Acta Polytechnica


Acta Polytechnica 53(2):241–245, 2013 © Czech Technical University in Prague, 2013
available online at http://ctn.cvut.cz/ap/

NUCLEAR FUSION EFFECTS INDUCED IN INTENSE
LASER-GENERATED PLASMAS

Lorenzo Torrisia,b,∗, Salvatore Cavallarob, Mariapompea Cutroneoa,c,
Josef Krasad

a Department of Physics, University of Messina, Messina, Italy
b INFN — Laboratori Nazionali del Sud, Catania, Italia
c CSFNSM — Centro Siciliano di Fisica Nucleare e Struttura della Materia, Catania, Italy
d Institute of Physics, ASCR — PALS Lab, Prague, Czech Republic
∗ corresponding author: lorenzo.torrisi@unime.it

Abstract. Deutered polyethylene (CD2)n thin and thick targets were irradiated in high vacuum
by infrared laser pulses at 1015 W/cm2 intensity. The high laser energy transferred to the polymer
generates plasma, expanding in vacuum at supersonic velocity, accelerating hydrogen and carbon
ions. Deuterium ions at kinetic energies above 4 MeV have been measured by using ion collectors
and SiC detectors in time-of-flight configuration. At these energies the deuterium–deuterium colli-
sions may induce over threshold fusion effects, in agreement with the high D−D cross-section values
around 3 MeV energy.

At the first instants of the plasma generation, during which high temperature, density and ion
acceleration occur, the D−D fusions occur as confirmed by the detection of mono-energetic protons
and neutrons with a kinetic energy of 3.0 MeV and 2.5 MeV, respectively, produced by the nuclear reaction.
The number of fusion events depends strongly on the experimental set-up, i.e. on the laser parameters
(intensity, wavelength, focal spot dimension), target conditions (thickness, chemical composition,
absorption coefficient, presence of secondary targets) and used geometry (incidence angle, laser spot,
secondary target positions).

A number of D−D fusion events of the order of 106÷7 per laser shot has been measured.

Keywords: D−D fusion, plasma laser, D−D cross section, proton detection, neutron detection.

1. Introduction
The nuclear reactions between two nuclei of deuterons
are generally accepted as playing crucial roles in re-
cent observed nuclear processes and significant heat
production in condensed matter. Independent mea-
surements of the cross sections for these nuclear re-
actions have an important role and determine signif-
icant heat production from D−D nuclear reactions.
By considering the possibility to achieve the D−D re-
action through the injection into the plasma of deu-
terium ions, if results that the number of fusion events
caused by the beam deuterons is too low to compen-
sate for the energy expended on creating the plasma
and the high energy ion beam, remains the possi-
bility of increasing the efficiency of the D−D reac-
tion. This can be done by using, directly or indirectly,
the neutrons released in the D−D reaction [5].
As is well-known, in a deuterium plasma

the D−D reaction can proceed along two paths having
the same probability:

D+D → (T + 1.01 MeV) + (p + 3.03 MeV), (1)
D+D → (3He + 0.82 MeV) + (n + 2.45 MeV). (2)

Intense pulsed lasers can be employed in the field
of nuclear fusion in different ways, such as to in-

crease the plasma temperature, to increase the elec-
tron density of the plasma, to ignite of fusion processes,
or to accelerate ions inside the plasma. This is the rea-
son why different lasers with different pulse durations,
wavelengths, focalization methods and pulse energy
can be utilized.
In our experiment a laser intensity of about

1015 W/cm2 is used to irradiate in vacuum a deutered
target producing a plasma from which deuterons
are accelerated at energies above 3 MeV, as recently
demonstrated [7]. These ions induce D−D nuclear
fusion in the same target and in secondary targets,
from which monochromatic protons and neutrons are
generated.

2. Material and Methods
The iodine laser at Prague PALS laboratory was em-
ployed for the experiment; it provides 300 ps pulses
at 1315 nm wavelength, 70 µm focused spot diameter
and an energy of 500 J [3]. This laser has been used
to irradiate thick and thin targets at normal incidence
in high vacuum (10−6 mbar). Deutered polyethylene,
(CD2)n, was used as thick (5 mm) and thin (5 µm)
targets. The primary target irradiated by laser was
a porous polymer acting as high absorbent laser radi-

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Lorenzo Torrisi et al. Acta Polytechnica

Figure 1. Sketch of the experimental set up.

ation; the secondary targets were three CD2 polymers
at high density and flat surface (each 1 cm radius).
These secondary targets were placed at different dis-
tances and angles from the primary target, so as re-
ported in the sketch of Fig. 1.

