Acta Polytechnica


doi:10.14311/AP.2015.55.0237
Acta Polytechnica 55(4):237–241, 2015 © Czech Technical University in Prague, 2015

available online at http://ojs.cvut.cz/ojs/index.php/ap

ABOUT THE UNIFORMITY AND THE STABILITY OF A VOLUME
DISCHARGE IN HELIUM IN NEAR-ATMOSPHERIC PRESSURE

V. S. Kurbanismailova, O. A. Omarova, G. B. Ragimkhanova,
A. A. Aliverdieva, b, ∗

a Dagestan State University, Gadjieva Str. 43A, 367025, Makhachkala, Russia
b DSC Institute for Geothermal Research of the Russian Academy of Sciences, Pr. Shamilya 39A, 367030,

Makhachkala, Russia
∗ corresponding author: aliverdi@mail.ru

Abstract. We present experimental electric and time-spatial characteristics of a volume discharge
and of the transition from a volume burning stage into a channel mode nearing atmospheric pressure.
We show that the discharge uniformity rises with the increase of cathode spots density and gas pressure.

Keywords: discharge formation; volume discharge; streamer; discharge plasma.

1. Introduction
One of the applications of volume discharges in inert
gases is gas laser pumping. In this case, in order to in-
crease the power characteristics of gas lasers, we need
(i) to improve the pumping methods and (ii) to opti-
mize the excitation conditions [1,2,3,4,5,6,7]. A prob-
lem of pumping optimization consists in the reception
of certain electric characteristics of discharge plasma
with a constant spatial uniformity during the pump-
ing. The discharge instability results in the transition
from volume burning into a channel stage (contracted
discharge). There can be various physical mechanisms
responsible for discharge instabilities. They depend
on the gas (or the gas mixture) [8,9,10,11,12]. There-
fore the study of volume discharge properties in pure
gases has both basic and practical interest.
Toward this general aim we have experimentally

investigated under a wide range of initial conditions,
the plasma characteristics of volume and contracted
discharges, as well as the processes of discharge coun-
teraction and plasma torch creation in helium at at-
mospheric pressure.

2. Experimental installation and
research methods

The experimental setup and research methods are simi-
lar to those described in our previous papers [13,14,15].
The gap under study (about 1 cm in length) irradiates
either by spark discharge through the grid anode or
by UV source placed in the same gas at a distance
of 5–7 cm from the main gap axis. The diameter of
the electrodes is 4 cm. We have used electrodes with
various shapes (plane and hemispherical, R = 30 cm)
made of different materials: aluminium, stainless steel
and copper.

The pulsed voltage source generates voltage pulses
with a variable amplitude of up to 30 kV and a front
duration of ∼ 10 ns. The discharge voltage and current
are measured with the application of digital oscillo-

scopes. Frame photographs of the discharge glow
(showing the distribution of radiation intensity both
along, and across electrodes) are obtained using a
FER-2 streak camera with the UMI-92 image tube.
When photographing a discharge in the frame mode,
the scanning voltage of the FER-2 is switched off.
Frame photographs are synchronized with electrical
characteristics of the discharge by simultaneously sup-
plying the triggering voltage pulse to the FER-2 and
the signal of the discharge current (or voltage) pulse to
double-beam storage oscilloscopes. Streak images of
the discharge glow (discussed in [15]) are also obtained
and synchronized with the discharge current (or volt-
age) pulse by applying the signal of the current (or
voltage) pulse to the deflecting plates of the UMI-92
image tube, simultaneously with the discharge scan-
ning. Time-integrated photographs of the discharge
glow with a high spatial resolution are taken using a
digital camera.

3. Results and discussion
We have investigated a discharge transition from a
volume burning into a channel stage in helium with
a discharge area S = 12 cm2, a distance between
electrodes d = 1 cm, a gas pressure P = 1–5 atm,
a discharge voltage U from static discharge up to
hundreds of percent of overvoltage.
As we can see from Fig. 1 photos 1–4, a homoge-

neous volume discharge burns at small external fields
(E0 < Ecritical = 6 kV/cm). The growth of uncom-
pleted anode channels (which are adhered to cathode
spots with high conductivity) starts from a current
density of about 40 A/cm2 (see Fig. 1 photos 5–6).
An increase in current density up to 60 A/cm2 (see
Fig. 1 photos 7–11) leads to further promotion of un-
completed anode channels, anode spotting, and also
to the appearance of uncompleted cathode channels.
When the current density surpasses 100 A/cm2, the
anode and cathode channels merge (Fig. 1 phot 12).

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http://dx.doi.org/10.14311/AP.2015.55.0237
http://ojs.cvut.cz/ojs/index.php/ap


V. S. Kurbanismailov, O. A. Omarov, G. B. Ragimkhanov, A. A. Aliverdiev Acta Polytechnica

Figure 1. Time-integrated photos of the discharge glow at atmospheric pressure.

(a) (b)

Figure 2. Typical oscillograms of current and voltage: (a) U0 = 8 kV, P = 1 atm, d = 1 cm; (b) U0 = 9 kV,
P = 3 atm, d = 1 cm). Here, t0 is the beginning of the applied voltage growth; t1 is the beginning of the first voltage
drop; t3 is the beginning of counteraction of a volume discharge in a spark channel; t3 − t2 is the volume phase
duration.

The instant of a discharge interval overlapping with
a plasma channel (Fig. 1 photo 12) is clearly visible,
when the growth of channel conductivity causes a
second sharp voltage drop (see Fig. 2).

