2. LASER PRESSURE ACCELERATION AND RT INSTABILITY

The radiation pressure P _r created by a laser irradiance I _L at the solid-vacuum interface is given by

(1)$$P_r=\left({\displaystyle{{I_L } \over c}} \right)\left({1+R} \right).$$

R is the laser reflection from the micro-foil target and c is the light velocity. For the following calculations, we take R = 1 that might be achieved with very short laser pulses τ_L where τ_L ~ 10 picoseconds and less. In this case, for a foil where the center of mass is moving in the x direction, one gets from the Newton second law that the acceleration a of the center of mass, in the x-direction, is given by

(2)$$a=\displaystyle{{2I_L } \over {{\rm \rho} cl_x }} \equiv - g\comma \;$$

ρ is the foil density and the x,y,z dimensions of the foil are l _x, l _y, l _z accordingly. In this case, one can analyze the foil fluid motion in a gravitational field described by g. For a fluid motion described by its field velocities ν(x,y,z) without turbulence, ∇× ν = 0, one can define the velocity potential ϕ by the relation ν = ∇ϕ(x,y,z;t). Neglecting the quadratic velocity term (ν²) and assuming a non-compressible fluid one can write the Euler equation in a gravitational field in the following way

(3)$$\displaystyle{{\partial {\rm \phi} } \over {\partial t}}+\displaystyle{P \over {\rm \rho} }+g{\rm x}= 0.$$

Using the relations ν_x = ∂x/∂t = ∂ϕ/∂x, v _y = ∂ϕ/∂y, v _z = ∂ϕ/∂z, taking the local pressure P as induced by the surface tension, P = −α(∂²x/∂y ² + ∂²x/∂z ²), and taking the time derivative of Eq. (3) we get the following equation

(4)$${\rm \rho} g\displaystyle{{\partial {\rm \phi} } \over {\partial x}} + {\rm \rho} \displaystyle{{\partial ^2 {\rm \phi} } \over {\partial t^2 }} - {\rm \alpha} \displaystyle{\partial \over {\partial x}}\left({\displaystyle{{\partial ^2 {\rm \phi} } \over {\partial y^2 }} + \displaystyle{{\partial ^2 {\rm \phi} } \over {\partial z^2 }}} \right)= 0 .$$

Defining the foil in the domain: −l _x ≤ x ≤ 0, 0 ≤ y ≤ l _y, 0 ≤ z ≤ l _z, and assuming the boundary conditions

(5)$$\eqalign{& {\rm v}_x \left({x = - l_x } \right)= \displaystyle{{\partial {\rm \phi} } \over {\partial x}}\left({x = - l_x } \right)= 0 \cr & {\rm v}_y \left({y = 0\comma \; l_y } \right)= \displaystyle{{\partial {\rm \phi} } \over {\partial y}}\left({y = 0} \right)= \displaystyle{{\partial {\rm \phi} } \over {\partial y}}\left({y = l_y } \right)= 0 \comma \cr & {\rm v}_z \left({z = 0\comma \; l_z } \right)= \displaystyle{{\partial {\rm \phi} } \over {\partial z}}\left({z = 0} \right)= \displaystyle{{\partial {\rm \phi} } \over {\partial z}}\left({z = l_z } \right)= 0}$$

we get the following solution of Eq. (4)

(6)$$\eqalign{& {\rm \phi} \left({x\comma \; y\comma \; z\semicolon \; t} \right)= e^{ - i{\rm \omega} t} Ae^{ - kl_x } \left[{e^{k\left({x + l_x } \right)} + e^{ - k\left({x + l_x } \right)} } \right]\;f\left({y\comma \; z} \right)\cr & f\left({y\comma \; z} \right)= \cos \left({\displaystyle{{n_y y} \over {l_y }}} \right)\cos \left({\displaystyle{{n_z z} \over {l_z }}} \right)\semicolon \; {\rm }\left. \matrix{n_y \hfill \cr n_z \hfill} \right\}{\rm = 0\comma \; 1}{\rm \pi} {\rm\comma \; 2}{\rm \pi} {\rm\comma \; 3}{\rm \pi} {\rm\comma \; }...{\rm }}$$

Substituting this solution into Eq. (4) we get the following dispersion relation at the foil back surface x = 0 (the laser irradiates the foil at the front surface, x = −l _x, while we are interested in the back surface instability about the surface x = 0).

(7)$${\rm \omega} ^2 = - k\left[{a \cdot {\rm tgh}\left({kl_x } \right)- \displaystyle{{\rm \alpha} \over {\rm \rho} }\left({\displaystyle{{n_y ^2 } \over {l_y ^2 }}+\displaystyle{{n_z ^2 } \over {l_z ^2 }}} \right)} \right].$$

In Eq. (7), we have substituted the acceleration a instead of the gravitational field g (g = −a, a > 0 according to Eq. (2)).

