Acta Polytechnica


doi:10.14311/AP.2015.55.0150
Acta Polytechnica 55(3):150–153, 2015 © Czech Technical University in Prague, 2015

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

POLYMERS CONTAINING Cu NANOPARTICLES IRRADIATED
BY LASER TO ENHANCE THE ION ACCELERATION

Mariapompea Cutroneoa, ∗, Lorenzo Torrisib, Anna Mackovaa, c,
Andriy Velyhand

a Nuclear Physics Institute, ASCR, 25068 Rez, Czech Republic
b Physics Department and of Earth Sciences, Messina University, V.le F.S. d’Alcontres 31, 98166 S. Agata,

Messina, Italy
c Department of Physics, Faculty of Science, J.E. Purkinje University, Ceske mladeze 8, 400 96 Usti nad Labem,

Czech Republic
d Institute of Physics, ASCR, v.v.i., 182 21 Prague 8, Czech Republic
∗ corresponding author: cutroneo@ujf.cas.cz

Abstract. The Target Normal Sheath Acceleration method was employed at PALS to accelerate ions
from laser-generated plasma at intensities above 1015 W/cm2. Laser parameters, irradiation conditions,
and target geometry and composition control the plasma properties and the electric field driving the ion
acceleration. Cu nanoparticles deposited on the polymer promote resonant absorption effects, increasing
the plasma electron density and enhancing the proton acceleration. Protons can be accelerated in the
forward direction at kinetic energies up to about 3.5 MeV. The optimal target thickness, the maximum
acceleration energy and the angular distribution of the emitted particles were measured using ion
collectors, an X-ray CCD streak camera, SiC detectors and a Thomson Parabola Spectrometer.

Keywords: TNSA, hydrogenated target, resonant absorption.

1. Introduction
In a laser-matter interaction, the electromagnetic en-
ergy of the laser radiation is converted initially into
electronic excitation and later into thermal, chemical
and kinetic energy [1]. The characteristics of the laser-
generated plasma, the amount of emitted ions and
their distribution into energy, charge states and angle
emission depend on many important factors. The
propagation of the ions in forward direction and in
backward direction, for example, is tied to the thick-
ness of the target [2]. The focal position and the laser
pulse duration have a crucial role on the characteris-
tics of the generated plasma [3]. The laser intensity
is the main factor influencing the ion distribution of
the energy and the charge state [4]. The mechanisms
for ion generation, acceleration and expansion in a
vacuum, are complex. Above the ablation thresh-
old, and at laser intensity higher than 1015 W/cm2,
plasma may be full ionized, and non-linear effects,
ponderomotive forces, relativistic electrons and mag-
netic self-focusing effects promote high charge states
and accelerate the emitted ions [5]. Using the target
normal sheath acceleration (TNSA) regime, in which
a double layer of charges generated in the rear side of
the foil drives the ion acceleration in the forward di-
rection, along the normal to the target surface, charge
states may reach 60+ and ion acceleration values may
be higher than 1 MeV per charge state [6]. A plasma
rich in protons, carbon and copper ions can be ob-
tained by irradiating thin polyethylene foils covered
by Cu films or containing Cu nanostructures. The

composition and the geometry of the target absorb
high laser energy and generate hot plasmas and high
charge separation, inducing high ion acceleration, as
will be reported. In this context, investigations into
optimal laser parameters and irradiation conditions
will be aimed at maximizing the ion kinetic energy.

2. Material and Methods
The high-power photodissociation iodine laser system
of the PALS Research Center in Prague, operating
at 1.315 µm wavelength, laser energy ranging between
450 and 600 J, pulse duration 300 ps, and intensity of
1015 W/cm2, was employed for the experiments pre-
sented here [7]. The focalization setting of the laser
beam consists in an aspherical lens (f = 627 mm for
1 ω) 29 cm in diameter focusing the laser beam on
to the target with a nominal spot of 70 µm. Sheets
of pure Mylar, pure Copper, and Mylar covered by
thin Cu films were irradiated at 30° with respect the
normal to the target surface. The original stoichiom-
etry of the Mylar or polyethylene terephthalate is
(C10H8O4)n. The thickness of the mylar ranges be-
tween 0.6 µm and 100 µm, and the thickness of the
Cu film ranges between 0.01 µm and 1 µm. The tar-
gets were produced by the physical vapor deposition
(PVD) method, using a Leybold-Heraeus evapora-
tor, at a vacuum of 10−6 mbar. A mylar substrate,
0.6 µm in thickness was covered by the evaporated Cu
thin film, the thickness of which was measured online,
with a calibrated quartz crystal, and offline, using the
transmission energy loss spectroscopy of the 241Am