In the coordinated pump mode, a specific heat input
of ∼ 0.1 J/cm3 is provided, which is the maximum for
helium in a homogeneous burning stage. The duration
of discharge uniformity is adjusted by the reduction of
the current density or by the increase of gas pressure.
At a pressure of 5 atm, the step on a pulse voltage

is practically not visible. In this case the volume
discharge duration is defined by the time of switching
of the discharge current. The voltage pulse on the
discharge interval thus smoothly falls down up to arc
value.

Oscillograms (Fig. 2) and discharge glow pictures,
with fixed spatial (Fig. 1) and temporal (see [15,16])
resolutions, show on the one hand the dynamics of
discharge development, and on the other hand allow
us to define the duration of breakdown stages.

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vol. 55 no. 4/2015 About the Uniformity and the Stability of a Volume Discharge in Helium

Figure 4. Distributions of radiation intensity (in a.u.) both along and across electrodes (d = 1 cm, P = 1 atm):
(a) t = 105 ns; (b) t = 130 ns; (c) t = 155 ns; (d) t = 210 ns. Here x is the coordinate along a field, and y is the
coordinate across a field.

Figure 3. Dependences of the burning voltage of vol-
ume discharge on pressure: (1) E/P = 3 kV/cm atm;
(2) E/P = 3.5 kV/cm atm.

The reduction of the duration of the volume dis-
charge burning stage due to the pressure growth, is
the result of non-compensated growth of the number
of ionization processes relatively to the recombina-
tion ones. The increase in gas pressure results in
an increase of the voltage at the discharge column.
This results in the growth of ionization processes due
to the shock ionization that is caused by the strong

dependence of the factor α on E0, as well as to the
step ionization. The rough uncompensated growth of
electron concentration then results in growth of con-
ductivity and in the recession of voltage up to the arc
value. Afterwards, the discharge moves to a recombi-
nation mode and dies. The increase of the overvoltage
up to 300 % causes the appearance of a large number
of plasma channels having a rather large diameter.
The time-differentiation of volume and high-current
stages is well visible on oscillograms of the discharge
current or of the voltage on the plasma channel.
At volume stage of discharge burning the voltage

Ub =const., and this constant value depends on pres-
sure (see Fig. 3), corresponding to the minimal voltage
of the breakdown with the fixed value of Pd, where
P is gas pressure and d is interval length.

To obtain a sparkless mode we need to obtain a full
dispersion of storage element energy (C = 1.5 · 10−8 F)
for burning time τb [1]. For volume discharges in
He this requirement is reached at U0 = 2Ub, where
Ub ≈ 3000 V is the volume discharge burning volt-
age at P = 1 atm, d = 1 cm). The analysis of such
measurements shows that the spark channel in this
case is initiated by instabilities in near-electrode areas
[15,18]. These instabilities define the binding of nar-
row diffusive channels and cause the transition from a
volume discharge mode into a spark mode. Figure 4
shows the distributions of radiation intensities both

239



V. S. Kurbanismailov, O. A. Omarov, G. B. Ragimkhanov, A. A. Aliverdiev Acta Polytechnica

along the field and across electrodes. From this figure
follows that the counteraction process is defined by
near-electrodes phenomena.
On the other hand, the basic energy is entered in

the discharge in quasi-stationary stages. Then, fot
the energy density, it is possibleto write:

W =
Pτb
V

=
IUτb
Sd

=
jUτb
d

, (1)

where τb is the volume stage duration, j is the current
density.
The energy, given to the gas before the formation

of the spark channel, increases the power, although
the burning duration τb exponentially decreases with
field growth [16]. Finally, the volume discharge emits
a spark in the channel at the critical current density
j ≥ jcritical ≈ 40 A/cm2 and the extreme specific
inputs ≈ 0.1–0.2 J/cm3 [13].
In a voltage drop stage (when we have a quasi-

neutral plasma column with the cross-section area S
and electron density ne in the discharge interval) the
resistance of this column defined by

R =
U

I
=

Pd

Senek
, (2)

where µ and νdr = kEP = µE are the mobility and
the drift speed of electrons. Accordingly, k = µP =
6.72 · 105 cm2 torr/V sec [1].
For our experiment S = 12 cm2; P = 760 torr;

d = 1 cm; ne ≈ 1013–1014 cm3. The resistance ranges
from 10 to 100 Ω.

4. Conclusions
To sum up, we can observe a clear sequence of events:
(1.) the occurrence of cathode spots in an initial stage
of discharge;

(2.) the development of uncompleted anode channels;
(3.) the formation of uncompleted cathode channels;
and finally

(4.) the merging of counter channels and the growth
of their conductivity.

In conditions of strong preliminary ionization and with
a wide range of initial voltage values the discharge has
a volume structure, and the duration decreases with
the growth of the initial voltage and gas pressure. In
the case of an extreme specific heat input ≈ 0.1 J/cm3
and a critical current density jcritical ≥ 40 A/cm2, the
discharge contracts to a spark channel.
The burning voltage Ub at various values of E/P

tends to reach such value at which Ub/Pd is constant.
At the same time the ionization ability of electrons
η = α/E0 is maximal and optimal for electron multi-
plication. The relation E/P in the volume discharge
plasma does not depend on an initial voltage (for
P = 1 atm, E/P ≈ 3 · 103 V/cm atm). A volume dis-
charge voltage determined basically by gas pressure,
has a linear dependence in quite wide ranges.

Acknowledgements
The work was partially supported by RFBR (12-02-96505,
12-01-96500, 12-01-96501) and it was written within the
framework of the State task 2.3142.2011 Ministry of Sci-
ence and Education of Russian Federation for 2012–2014.

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	Acta Polytechnica 55(4):237–241, 2015
	1 Introduction
	2 Experimental installation and research methods
	3 Results and discussion
	4 Conclusions
	Acknowledgements
	References