Denoting by ξ the local disturbance at the back surface of the foil we obtain from Eq. (6)

(8)$${\rm \xi} = \vint {\left({\displaystyle{{\partial {\rm \phi} } \over {\partial x}}} \right)_{x = 0} dt = } \;{\rm \xi} _0 e^{ - i{\rm \omega} t}$$

where ξ₀ is the initial disturbance at the x = 0 surface and ω is given by Eq. (7). Neglecting the surface tension term (i.e., α = 0), ω is imaginary and one gets the RT instability by using Eq. (2)

(9)$$\eqalign{& \displaystyle{{\rm \xi} \over {{\rm \xi} _0 }} = {\rm exp }\lcub \lsqb {\rm ka} \cdot {\rm tgh}\left({{\rm k}l_{\rm x} } \right)\rsqb ^{1/2} {\rm t}\rcub \equiv \exp \left({\displaystyle{t \over {{\rm \tau} _{RT} }}} \right)\cr & \displaystyle{1 \over {{\rm \tau} _{RT} }} \equiv \left[{\left({\displaystyle{{2{\rm \pi} a} \over L}} \right){\rm tgh}\left({\displaystyle{{2{\rm \pi} l} \over L}} \right)} \right]^{1/2} = \left[{\left({\displaystyle{{4{\rm \pi} I_L } \over {{\rm \rho} clL}}} \right){\rm tgh}\left({\displaystyle{{2{\rm \pi} l} \over L}} \right)} \right]^{1/2} } .$$

In the second term of Eq. (9), the most restrictive constrain on the instability is taken by choosing k = 2π/L, where L is the target dimension orthogonal to the x amplitude. For tgh(kl _x) = 1 one gets the standard RT expression (Eliezer, Reference Eliezer2002; Chandrasekhar, Reference Chandrasekhar1961). However in our case L ~ l _y = l _z ≫ l _x ≡l implying tgh(2πl/L) ~ 2πl/L and the following time scale for the RT instability

(10)$${\rm }{\rm \tau} _{RT} = \left({\displaystyle{L \over {2{\rm \pi} }}} \right)\sqrt {\displaystyle{{{\rm \rho} c} \over {2I_L }}} \;{\rm for }\;l{\rm\ll \; L}.$$

Denoting the critical value that the foil breaks by (ξ/ξ₀)_cr at time t _cr, one gets the foil velocity v _f before breakdown by RT instability

(11)$$\eqalign{& {\rm v}_f = at_{cr} = a{\rm \tau} _{RT} \ln \left({\displaystyle{{\rm \xi} \over {{\rm \xi} _0 }}} \right)_{cr} \Rightarrow \cr & {\rm v}_f = c\left\{{\left({\displaystyle{{I_L } \over {{\rm \rho} c^3 }}} \right)\left({\displaystyle{L \over {{\rm \pi} l}}} \right)\left[{tgh\left({\displaystyle{{2{\rm \pi} l} \over L}} \right)} \right]^{ - 1} } \right\}^{1/2} ln\left({\displaystyle{{\rm \xi} \over {{\rm \xi} _0 }}} \right)_{cr}. }$$

For I _L = 10¹⁸ W/cm², L =10 µm, l = 1 µm, and ρ = 1 g/cm³ we get using Eqs. (2) and (9) the acceleration a = (2/3) × 10¹⁹ cm/s² and the RT time scale τ_RT =6.54 ps. This interesting result implies that a foil with very small initial disturbances can be accelerated until it breaks at ln(ξ/ξ₀)_cr ~3 inferring t _cr ~20 ps before breaking down by RT instability. In this case, the foil velocity v _f is about v _f ~ 3aτ_RT = 1.34 × 10⁸ cm/s.

The final velocity of the accelerated foil before breakdown by Rayleigh Taylor instability according to Eq. (11) is given in Figure 1, where we have chosen ln(ξ/ξ₀)_cr = 3 and the foil density ρ = 1 g/cm³. The ratio of foil thickness (l) to the transversal dimension (L) are given for (1) 2πl/L= 1, (2) 2πl/L=0.1. As one can see from these figures the laser can accelerate foils to velocities as high as 10⁹ cm/s before breaking by RT instability.

Fig. 1. (Color online) The final velocity of the accelerated foil before breakdown by Rayleigh Taylor instability according to Eq. (11). In this equation ln(ξ/ξ₀)_cr was chosen to be equal to 3 and the foil density ρ =1 g/cm³. The ratio of foil thickness (l) to the transversal dimension (L) are chosen for (a) 2πl/L = 1, (b) 2πl/L = 0.1.

