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Title: Nonlinear interaction of intense laser beams with magnetized plasma


1
Nonlinear interaction of intense laser beams with
magnetized plasma
Rohit Kumar Mishra
Department of Physics, University of Lucknow
Lucknow 226 007
2
  • Interaction of intense lasers with plasma
    involves a number of interesting nonlinear
    physical phenomenon including self-focusing,
    wakefield generation and quasi-static magnetic
    field generation.
  • Experiments report that quasi-static magnetic
    fields (both axial and azimuthal) of the order of
    MG are generated when intense laser beams
    interact with underdense plasma.
  • These fields affect the propagation
    characteristics of the laser pulses and hence
    play vital role in fast ignition schemes of
    inertial confinement fusion, charged particle
    acceleration and harmonic generation.

3
  • In the present thesis a theoretical analysis of
    intense laser plasma interaction , in the
    presence of a uniform magnetic field has been
    presented.
  • The effect of magnetic field on
  • (a) self-focusing property,
  • (b) modulation instability
  • and
  • (c) possible generation of second harmonic
    frequencies
  • have been shown.

4
Self-focusing of intense laser beams propagating
in magnetized plasma
  • For a laser beam having Gaussian radial profile,
    the intensity is peaked on axis
    causing the plasma electrons to be expelled away
    from the axis. Therefore, the refractive index
    tends to maximize along the axis . Due to this
    refractive index gradient the phase velocity of
    the laser wavefront increases with the radial
    distance, causing the wavefronts to curve inwards
    and the laser beam to converge

5
(a) Linearly polarized laser beam propagating in
transversely magnetized plasma
  • Consider a linearly polarized laser pulse
    propagating in a uniform plasma embedded in a
    constant external magnetic field

Amplitude
Wave number
Frequency
  • Basic equations describing the evolution of
    laser beam in magnetized plasma are
  • Wave equation

Jha et al Phys. Plas. 13, 103102 (2006)
6
  • Current density equation
  • Lorentz force equation

and
  • Continuity equation

is the relativistic factor and is the
magnetic vector of the radiation
field.
Jha et al Phys. Plas. 13, 103102 (2006)
7
  • Using perturbative technique all quantities are
    simultaneously expanded in orders of the
    radiation field. Using Eq. (4) first order
    velocities are given by
  • is the cyclotron frequency
    and is the normalized
    field amplitude.
  • Presence of magnetic field increases the
    transverse quiver velocity of plasma electrons
    and also leads to the generation of a
    longitudinal velocity component due to
    force acting on plasma electrons.

Jha et al Phys. Plas. 13, 103102 (2006)
8
  • Second and third order velocities are
  • The second order high frequency x-component of
    velocity is generated due to uniform magnetic
    field and reduces to zero in its absence. However
    z- component and third order tranverse velocities
    are modified due to external magnetic field.

Jha et al Phys. Plas. 13, 103102 (2006)
9
  • Density perturbations introduced in the plasma
    due to interaction with the laser beam can be
    obtained by expanding the continuity Eq. (5).
    Thus first order density perturbation is given by
  • The first order density perturbation arises due
    to the presence of external magnetic field and
    reduces to zero in its absence. The second order
    density perturbation is given by

Jha et al Phys. Plas. 13, 103102 (2006)
10
  • Perturbed velocities and densities are used to
    obtain the transverse current density Eq. (3).

Nonlinear current density terms
Linear current density
external magnetic field
Relativistic mass correction
  • Using the value of current density obtained with
    the help of Eq.(8) and using it in the wave
    equation and assuming the radiation amplitude to
    be slowly varying function of z, the paraxial
    wave equation is given by

Jha et al Phys. Plas. 13, 103102 (2006)
11
  • N includes nonlinear perturbations due to
  • Relativistic effects
  • Density fluctuations
  • Coupling of radiation field with magnetic field
  • Using source dependent expansion (SDE) method the
    equation for laser spot-size is obtained as

Jha et al Phys. Plas. 13, 103102 (2006)
12
  • Here is the normalized laser
    power and is the
  • Rayleigh Length. defines the critical
    laser power for nonlinear
  • self-focusing of a laser beam in magnetized
    plasma and its value is
  • A graphical analysis of the normalized laser spot
    size variation with propagation distance and
    magnetic field and the variation of critical
    power with magnetic field is presented.