150

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vol. 55 no. 3/2015 Polymers Containing Cu Nanoparticles

Figure 1. Experimental setup.

alpha source. At very low thicknesses, of the order of
5–10 nm, the Cu film is not uniform; it consists of nu-
cleated Cu cluster with dimensions comparable with
the thickness, as observed at SEM. The laser beam
was focused 100 microns in front of the the target
surface (FP = −100 µm) [8]. The scattering chamber
is equipped with a target holder movable in x, y, z di-
rections with 1 µm minimum steps [7]. A KENTECH
X-ray streak camera, fixed in a side view having 2 ns
exposition time, is employed to monitor the initial
position of the plasma formation. Ion collectors (IC)
and SiC semiconductors are employed in time-of-flight
(TOF) configuration for the ion detection at an angle
of 30° and at a distance of 1.03 and 0.6 m from the
target [9]. SiC is a promising detector not sensitive
to the visible, soft UV, and infrared light, where op-
tical photons are not able to produce electron-hole
pairs because their energies are below the 3.2 eV of
the 4H-SiC gap energy. The photons, electrons and
ions absorbed in the sensitive volume of the detector
generate e-h pairs, losing 7.8 eV for a pair production,
which results in voltage signal at the device electrodes
proportional to the deposited radiation energy [10]. A
Thomson Parabola Spectrometer (TPS) was placed
in forward direction at 0° angle and 1.67 m distance
from the target [11].

TPS consists in a magnetic-electrostatic system; it is
equipped with two input pin-holes, 1 mm and 0.1 mm
in diameter. The emitted ions undergo a magnetic
deflection of about 0.1 T and an electrostatic deflection
voltage of the order of 3 kV. The trajectories of the
emerging are parabolic. They are detected on a plane
orthogonal to the incident ions by a Multi-Channel

Figure 2. SiC spectra for irradiation of pure mylar
(a) and of irradiation of mylar covered with a layer of
Cu 10 nm in thickness (b), 50 nm in thickness (c) and
100 nm in thickness (d).

Plate (MCP) coupled to a phosphorus screen and a
CCD camera. the recorded spectra were stored into a
fast oscilloscope operating at 20 GS/s. A schematic
view of the experimental arrangement is shown in
Fig. 1.

3. Results and Discussion
The SiC spectra of ions accelerated by a laser irradiat-
ing mylar and Cu are presented in Fig. 2. Irradiating
a pure mylar thin film, 8 µm in thickness, with 471 J
pulse energy and −100 µm focal position, the kinetic
energy of faster protons is 0.9 MeV (a). Due to the
conditions of the focal position, this relatively high
proton energy is controlled accurately by the streak
camera. At the value used here, self-focusing may
be induced, decreasing the laser spot on the target
and increasing the laser intensity [4]. However the
laser energy released in the thin mylar remains low
because the pure mylar has a very low absorption
coefficient for the IR laser wavelength that is used,
with evaluated transmission of the order of 90 % [12].
Using the same experimental condition, in a pure Cu
target, 1 µm in thickness, the maximum proton energy
was evaluated to be 1.2 MeV. The proton energy in-
creases with the Cu deposition thickness, from 10 nm
(b) to 50 nm (c) and to 100 nm (d), and assume an en-
ergy of 1.1 MeV, 3.2 MeV and 1.5 MeV, respectively, as
demonstrated by the TOF measurements of the four
spectra. This result is due to two causes: enhance-
ment of the plasma electron density responsible for
the electric field driving the proton acceleration, and
enhancement of the laser absorption in the thin target
obtained using the Cu metal. The optimal Cu thick-
ness seems to be 50 nm according to the replicability
of the measurements under the same experimental
conditions. C ions are accelerated to maximum ki-
netic energies approximately proportional to six times
the maximum proton energy, in agreement with the
Coulomb acceleration in the charge space separation
generated in the rear side of the thin target.

151



M. Cutroneo, L. Torrisi, A. Mackova, A. Velyhan Acta Polytechnica

Figure 3. TPS spectra for irradiation of pure mylar
(a) and of mylar covered with a Cu thickness of 10 nm
(b), 50 nm (c) and 100 nm (d).