3. THE SURFACE TENSION AND RAYLEIGH-TAYLOR (RT) INSTABILITY

In this section, we describe the double layer by a capacitor model as given in Figure 2. This capacitor model is controlled by laser irradiances I _L where the ponderomotive force dominates the interaction. E _x is the electric field inside the double layer, λ_DL is the distance between the positive and negative DL charges, l is the foil thickness, and δ is the solid density skin depth of the foil. n _e and n _i are the electron and ion densities accordingly, E _x is the electric field solution. The DL is geometrically followed by neutral plasma where the electric field decays within a skin depth δ given by δ = c/ω_pe, where ω_pe = 5.64 × 10⁴√n _e = 1.78 × 10¹⁶ s⁻¹, implying δ ~ 2 × 10⁻⁶ cm.

Fig. 2. (Color online) (a) The capacitor model for laser irradiances I _L where the ponderomotive force dominates the interaction. E _x is the electric field inside the double layer, λ_DL is the distance between the positive and negative DL charges, l is the foil thickness and δ is the solid density skin depth of the foil. (b) A schematic figure that our capacitor model is based. n _e and n _i are the electron and ion densities accordingly, E _x is the electric field solution. The DL is geometrically followed by neutral plasma where the electric field decays within a skin depth.

The acceleration of double layers by a high power laser to high velocity was suggested in the literature for a long time. The dispersion relation that takes into account also the double layer (DL) surface tension (Eliezer & Hora, Reference Eliezer and Hora1989; Hora et al., Reference Hora, Min, Eliezer, Lalousis, Pease and Szichman1989) is given in Eq. (7). The double layer motion is RT stable if ω² > 0 and this can be achieved if the following inequality is satisfied:

(12)$${\rm \alpha} \geq {\rm \rho} aL^2 \cdot {\rm tgh}\left({\displaystyle{{2{\rm \pi} l} \over L}} \right).$$

In Eq. (12), we have taken the most unstable modes as defined in Eq. (7) by (n _y = 2π, n _z =0) or (n _y =0, n _z = 2π). The DL surface tension within the context of a capacitor model (see Fig. 2) is given by

(13)$${\rm \alpha} = \left({\displaystyle{{E_{DL} ^2 } \over {8{\rm \pi} }}} \right){\rm \lambda} _{DL} \approx \displaystyle{{I_L {\rm \lambda} _{DL} } \over {c{\rm \varepsilon} _r ^2 }}$$

E _DL is the electric field in the DL region; λ_DL is the distance between the positive and negative DL charges, usually (Eliezer & Hora, Reference Eliezer and Hora1989) of the order of the Debye length λ_D ≈ 750(T _eV/n _e)^1/2 where T _eV and n _e are the electron temperature in eV units and the electron density accordingly. ε_r ≈ (1 − ω_p²/ω_L²) = (1 − n _e/n _c) is the dielectric constant in the DL domain. Since the electrons are pushed out of the DL by the ponderomotive force then one can assume that the electron density inside the DL is smaller than the critical density n _c, described schematically in Figure 2, implying ε_r ≈ 1 as a good approximation. Substituting the acceleration from Eq. (2) into Eq. (13) we get the DL stability for

(14)$${\rm \lambda} _{DL} \geq 2\left({\displaystyle{{L^2 } \over l}} \right){\rm tgh}\left({\displaystyle{{2{\rm \pi} l} \over L}} \right).$$

For l/L ≪  1 we can approximate the DL stability by the simple relation

(15)$${\rm \lambda} _{DL} \geq 4{\rm \pi} L .$$

As a typical example we can take λ_DL of the order of the Debye length λ_D and for T = 100 eV, n _e = 10²² cm⁻³ we have λ_DL ~ 7.5 × 10⁻⁸ cm ~10 L, a transversal dimension of a nano-foil or rather a nanotube! Therefore it looks that for micro-foils the DL surface tension does not contribute to hydrodynamic stability unless the electron density is few orders of magnitude smaller than 10²² cm⁻³ and the temperature significantly higher than 100 eV.