Jha et al Phys. Plas. 13, 103102 (2006)
13
Fig. 1 Variation of rs/r0 with z/ZRfor (a)
unmagnetized plasma
(b) 0.2 and (c) 0.4, with,
, and
0.1.
14
Fig. 2 Variation of with at
0.3 for 0.271,
s-1 and 0.1.
15
Fig. 3 Variation of with
for ,
s-1 and 0.1.
16
(b) Circularly polarized laser beam propagating
in axially magnetized plasma
  • A circularly polarized laser beam propagating in
    plasma is embedded in a uniform, axial magnetic
    field . The normalized electric
    field vector of the radiation
    field propagating along the z-direction is
    represented by

where k0 and ?0 are the
normalized amplitude, wave number and
frequency of the radiation field,
respectively. s takes values 1for right or left
circularly polarized radiation, respectively.
  • Wave equation governing the propagation of a
    circularly polarized laser beam in presence of
    axial magnetic field is given by

17
  • Proceeding in the same manner as in the case of
    linearly polarized laser beam the spot-size of
    the circularly polarized laser beam is given by

where S is given by
18
Fig. 4 Variation of rs/r0 with z/ZR for (a) ?c/?0
0, (b) ?c/?0 0.15, s -1 and (c) ?c/?0
0.15 s 1with a0 0.271 and ?0 1.881015
s-1.
19
Fig. 5 Variation of rs/r0 with ?c/?0 for right
circularly polarized laser beam having z/ZR 0.3,
a0 0.271, ?0 1.881015 s-1 and ?c/?0 0.1.
20
Fig. 6 Variation of rs/r0 with ?c/?0 for left
circularly polarized laser beam having z/ZR 0.3,
a0 0.271, ?0 1.881015 s-1 and ?c/?0 0.1.
21
Modulation instability of laser pulses in axially
magnetized plasma
  • Modulation instability is the process in which
    the pump wave amplitude gets modulated in space
    or time. Modulation occurs due to the interplay
    between the nonlinearity and dispersive effects
    Due to this instability the actual wave number
    (k0) of laser beam change into k0K (where K is
    modulation wave number).
  • Modulation instability of a circularly polarized
    laser beam propagating through axially
    magnetized, cold and underdense plasma has been
    studied. The governing wave equation is

22
  • Considering only linear source term and taking
    the Fourier Transform of wave equation gives

where is the Fourier
Transform of slowly varying amplitude a0( ,t)
and
is the linear part of the total refractive
index, having contributions due to vacuum, finite
spot-size of the laser radiation and presence of
magnetized plasma respectively. Defining mode
propagation constant and
considering the limit that mode propagation
constant is close to the unperturbed wave number
(k0), Eq. (15) may be written as
23
  • Using Taylor series expansion the frequency
    dependent function ßm (?) may be expanded
    about ?0 as

where . In
Eq. (17) is related to the group velocity
dispersion (GVD).
  • Substituting Eq. (17) in Eq. (16), retaining
    terms up to ß2m (?) and introducing nonlinear
    current source term on the right hand side gives
    the nonlinear non-paraxial wave equation as

24
  • In order to study the spatial modulation
    instability, transformations are carried out from
    spatial and temporal coordinates (z, t) in the
    laboratory frame to the spatial coordinates (z,
    ?)in the pulse frame. The transformation is
    achieved by substituting ?z vgt and z z.
    Substituting the nonlinear parameter
    , setting ß0 k0,
    and neglecting in
    comparison to 2
    Eq. (18) may be written in the 1-D limit as

