Acta Polytechnica


Acta Polytechnica 53(2):254–258, 2013 © Czech Technical University in Prague, 2013
available online at http://ctn.cvut.cz/ap/

EMITTANCE CHARACTERIZATION OF ION BEAMS
PROVIDED BY LASER PLASMA

Luciano Velardia,b,∗, Domenico Delle Sidea,b, Massimo De Marcoa,
Vincenzo Nassisia,b

a Laboratorio di Elettronica Applicata e Strumentazione (LEAS), Dipartimento di Matematica e Fisica,
Università del Salento, Lecce, Italy

b Istituto Nazionale di Fisica Nucleare (INFN) Section of Lecce, Lecce, Italy
∗ corresponding author: luciano.velardi@le.infn.it

Abstract. Laser ion sources offer the possibility to obtain ion beams useful for particle accelerators.
Nanosecond pulsed lasers at intensities of the order of 108 W/cm2, interacting with solid matter in
a vacuum, produce plasma of high temperature and high density. To increase the ion energy, an external
post-acceleration system can be employed by means of high voltage power supplies of some tens of kV.
In this work, we characterize the ion beams provided by an LIS source and post-accelerated. We
calculated the produced charge and the emittance. Applying 60 kV of accelerating voltage and laser
irradiance of 0.1 GW/cm2 on the Cu target, we obtain 5.5 mA of output current and normalized beam
emittance of 0.2 π mm mrad. The brightness of the beams was 137 mA (π mm mrad)−2.

Keywords: LIS source, ion beam, emittance.

1. Introduction
It is known that the presence of specific doped ions can
significantly modify the chemical-physical properties
of many materials. Today many laboratories, includ-
ing LEAS, are involved in developing accelerators
of very contained dimensions, easy to install in small
laboratories and hospitals. The use of ion sources
facilitates the improvement of ion beams of moderate
energy and with good geometric qualities. They are
used for the production of innovative electronic and
optoelectronic films [7], biomedical materials [8, 16],
new radiopharmacy applications [14, 6], hadronther-
apy applications [3], and to improve the oxidation
resistance of many materials [13].
There are many methods for obtaining particle

beams; application of the pulsed laser ablation (PLA)
technique (the technique that we adopt in this work)
enables ions to be obtained solid targets, without any
previous preparation, whose energy can easily be in-
creased by post-acceleration systems [2, 12, 1]. In this
way, plasma can be generated from many materials,
including from refractory materials [9, 15].

In this work, we characterize the ion beams provided
by a laser ion source (LIS) accelerator composed of two
independent accelerating sectors, using an excimer
KrF laser to get PLA from the pure Cu target. Using
a home-made Faraday cup and a pepper pot system,
we studied the extracted charges and the geometric
quality of the beams.

2. Materials and methods
The LIS accelerator consists of a KrF excimer laser
operating in the UV range to get PLA from solid
targets, and a vacuum chamber device for expanding

the plasma plume, extracting and accelerating its ion
component. The maximum output energy of the laser
is 600 mJ. It works at 248 nm wavelength and the pulse
duration is 25 ns. The angle formed by the laser beam
with respect to the normal to the target surface is 70◦.
During our measurements, the laser spot area onto
the target surface is fixed at 0.005 cm2. The laser
beam strikes the solid targets and it generates plasma
in a expansion chamber (EC), Fig. 1.
This chamber is closed around to the target sup-

port (T) and it is put at a positive high voltage
(HV) of +40 kV. The length of the expansion cham-
ber (18 cm) is sufficient to decrease the plasma den-
sity [5]. The plasma expands inside the EC and, since
there is no electric field, breakdowns are absent.
Thanks to the plasma expansion, the charges reach
the extremity of the expansion chamber, which is
drilled with a 1.5 cm hole to allow ion extraction.
A pierced ground electrode (GE) is placed at 3 cm
distance from EC. In this way it is possible to gener-
ate an intense accelerating electric field between EC
and GE. Four capacitors of 1 nF, between EC and
ground, stabilize the accelerating voltage during fast
ion extraction.