4. RELATIVISTIC RAYLEIGH-TAYLOR (RT) INSTABILITY

With the development (Piazza et al., Reference Piazza, Muller, Hatsagortsyan and Keitel2012) of laser irradiances larger than 10²¹ W/cm² it became possible to accelerate a micro-foil to relativistic velocities due to the laser pressure P =2I _F /c, where I _F is the laser irradiance in the accelerated foil rest frame and c is the speed of light and it is assumed that the reflection in the foil rest frame is one. The laser irradiance I _L and angular frequency ω_L in the laboratory are related to their appropriate values in the foil rest frame (denoted by subscript F) by Doppler equation, based on appropriate Lorenz transformation of the electro-magnetic fields and the definition of I in term of these fields,

(16)$$\eqalign{& I_L = I_F \left({\displaystyle{{{\rm \omega} _L } \over {{\rm \omega} _F }}} \right)^2 = I_F \left({\displaystyle{{1 + {\rm \beta} _f } \over {1 - {\rm \beta} _f }}} \right)\cr & P = \displaystyle{{2I_L } \over c}\left({\displaystyle{{1 - {\rm \beta} _f } \over {1+{\rm \beta} _f }}} \right)}$$

where cβ_f is the foil velocity in the laboratory frame of reference.

The relativistic Newton law of motion

(17)$$\displaystyle{d \over {dt}}\left[{\left({{\rm \rho} _0 lc} \right)\displaystyle{{{\rm \beta} _f } \over {\sqrt {1 - {\rm \beta} _f ^2 } }}} \right]= \displaystyle{{2I_L } \over c}\left({\displaystyle{{1 - {\rm \beta} _f } \over {1+{\rm \beta} _f }}} \right)\comma \;$$

has been solved (Eliezer et al., Reference Eliezer, Martinez Val and Pinhasi2013)

(18)$$\mathop{\vint}\limits_0^{{\rm \beta} _f} \displaystyle{dx \over \left({1 - x} \right)^{5/2} \left({1 + x} \right)^{1/2}} = \displaystyle{\left(2 - {\rm \beta} _f \right)\sqrt{1 - {\rm \beta} _f ^2} \over 3\left(1 - {\rm \beta}_f \right)^2} - \displaystyle{2 \over 3} = \displaystyle{2It \over {\rm \rho}_0 c^2 l} \equiv \displaystyle{t \over {\rm \tau} } \comma \;$$

for a pulsed laser with constant intensity in order to get micro-foil velocity β_f as function of the laser pulse duration t _L in units of τ = ρ₀c ²l/(2I _L), where ρ₀ is the micro-foil initial density and l is the foil thickness. Figure 3 describes the micro-foil velocity as a function of the laser pulse duration in units of τ. For example, if ρ₀ = 1 g/cm³, l = 0.1 µm, foil cross-section of 10 µm², then β_f = 0.5 for a laser with I _Lt _L = 4.5 × 10⁸ J/cm² and energy 45 J. Furthermore, for an irradiance of 10²² W/cm² one requires a laser with pulse duration of 45 fs.

Fig. 3. (Color online) Micro-foil velocity β_fc as a function of the laser pulse duration in units of τ = ρ₀c ²l/(2I _L), where ρ₀ is the micro-foil initial velocity upon impact and l is the foil thickness.

A crucial question in accelerating a foil to relativistic velocity is its hydrodynamic stability. In particular, the relativistic Rayleigh-Taylor instability was calculated (Pegoraro & Bulanov, Reference Pegoraro and Bulanov2007) as described in Eq. (19).

(19)$$\eqalign{& {\rm \xi} _{NR} = \displaystyle{{\Delta x} \over {x_0 }} = \exp \left({\displaystyle{t \over {{\rm \tau} {}_{NR}}}} \right)\cr & {\rm \xi} _R = \displaystyle{{\Delta x} \over {x_0 }} = \exp \left[{\left({\displaystyle{t \over {{\rm \tau} {}_R}}} \right)^{1/3} } \right]\cr & \displaystyle{{{\rm \tau} _R } \over {{\rm \tau} _{NR} }} = \left({\displaystyle{1 \over {3{\rm \pi} }}} \right)\left({\displaystyle{L \over {l_0 }}} \right)\left({\displaystyle{{I_L } \over {{\rm \rho} _0 c^3 }}} \right)}$$

ξ_NR and ξ_R are accordingly the non-relativistic and relativistic development of the instability for an initial disturbance x ₀ and L is the target dimension orthogonal to the x amplitude. The non-relativistic time scale τ_NR we calculate from the second of Eq. (9): τ_NR =τ_RT. We consider the following example: L =10 µm, x ₀ =10 nm, ρ₀ =1 g/cm³, l = 0.1 µm, I _L =10²⁴ W/cm². Assuming that the foil breaks for ξ = 10 (i.e., Δx ~ l) then the foil breaks at 14.2 fs (τ_NR = 6.2 fs) for the non-relativistic case while in the relativistic regime the foil is stable during 90.5 fs (τ_R =39.3 fs). This behavior is understood from the different time dependence of the RT instability in relativistic and non-relativistic cases. Taking into account that during few femtoseconds one can accelerate a micro-foil to relativistic velocities one can achieve stable relativistic acceleration for laser irradiances of the order of 10²³ W/cm².