Solution of Eq.(19) may be written as
where a10 (z, ?) is the perturbed beam amplitude
and is the normalized laser power in
presence of axial magnetic field.
25
  • The exponentially varying perturbed amplitude may
    be taken to be of the form

where k is the propagation wave number of the
perturbed wave amplitude. Taking to vary
with z as exp(Kz), where K is the modulation
wave number, the dispersion relation for
one-dimensional modulation instability is written
as
where , and
are normalized dimensionless
quantities.
26
  • Modulation instability is excited provided
    is sufficiently negative ,
    , so that can be complex.
    Consequently the range of unstable wave numbers
    for which the instability exists is given by
  • The growth rate of modulation instability for the
    laser beam propagating through transversely
    magnetized plasma is given by

27
Fig. 7 Variation of modulation instability growth
rate for right (curve a), and left (curve c)
circularly polarized laser beam propagating in
magnetized plasma and for laser beam propagating
in unmagnetized (curve b) plasma, with normalized
wave number with r015µm, a00.271 ,
?01.881015s-1 , ?p/?00.1 and ?c/?00.05
(curves a and b).
28
Fig. 8 Stability boundry curves showing the
variation of normalized laser power with
for right (curve a), left (curve c) circularly
polarized laser beam propagating in magnetized
plasma and unmagnetized case (curve b). The
parameters used a00.271 , ?01.881015s-1 ,
?p/?00.1 and ?c/?00.05.
29
Second harmonic generation in laser magnetized
plasma interaction
  • It has been shown that when an intense laser beam
    interacts with homogeneous plasma embedded in a
    transverse magnetic field, second order
    transverse plasma electron velocity oscillating
    with frequency twice that of the laser field is
    set up
  • This plasma electron velocity couples with the
    ambient plasma density leading to a transverse
    plasma current density oscillating at the second
    harmonic frequency. Also first order density
    perturbation oscillating at the laser frequency
    arises due to the presence of the magnetic field.
    This density perturbation couples with the
    fundamental transverse quiver velocity to give
    transverse plasma current density oscillating at
    twice the laser frequency.

30
  • Consider a linearly polarized laser beam
    propagating along the z-direction as
  • As the beam propagates through transversely
    magnetized plasma, transverse current density at
    twice the laser frequency arises and
    acts as a source of second harmonic generation.
  • Corresponding to the frequencies and
    the electric fields are assumed to be
    given by

Laser frequency
Amplitude
Propagation constant
31
  • Here and
    . and are wave
    refractive indices corresponding to the
    frequencies and .
  • The equation governing the propagation of the
    laser pulse through plasma is given by
  • where .
  • The plasma electron density is given by

Plasma electron velocity
Plasma electron density
32
  • Relativistic interaction between the
    electromagnetic field and plasma electron is
    governed by
  • Lorentz force equation
  • Continuity equation

Transverse magnetic field
Magnetic vector of radiation field
33
  • Using perturbative technique all quantities can
    be expanded in orders of the radiation field.
    Using Lorentz force equation the first and second
    order longitudinal velocities and second order
    transverse velocity of the plasma electrons is
    given by
  • where is the cyclotron frequency of
    plasma electrons and
    and are normalized
    amplitudes.

34
  • The first order plasma electron density is
    obtained by using continuity equation as
  • The transverse current density can now be
    written as
  • From the current density equation it is observed
    that current density at second harmonic arises
    via
  • Transverse plasma electron velocity oscillations
    at second harmonic frequency.
  • Coupling of electron density oscillations at
    fundamental frequency and electron quiver
    velocity also oscillating at fundamental
    frequency. This contribution is attributed to
    the external magnetic field and provides source
    for the generation of second harmonic radiation.

35
  • Linear fundamental and second harmonic
    dispersion relations are given by
  • For obtaining second harmonic amplitude the
    value of the current density is
    substituted in the wave equation and it is
    assumed that the distance over which
    changes appreciably is large compared with the
    wave length and that depletes (with z)
    very slightly so that quantity can be
    assumed to be independent of z.
  • The evolution of the second harmonic amplitude
    is given by
  • where .

36
  • The second harmonic conversion efficiency is
    defined as
  • For a given conversion efficiency is
    periodic in z.
  • The minimum value of z for which is
    maximum is given by
  • The length represents the maximum plasma
    length up to which the second harmonic power
    increases. For z gt the second harmonic power
    reduces again.