After GE, a third electrode (TE) is placed 2 cm from
it, and it is connected to a power supply of negative
bias voltage −20 kV. It is also utilized as a Faraday
cup collector.
TE is connected to the oscilloscope by an HV ca-

pacitor (2 nF) and a voltage attenuator, ×20, in or-
der to separate the oscilloscope from the HV and
to suit the electric signal to the oscilloscope input
voltage. The value of the capacitors (4 nF) applied
to stabilize the accelerating voltage and the value

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vol. 53 no. 2/2013 Emittance Characterization of Ion Beams Provided by Laser Plasma

Figure 1. Schematic drawing of the LIS accelerator (T: Target support, EC: Expansion Chamber, GE: Ground
Electrode, R: Radiochromic, TE: Third Electrode).

of the capacitors (2 nF) used to separate the oscillo-
scope from the HV are calculated assuming a storage
charge higher that the extracted one. Under this con-
dition, the accelerating voltages during charge extrac-
tion are constant and the oscilloscope is able to record
the real signal.

TE is not able to support the suppressing electrode
on the cup collector, and secondary electron emission,
caused by high ion energy, is therefore present. In this
configuration, we are aware that the output current
values are about 20 % higher than the real values [11].

3. Results and discussion
The value of the laser irradiance used to produce
the ion beams was 1.0 × 108 W cm−2 and the ablated
target was a pure (99.99 %) disk of Cu.

Figure 2 shows the time of flight (TOF) spectra ob-
tained at 60, 40 and 30 kV of total accelerating voltage
from the Cu target, detecting the ion emission with
the Faraday cup placed 23 cm from the target. The ver-
tical axis represents the output current. The maxi-
mum output current is reached applying 40 and 20 kV,
respectively, on the first gap (EC–GE) and on the
second gap (GE–TE).

The space charge effects are more evident at the low-
est accelerating voltage applied on the first gap, al-
though they are present anyway. So, considering only
the TOF curves out of the charge domination effects,
we obtain the behaviour of the accelerated charge
with respect to the accelerating voltage. From these
results, we can observe the absence of a saturation
phase. In fact the curves in Fig. 3 have a growing
trend with respect to the applied voltage. The growing
trend on the first gap voltage is larger than the one de-
pendent on the second gap voltage. Theoretically, we
can expect to observe a constant trend for the curves,
dependent principally on the voltages of the second
acceleration gap, because the charge is already ex-
tracted and its value should be constant. We can as-

Figure 2. Waveforms of the output current at dif-
ferent accelerating voltages for a Cu target; laser ir-
radiance: 0.1 GW cm−2.

cribe this behaviour toi the secondary emission of elec-
trons from the cup collector, because we are not able
to prevent this emission, owing to the absence of a sup-
pressing electrode on the Faraday cup. So we expect
that the real charge must be increased by about 20 %
for the used voltage values.

Fixing the voltage at 20 kV in the second gap, the ex-
traction current increased with the change of the volt-
age applied on first gap, reaching 150 % at the max-
imum voltage of 40 kV with respect to the value ob-
tained at 0 kV. This result implies strong dependence
of the extraction efficiency on the first stage voltage.
In effect, simulations results preformed in previous
works, have shown, tha the electric field strenght near
the EC hole increased with respect to the applied
voltage. This fact can enlarge the extracting vol-
ume inside the anode, and as a consequence, the ex-
traction efficiency. The Cu target at zero voltage
produced ion beams containing 1.2 × 1011 ions/pulse
(0.7 × 1011 ions cm−2). Instead, applying accelerat-
ing voltages of 40 and 20 kV in the first and sec-

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Luciano Velardi et al. Acta Polytechnica

Figure 3. Output charge on accelerating voltages
for the Cu target; laser irradiance: 0.1 GW cm−2.

ond accelerating gap, respectively, we obtained an in-
crease of the ion dose up to 3.4 × 1011 ions/pulse,
(2 × 1011 ions cm−2).

For a geometric characterization of the beam, we
performed emittance measurements by the pepper pot
technique. We can assume the propagation direction
of the beam along the z axis. So the x-plane emittance
x is 1/π times the area Ax in the xx′ trace plane (TPx)
occupied by the points representing the beam particles
at a given value of z, namely

εx =
Ax
π
. (1)

In the phase plane (PPx), the area of the particle
is defined as [11]

A0x =
∫ ∫

f 02 6=0
dx dpx = m0cβγ Ax, (2)

where f02 is the distribution function of the particles,
m0 is the rest mass of the particles, β = v/c and
γ = 1/(1 − β2)1/2.