Thus, in the case of a 50 nm Cu/mylar target, the
carbons are accelerated up to about 20 MeV, due to the
six charge states of carbon ions. The corresponding
TPS spectra of the targets irradiated in the condi-
tions reported for Fig. 2 are presented in Fig. 3. This
figure compares the TPS protons and carbon parabo-
las achieved by irradiating a pure mylar (a) and the
parabolas obtained when we increase the thickness
of the Cu film deposited on mylar, from 10 nm (b)
to 50 nm (c) and to 100 nm (d). The parabola recog-
nition was obtained for comparison with simulation
programs based on the real TPS geometry and used
value of deflecting magnetic and electric fields used
here, as presented in literature [11]. Recognition of
the Cu parabolas permits full Cu ionization, up to
Cu+29, to be evinced.

For the pure mylar foil the parabola luminosity de-
creases, as a consequence of the lower plasma electron
density and the lower absorbed laser energy in the
polymeric film, which absorbs only about 10 % of the
laser pulse energy [12]. The parabolas obtained in
the other cases shows more energetic ions and may be
more luminous. The most energetic ions, less deflected
by the magnetic and electric fields, are produced for
a Cu thickness of 50 nm deposited on the mylar sub-
strate, in agreement with measurements obtained by
SiC. Such a thin film produces high laser absorption
due to the presence of the metal which absorbs the IR
laser radiation and also due to the Cu nanoparticles in
which surface plasmon resonant absorption effects are
induced by the laser electromagnetic wave [13]. Thus
laser absorption enhancement is induced in the target
and transferred to the plasma, the Cu thin film in-
creases the plasma electron density and consequently
the charge separation developed in the rear side of
the target and higher ion acceleration is developed.
The Cu nanoparticle absorption plays an important
role in laser absorption in the thin mylar target, de-
pending on the size of the Cu nanoparticles, which is

Target Thickness El (J) Ep(H+)
Mylar 8 µm 471 0.9 MeV
Cu/Mylar 10 nm/8 µm 500 1.0 MeV
Cu/Mylar 50 nm/8 µm 495 3.2 MeV
Cu/Mylar 100 nm/8 µm 486 1.5 MeV
Mylar/Cu 8 µm/100 nm 472 1.1 MeV
Cu 1 µm 608 1.2 MeV

Table 1. Summary of results of proton acceleration
obtained irradiating different thin films.

very high for particles with dimensions of the order
of hundreds nm absorbing in the range of visible and
IR wavelengths.

4. Conclusions
Bilayer targets, consisting of milar foil 8 µm in
thickness covered with thin Cu PVD depositions,
with thicknesses ranging between 10 nm and 100 nm,
are suitable for high energy proton acceleration in
the forward direction from laser intensity of about
1015 W/cm2 in the TNSA regime.

A summary of our results is given in the Table 1,
demonstrating that the Cu nanostructures increase
the proton acceleration as result of the enhanced laser
absorption in the thin film. Mylar covered by Cu was
laser irradiated from the Cu face. Irradiating on the
converse face, from mylar to Cu, the maximum proton
energy decreases with respect to the value obtained
when irradiating from the Cu face, as presented in the
table. A possible explanation involves the plasma elec-
tron density which is higher in the case of Cu/mylar
irradiation due to high Cu electron injection in the
Mylar plasma. In conclusion three main parameters
play an important role in ion acceleration in the for-
ward direction from the TNSA regime: (1) the plasma
electron density, which can be increased using metals
to cover the polymer filmsthat inject the electrons into
the polymer plasma; (2) the use of metallic nanos-
tructures depsited on the polymer, which significantly
increase the laser absorption due to surface plasmon
resonance effects at wavelength in the visible and IR
regions; (3) the use of an optimal laser focal posi-
tion to induce self-focusing effect in thin films. For
polymers a distance of −100 µm in front of the target
surface is used. This enables the laser light due to
the formation of the first ionized vapor to be focused,
and enables the self-focusing effect to be made use of.

Acknowledgements
The authors acknowledge the PALS laser team for its ex-
pert support for this experiment and Mr C. Cutroneo and
Mrs M. D’Amico for their precious contribution. Access
to the PALS laser facility was supported by the Euro-
pean Commission under LASERLAB-Europe by project
pals001823 and by project P108/12/G108.

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	Acta Polytechnica 55(3):150–153, 2015
	1 Introduction
	2 Material and Methods
	3 Results and Discussion
	4 Conclusions
	Acknowledgements
	References