A SiC detector, a semiconductor with a 3.2 eV ener-
getic gap, was fixed in forward direction, at 150◦ angle
with respect to the incidence direction and at a dis-
tance of 102 cm, from primary target and at 115 cm,
127 cm and 141 cm from first, second and third sec-
ondary targets, respectively. It permits to detect ions
with a low background signal due to its not-absorbent
visible light emitted from plasma. Thus protons
and deuterium ions emitted from primary and sec-
ondary targets, can be detected and their kinetic
energy measured. SiC was employed in time-of-flight
(TOF) configuration; its signal was acquired through
a fast storage oscilloscope (20 GS/s) in order to mea-
sure the TOF of arriving ions and the corresponding
kinetic energy of the produced protons, as in previous
experiments [4].
A plastic scintillator NE102A has been used cou-

pling it with a fast photomultiplier and a stor-
age oscilloscope to detect MeV neutrons produced
by the D−D neutron branch. The scintillator, having
a density of 1.032 g/cm3, provides a fast response
to gamma and neutrons, thanks to its 2.4 ns decay
time and high detection efficiency (light output 65 %
with respect to antracene medium). The scintillator
was placed at a distance of 200 cm from the primary
target and 216 cm, 238 cm and 242 cm from the first,
second and third secondary targets, respectively.
Its use was dedicated mainly to neutron energy mea-
surements through TOF approach.
A Thomson parabola (TP) spectrometer is fixed

along the normal direction to the target surface
at about 2 m distance from the target. TP analyzes
the plasma ion emission produced by thin targets
(∼ 1 µm in thickness) that is transimmetted by a nar-
row collimation constituted by two pinholes, the first
1 mm and the second 100 µm in diameter, respectively.
A magnetic field of 0.2 T and an electric field of 3 kV
are provided in order to produce the ions deflection.

Figure 2. D−D cross section as a function of the
deuterium energy.

The electric field is placed after the magnetic one it
is realized using two parallel plates 8 cm long and
1 cm apart. The distance between the electric deflec-
tor plates and the shield containing the micro-channel
plates (MCP) detector for the parabolas recording
is 16.5 cm. A CCD camera, in remote control, cap-
tures, at high spatial resolution, the parabola images
shown by MCP. OPERA-3D/TOSCA code [1] allows
to simulate the ion trajectories starting from magne-
tostatic and electrostatic forces acting in the TP spec-
trometer so that simulation data can be compared
with the experimental ones in order to have informa-
tion about the charge/mass, charge states and ion
kinetic energies.

3. Results
The D−D cross sections as a function of the deuterium
energy, which permits to calculate the number of fu-
sion events generating monocromatic protons and neu-
tron branches carried out to calculate the number
of monochromatic protons and neutrons, is reported
in Fig. 2. The maximum cross section of 0.2 barns
is obtained at 3.0 MeV incident deuterons.

The deuteron energy acquired in the laser-generated
plasma has been measured by irradiating thick
and thin CD2i targets at normal incidence angle.

Figure 3 shows a typical example of SiC-TOF spec-
trum at 150◦ detection angle in forward direction
obtained from a plasma generated by 5 µm deutered
polyethylene target.
The SiC detector spectrum, placed at 102 cm dis-

tance from the target shows a narrow photopeak
due to photons coming from plasma (start signal)
and a narrow minor peak coming from electron
Bremsstrahlung at about 10 ns.
Moreover, a structured and larger peak, due

to the detection of fast and slower ions, extends

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Figure 3. Typical example of SiC-TOF spectrum
produced by the ions emitted from plasma generated
in forward direction by 5 µm deutered polyethylene
irradiated target; deuterium peak loceted at a TOF
of 55 ns has an energy of 3.5 MeV.

Figure 4. Typical TPS spectrum (a) and compari-
son with simulation data (b) reporting the parabolas
for protons, deuterium carbon and contaminant oxy-
gen ions; the maximum energy of 3.0 MeV and 3.5 MeV
is evaluated for protons and deuterium respectively.

in times higher than 60 ns. The front peak, located
at 55 ns, is due to fast deuterons detected at a kinetic
energy of 3.5 MeV.

The deuteron energy measurement is confirmed also
by TP analysis, for forward ion emission. A typical TP
spectrum is reported in Fig. 4a together with the sim-
ulated plot (a) which permits the ion parabola recog-
nition. It shows the parabolas relative to the detected
ion species, charge states and kinetic energies coming
from a laser irradiated thin deutered polyethylene foil.

The spectrum features protons, the six charge states
of carbon ions, the deuterium parabola overlapped

Figure 5. Typical TOF neutron spectrum obtained
by the plastic scintillator reporting peaks at 2.5 MeV
neutrons coming from the secondary targets.

with C+6 parabola and the presence of oxygen con-
taminant ions. The maximum ion energy, measurable
fron the distance between the center of the circle
point (due to X-ray MCP detection) and the initial
point of the parabola line, is 3.0 MeV and 3.5 MeV
for protons and deuterium, respectively. The maxi-
mum energy for the carbon ions is of about 0.5 MeV
per charge state.
The detection of protons and neutrons

with the characteristic energy of 3.0 MeV
and 2.45 MeV, respectively, was obtained by irradi-
ating thick deutered polyethylene and by observing
the SiC and the plastic scintillator spectra showing
signals coming from the generation of protons
and neutrons from the nuclear events. The scintillator
spectrum relative to the neutrons detection is reported
in Fig. 5. It shows a fast and very high photopeak,
due to electron Bremsstrahlung in the primary target,
followed by three lower peaks at different TOF times
all corresponding to the 2.45 MeV neutrons emitted
from the three secondary targets.
The fusion reaction yield, in terms of the number

of fusion per incident D+ ion produced along the ion
track in the target, as a function of depth is given by