Actually, it is necessary to define an invariant quan-
tity of the motion called normalized emittance εnx
in the TPx. Therefore, by Liouville’s theorem, it is
known that the area occupied by the particle beam
in PPx is an invariant quantity and the normalised
emittance can assume the form

εnx = βγεx. (3)

Figure 4 shows a sketch of the system used to mea-
sure the emittance value.

The mask we used has 5 holes of 1 mm in diameter,
and it was fixed on the GE. One hole is in the centre
of the mask and 4 holes are at 3.5 mm from the cen-
tre. We used Gafchromic EBT radiochromic films (R)
as photo-sensible screen, placed on the TE.
Radiochromic detectors take advantage of the di-

rect impression of a material by the absorption of en-
ergetic radiation, without requiring latent chemical,

optical, or thermal development or amplification. A ra-
diochromic film changes its optical density as a func-
tion of the absorbed dose. This property, and the rel-
ative ease of use, led to the adoption these detectors
as simple ion beam transverse properties diagnostic
tools.
So, the ion beam after the mask imprinted the ra-

diochromic film and then it was possible to measure
the divergence of all beamlets. The divergence values
allowed us to determine the beam area Ax in TPx.
We applied 250 laser shots to imprint the radiochromic
films.
We measured the emittance for different accelerat-

ing voltage values. We fixed the accelerating voltage
of the second gap at 20 kV, while the accelerating
voltage of the first gap was put at 10, 20 and 40 kV.
So, the obtained values of the area in the TPx resulted
in 613, 545 and 435 mm mrad for 30, 40 and 60 kV
of total accelerating field, respectively (Fig. 5).
Considering Eq. 3, we found the normalized emit-

tance values. For all the applied voltage values,
the normalized emittance resulted constant:
εnx = 0.2 π mm mrad.

Therefore, to estimate the total properties of the de-
livered beams, it is necessary to introduce the concept
of brightness. Brightness is the ratio between the cur-
rent and the emittance along the x- and the y-axis.
Generally assuming x equal to y, the normalised
brightness becomes

Bn =
I

ε2nx
. (4)

By Eq. 4, at the current peak (5.5 mA), the bright-
ness values resulted in 137 mA (π mm mrad)−2
at 60 kV of accelerating voltage.
Due to low emittance and high current, this ap-

paratus is very promising for use for feeding large
accelerators. The challenge of the moment is to get
accelerators with dimensions so small that can be
easily deployed in small laboratories and hospitals.

4. Conclusions
Post-acceleration of ions emitted from laser-generated
plasma can be developed to obtain small and com-
pact accelerating machines. The output current can
easily increase on accelerating voltage. The applied
voltage can cause breakdowns, and for this reason
the design of the chamber is very important (primar-
ily its dimensions and morphology). We have also
shown that two gaps of acceleration can efficiently
increase the ion energy. By increasing the voltage
of the first accelerating gap, we substantially increased
the efficiency of the extracted current due to the rise
of the electric field and the extracting volume inside
the EC. The charge extracted without the electric
fields was 0.7 × 1011 ions/cm2. At the maximum ac-
celerating voltage the ion dose was 2 × 1011 ions/cm2,
and the corresponding peak current was 5.5 mA. We

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Figure 4. Sketch of the pepper pot system used to measure the emittance.

Figure 5. Emittance diagram in the trace plane for different accelerating voltage values.

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Luciano Velardi et al. Acta Polytechnica

measured the geometric characteristics of the beam
utilising the pepper pot method. We found a low
value for the normalized emittance of our beams,
εnx = 0.2 π mm mrad. The resulting brightness values
were therefore 137 mA (π mm mrad)−2.

This study has demonstrated that our apparatus
can produce ion beams of good quality, e.g. with a low
emmitance value and high current. For this reason it
is very promising for use in feeding large accelerators.

Acknowledgements
The work was supported by the Fifth National Committee
of INFN in the LILIA experiment.

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	Acta Polytechnica 53(2):254–258, 2013
	1 Introduction
	2 Materials and methods
	3 Results and discussion
	4 Conclusions
	Acknowledgements
	References