolometer is starting to rise at the time 6 µs and
at the time 8 µs is fully stabilized. The electromagnetic
noise at the time around 10 µs is caused by ignition
of the spark-gaps in the Marx generators. The irradi-
ation of the bolometer occurs at time of 12 µs, when
the significant voltage step is observed. The magni-
tude of this voltage step corresponds to 50 kJ of radi-
ated energy during implosion of the gas-puff. Other
measured values including the shots in the deuterium
and combination of the deuterium and neon, or ar-
gon are shown in Tab. 2. All these shots were carried
out with the triple shell gas-puffs. The notation A-B-C
means gas A in outer the shell, gas B in the middle
shell and gas C in the inner shell.

Results of these shots are shown in the Tab. 2.

4.1. Discussion of the experimental
results

It is seen in Tab. 2 that the radiation in shot
with the deuterium was lower. Thus more of the ki-
netic energy of the Z-pinch is transformed to the ther-
mal energy.
It is not easy to theoretically calculate the kinetic

energy of the Z-pinch exactly. For a rough estimation
of the kinetic energy of the Z-pinch can be used the for-
mula [8]

Ek = 2.3I2ml (kJ), (8)
where Im is the maximum of the current peak
in MA and l is the length of the discharge in cm.

136



vol. 53 no. 2/2013 The Construction of the Fast Resistive Bolometer

Figure 5. The signal of the bolometric detector
during the discharge in comparison with detector’s
signal without the irradiation.

Shot Current Triple shell SXR energy
No. (MA) Gas-puff (kJ)
1 3.73 Ne-Ne-Ne 50
2 3.55 D2-D2-D2 13
3 3.64 D2-D2-D2 22
4 2.58 D2-D2-D2 21
5 3.60 Ne-D2-D2 28
6 3.36 Ne-D2-D2 23
7 3.36 Ne-D2-D2 26
8 3.10 Ne-D2-D2 18
9 3.28 Ne-D2-D2 24
10 3.66 Ar-D2-D2 14
11 2.16 D2-D2-D2 27

Table 2. Results of the SXR measurement at the ex-
periments on GIT-12 facility.

Substituting values from shot no. 1 we obtain the ki-
netic energy about 64 kJ. It corresponds to measured
values and to the assumption that the most of kinetic
energy of the neon gas-puff is changed to the energy
of the radiation.
The temperature of the bolometer at the steady

state can be determined by the well known for-
mula ∆ϑ = ∆Q/(Cm), where ∆Q is an absorbed
energy, C is a specific heat capacity and m is the mass
of the bolometer foil. Substituting the parameters
of the bolometer and radiated energy of 50 kJ from
the shot no. 1, we obtain the change of the temperature
of 144 K. If the initial temperature of the bolometer
was 293 K, the temperature after irradiation is 437 K.
So the melting point of the copper at 1357 K was not
achieved.
The accuracy of this measurement is decreased

by several error factors. The most significant factor
is electromagnetic noise. For example the RMS value
of this noise in shot no. 1 achieved to 7 % of the useful
signal. Including the noise, uncertainty of the stability
of the power supply current and uncertainty of the di-
mensions of the bolometer foil, the total uncertainty
of the measured radiated energy is about 10 %.

5. Conclusion
The bolometric detector for pulse SXR measurement
was designed and constructed. The experiments
on the GIT-12 facility was performed with this de-
tector. The sensitivity, noise immunity and uncer-
tainty of the detector is sufficient for the measurement
at the terawatt generator GIT-12. Amount of ener-
gies were measured in the range from 13 kJ to 50 kJ.
It depended on the current peak and gas of the load
and its amount.
The measurements confirmed the assumption that

the discharges in the deuterium produced less amount
of the radiated energy of SXRs than the discharges
in gases with higher atomic number. However the en-
ergy of SXRs radiated during the discharge in deu-
terium gas-puff was surprisingly high. Probably it is
the radiation of the material of electrodes. The mea-
sured values corresponds to the theoretical estima-
tion of the kinetic energy of the gas-puff. Because
the amount of the radiated energy carries the infor-
mation about the real kinetic energy of the gas-puff,
it can be used for the gas-puff optimization as a scale.

For determination of the dependences of the amount
of the radiated energy on the gas-puff parameters and
for verification of the detector’s time resolution we
need more experimental shots which are scheduled
on spring 2013.

Acknowledgements
This work was supported by the Research Program MSMT
No. LA08024, ME09087 and GACR P205/12/0454,
IAEA RC 14817 and CTU SGS 10/266/OHK3/3T/13.

References
[1] D. Attwood. Soft X-rays and extreme ultraviolet

radiation: Principles and applications. Canbridge
University press, 1999.

[2] J. Cikhardt. Konstrukce rychleho bolometru pro
mereni intenzity impulsniho mekkeho rentgenového
zareni. FEE CTU, Prague, 2012. Diploma thesis.

[3] E. M. Gullikson. Filter transmission. http:
//henke.lbl.gov/optical_constants/filter2.html.
The Center for X-Ray Optics.

[4] A. Yu. Labetsky, V. A. Kokshenev, N. E. Kurmaev,
et al. Study of the current-sheath formation during the
implosion of multishell gas puffs. Plasma Physics
Reports 34(3):228–238, 2008.

[5] M. A. Liberman, J. S. De Groot, A. Toor, R. B.
Spielman. X-ray data booklet. Berkley. Lawrence
Berkley National Laboratory University of California,
2009. 3rd edition.

[6] J. H. Lienhard IV, J. H. Lienhard V. A Heat Transfer
Textbook. Phlogiston Press, Cambridge, Massachusetts,
2008. 3rd edition.

[7] R. B. Spielman, C. Deeney, D. L. Fehl, et al. Fast
resistive bolometer. Tech. Rep. SAND98-1987, Sandia
National Laboratories, 1998.

[8] A. Thompson, et al. X-ray data booklet. Lawrence
Berkley National Laboratory University of California,
Berkley, 2009. 3rd edition.

137

http://henke.lbl.gov/optical_constants/filter2.html
http://henke.lbl.gov/optical_constants/filter2.html

	Acta Polytechnica 53(2):134–137, 2013
	1 Introduction
	2 Parameters determination
	2.1 Sensitivity
	2.2 Range of photon energies
	2.3 Time resolution

	3 Construction
	3.1 Bolometric detector
	3.2 Power supply

	4 Experiments on GIT-12 facility
	4.1 Discussion of the experimental results

	5 Conclusion
	Acknowledgements
	References