Y (x) dx = ΦxND σ(E(x)) dx, (3)

where Y (x) is the probability that a fusion will oc-
cur per unit length, Φx is the ion current, ND is
the density of deuterium atoms in the target,
σ(E(x)) is the D−D fusion cross section as a func-
tion of the deuteron energy and dx is the distance
along the deuteron track. The deuterium ions acceler-
ated by the plasma penetrate in the CD2 secondary
target matter up to the range depth of the ener-
getic particles. This can be calculated through SRIM
code [8] that gives the energy loss per unit length
in the target material dE(x)/dx as a function of the
depth. These data can be used to calculate the D+ ion
energy as a function of the depth travelled in the target
as

E(x) = E0 −
∫ R

0

dE
dx

dx (4)

where E0 is the initial accelerating energy assumed
to be 3.5 MeV.

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Lorenzo Torrisi et al. Acta Polytechnica

Figure 6. Plot of the deuterium energy (a) and of the
D−D cross section (b) versus the polyethylene depth
for 3.5 MeV D+ ions impacting a CD2 substrate.

Figure 6a reports the graph of deuterium energy
versus the polyethylene depth for 3.5 MeV D+ ions im-
pacting a CD2 substrate. The range is about 135 µm.
The total D−D cross section as a function

of the depth can be calculated integrating the val-
ues over the deuterium ion range in the deutered
polyethylene target through the equation

σT =
∫ R

0
σ(E(x) dx. (5)

Equation 5 can be plotted as a function
of the polyethylene depth, as represented in Fig. 6b,
demonstrating that the cross section maintains
its maximum value within the first 120 µm of surface
layers.
The density of deuterium atoms can be calculated

from the equation

ND = 2ρNA/M , (6)

where ρ is the polyethylene density, NA the Avogadro’s
number and M the CD2 mass. The factor 2 is due
to the presence of two deuterium atoms per carbon.

The total number of fusion processes can be calcu-
lated as

NF =
∫ R

0
Y (x)dx = ΦxNDσT. (7)

Thus, in order to evaluate NF, three parameters
must be known. The first parameter is the deuterium

ion current, Φx, produced by the plasma developed
from the primary target. IC measurements of ion
currents from polyethylene laser irradiation have in-
dicated that a total current of the order of 10 mA
can be produced at time of the order of 10 µs. As-
suming the mean charge state to be 2+ (carbon
is present with charge states from 1+ up to 6+
but the lower charge states are more intense with re-
spect to the higher ones) and that the deuterium ions
represent only the 30 % of the total ions in the plasma,
a current of about Φx ' 1011 D+ ions per laser shot
can be estimated.
The evaluation of the second parameter concerns

the target density: assuming the CD2 polymer
to have a density of 0.98 g cm−3, the atomic den-
sity is ND = 7.4 × 1022 cm−3. Thus the deu-
terium atoms, for 120 µm deuterium range, correspond
to 8.9 × 1020 cm−2. The surface of the three sec-
ondary targets irradiated by the primary deuterons
is about 9.4 cm2, thus a total irradiation of about
8.4 × 1021 atoms is possible.
The third parameter is the D−D cross section

which is about constant to σT = 0.018 × 10−24 cm2
in the first 120 µm depth, where the kinetic energy
ranges between 3.5 MeV and about 1 MeV. These ap-
proximations permit to evaluate a total number of fu-
sion processes NF of about 1.5 × 107 per laser shot.
A value comparable to other similar experiments per-
formed with a laser-generated plasma [6, 2].

4. Conclusions
The measurements have determined, with an accuracy
of the order of 15 %, the detection of 3.0 MeV protons
and 2.5 MeV neutrons coming from the secondary tar-
gets irradiated by MeV deuterons accelerated by laser-
generated plasma.
Proton detection occurs togheter fast deuterium

ions, while neutron spectra show the coexistence
of gamma-rays, as a consequence of the elec-
tron Bremsstrahlung. The preliminary evaluation
of the number of fusion events per laser shot is of
the order of 107. Further nuclear fusion events may oc-
cur in the primary target due to D−D collisions gener-
ated in plasma and increase the yield of monoenergetic
protons and neutrons. Therefore the fusion event pro-
duces an energy emission of 3.27 MeV for the neutron
production channel and of 4.03 MeV per the proton
emission channel, the total number of events occurring
in the three secondary targets corresponds to a nu-
clear energy generation of the order of 10 µJ per laser
shot. Thus the laser energy conversion in nuclear
event is low, considering that the used laser pulse
is of about 500 J, and further investigations should be
performed in order to increase this conversion factor.
The presented results highlight the importance

of the laser induction of nuclear fusion events to de-
velop nuclear energy without generation of dangerous
radioactive species.

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	Acta Polytechnica 53(2):241–245, 2013
	1 Introduction
	2 Material and Methods
	3 Results
	4 Conclusions
	References