37
  • The maximum second harmonic efficiency, after
    traversing a distance is given by
  • The maximum conversion efficiency is zero in the
    absence of magnetic field and increases in with
    increase in magnetic field. However, near the
    electron cyclotron resonance the theory breaks
    down. The conversion efficiency also increases
    with the increase in the intensity of the laser
    beam.

38
Fig. 9 Variation of conversion efficiency (?)
with the propagation distance z for?c/?0?p/
?00.1, a120.09 and ?01.881015s-1.
39
Fig. 10 Variation of maximum conversion
efficiency (?max) with ?c/?0 for ?p/?00.1,
a120.09 and ?01.881015s-1.
40
Conclusions
  • Transverse magnetization of plasma enhances the
    self-focusing property of the laser beam and the
    critical power required to self-focus the
    linearly polarized laser beam propagating in
    transversely magnetized plasma is reduced. This
    above explanation is also valid for a left
    circularly polarized laser beam propagating in
    axially magnetized plasma
  • If the laser beam is right circularly polarized,
    the beam will be defocused. Focusing of the right
    circularly polarized beam can be brought about by
    reversing the direction of the external magnetic
    field.
  • Magnetic fields alter the growth rate of
    modulation instability. The peak growth rate of
    modulation instability in the presence of the
    magnetic field for a left circularly polarized
    laser beam is found to increase while for right
    circularly polarized beam the spatial growth rate
    reduces as compared to the absence of magnetic
    field.
  • The stability boundary curve shows that for left
    circularly polarized beam, the area representing
    the unstable interaction is increased while that
    for left circularly polarized laser beam it
    reduces.

41
  • It is seen that second harmonic conversion
    efficiency oscillates as the wave propagates
    along the z-direction.
  • It is found that maximum conversion efficiency
    is zero in the absence of magnetic field and
    increases as the magnetic field is increased.
  • The conversion efficiency also increases with
    increase in intensity of the laser beam.
  • observation of second harmonics in homogeneous
    plasma could point towards the possibility of
    presence of a magnetic field, since second
    harmonics have so far been generated by the
    passage of linearly polarized laser beams through
    inhomogeneous plasma.

42
Journal Publications
  • Self focusing of intense laser beam in magnetized
    plasma
  • Pallavi Jha, Rohit K. Mishra, Ajay K. Upadhyay
    and Gaurav Raj, Physics of Plasmas, 13, 103102
    (2006).
  • Also published in Virtual Journal of Ultrafast
    Science, 5, Issue 10 (2006)
  • Second harmonic generation in laser
    magnetized-plasma interaction
  • Pallavi Jha, Rohit K. Mishra, Gaurav Raj and
    Ajay K. Upadhyay, Physics of Plasmas, 14, 053107
    (2007).
  • Also published in Virtual Journal of Ultrfast
    Science, 6, Issue 5, (2007)
  • Spot-size evolution of laser beam propagating in
    plasma embedded in axially magnetic field.
  • Pallavi Jha, Rohit K. Mishra, Ajay K. Upadhyay
    and Gaurav Raj, Physics of Plasmas, 13, 103102
    (2006).

43
Conference Proceedings
  1. Interaction of laser pulses with magnetized
    plasma
    Rohit K. Mishra, Ajay K. Upadhyay, Gaurav Raj
    and Pallavi Jha
    Presented at 20th National Symposium on Plasma
    Science and Technology Cochin (2005).
  2. Modulation instability of a laser beam in a
    transversely magnetized plasma Rohit K.
    Mishra, Ajay K. Upadhyay, Gaurav Raj and Pallavi
    Jha Presented at 21st
    National Symposium on Plasma Science and
    Technology Jaipur (2006).
  3. Spot-size evolution in axially magnetized plasma

    Rohit K. Mishra, Ajay K. Upadhyay, Gaurav Raj and
    Pallavi Jha Presented at
    6th National Laser Symposium Indore (2007).
  4. Magnetic field detection via second harmonic
    generation
    Rohit K. Mishra, Ram G. Singh and Pallavi Jha

    Presented at 22nd National Symposium on Plasma
    Science and Technology Ahmedabad (2007).

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