Reversed Cherenkov emission of terahertz waves from an ultrashort laser pulse in a sandwich structure with nonlinear core and left-handed cladding

doi:10.1364/OE.18.001684

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Reversed Cherenkov emission of terahertz waves from an ultrashort laser pulse in a sandwich structure with nonlinear core and left-handed cladding

M. I. Bakunov, R. V. Mikhaylovskiy, S. B. Bodrov, and B. S. Luk'yanchuk »View Author Affiliations

Optics Express, Vol. 18, Issue 2, pp. 1684-1694 (2010)
http://dx.doi.org/10.1364/OE.18.001684

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– Abstract
1. Introduction
2. Generation scheme and model
3. General solution
4. Results and discussion
5. Conclusion
– References and links

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Abstract

We propose a scheme for an experimental verification of the reversed Cherenkov effect in left-handed media. The scheme uses optical-to-terahertz conversion in a planar sandwichlike structure that consists of a nonlinear core cladded with a material that exhibits left-handedness at terahertz frequencies. The focused into a line femtosecond laser pulse propagates in the core and emits Cherenkov wedge of terahertz waves in the cladding. We developed a theory that describes terahertz generation in such a structure and calculated spatial distribution of the generated terahertz field, its energy spectrum, and optical-to-terahertz conversion efficiency. The proposed structure can be a useful tool for characterization of the electromagnetic properties of metamaterials in the terahertz frequency range.

1. Introduction

One of the most intriguing electromagnetic phenomena in left-handed (LH) media is the reversed Cherenkov effect. Predicted by Pafomov as early as 1959 [1

V. E. Pafomov, “On transition radiation and the Vavilov-Cherenkov radiation,” Zh. Eksp. Teor. Fiz. 36, 1853–1858 (1959) (Sov. Phys. JETP 9, 1321 (1959)).

] (see also the famous paper by Veselago [2

V. G. Veselago, “The electrodynamics of substances with simultaneously negative values of ε and μ,” Usp. Fiziol. Nauk 92, 517–526 (1967) (Sov. Phys. USPEKHI 10, 509–514 (1968)).

]), this effect started being studied in detail only recently. In Ref [3

J. Lu, T. Grzegorczyk, Y. Zhang, J. Pacheco Jr, B.-I. Wu, J. A. Kong, and M. Chen, “Cerenkov radiation in materials with negative permittivity and permeability,” Opt. Express 11(7), 723–734 (2003). [CrossRef] [PubMed]

], Cherenkov radiation from a point charge in an isotropic LH medium, whose permittivity and permeability were modeled by Lorentz formulas, was calculated. It was shown, in accord with the prediction of Pafomov and Veselago, that the radiation pattern presents lobes in the backward direction – at the angles larger than 90° with respect to the charge velocity. In Ref [4

Yu. O. Averkov and V. M. Yakovenko, “Cherenkov radiation by an electron bunch that moves in a vacuum above a left-handed material,” Phys. Rev. B 72(20), 205110 (2005). [CrossRef]

], Cherenkov radiation of bulk and surface electromagnetic waves by a nonrelativistic electron bunch that moves above the surface of a model LH material was investigated. The effect of the LH material anisotropy on the spectral density and total radiated energy of reversed Cherenkov radiation was studied for a point charge moving in an unbounded anisotropic LH medium [5

Z. Y. Duan, Y. B. Gong, Y. Y. Wei, W. X. Wang, B.-I. Wu, J. A. Kong, and M. Chen, “Theoretical investigation into Cherenkov radiation in an anisotropic double-negative medium,” in Proceedings of 33rd International Conference on Infrared, Millimeter, and Terahertz Waves, (Pasadena, Calif., 2008).

] and in a waveguide (partially) filled with such a medium [6

Z. Y. Duan, B.-I. Wu, J. Lu, J. A. Kong, and M. Chen, “Reversed Cherenkov radiation in a waveguide filled with anisotropic double-negative metamaterials,” J. Appl. Phys. 104(6), 063303 (2008). [CrossRef]

Z. Y. Duan, B.-I. Wu, J. Lu, J. A. Kong, and M. Chen, “Cherenkov radiation in anisotropic double-negative metamaterials,” Opt. Express 16(22), 18479–18484 (2008). [CrossRef] [PubMed]

]. In Ref [8

S. Antipov, L. Spentzouris, W. Gai, M. Conde, F. Franchini, R. Konecny, W. Liu, J. G. Power, Z. Yusof, and C. Jing, “Observation of wakefield generation in left-handed band of metamaterial-loaded waveguide,” J. Appl. Phys. 104(1), 014901 (2008). [CrossRef]

], an indirect experimental observation of the reversed Cherenkov radiation from a beam of charged particles in a LH-medium-loaded waveguide was reported. In Ref [9

S. Xi, H. Chen, T. Jiang, L. Ran, J. Huangfu, B.-I. Wu, J. A. Kong, and M. Chen, “Experimental verification of reversed Cherenkov radiation in left-handed metamaterial,” Phys. Rev. Lett. 103(19), 194801 (2009). [CrossRef]

], a waveguide with an array of slots was used to imitate the moving dipole, and backward radiation was detected after covering the array with a LH prism. Direct experimental verification of the reversed Cherenkov effect still remains a challenging problem [10

Z. Y. Duan, B.-I. Wu, S. Xi, H. S. Chen, and M. Chen, “Research progress in reversed Cherenkov radiation in double-negative metamaterials,” Progress In Electromagnetic Research PIER 90, 75–87 (2009). [CrossRef]

In this paper we propose a feasible scheme for direct observation of the reversed Cherenkov radiation in the terahertz frequency range. To produce the Cherenkov radiation we propose to use an ultrashort laser pulse propagating in an electro-optic medium, rather than an electron bunch. The nonlinear polarization, produced by the pulse via nonlinear optical rectification, moves with the optical group velocity and emits terahertz radiation very much like a relativistic dipole [11

G. A. Askar’yan, “Cherenkov radiation from optical pulses,” Phys. Rev. Lett. 57(19), 2470 (1986). [CrossRef] [PubMed]

]. To achieve the regime of the reversed Cherenkov radiation, we propose to sandwich a thin (of ~10 − 100 μm thickness) layer of a strongly nonlinear material, such as LiNbO₃, between two prisms made of a metamaterial exhibiting left-handedness in the terahertz frequency range (one of the prisms can be replaced by a substrate). To input the laser pulse into the structure, we propose to focus it by a cylindrical lens onto the facet of the nonlinear core so that the light line would be parallel to the plane of the structure. The laser pulse propagates in the core as a mode of the dielectric slab waveguide and emits Cherenkov wedge of terahertz waves in the LH prisms. The prisms are properly cut to output the radiation to vacuum. A similar sandwich structure but with ordinary right-handed (Si) cladding was recently proposed for highly efficient terahertz generation [12

S. B. Bodrov, M. I. Bakunov, and M. Hangyo, “Efficient Cherenkov emission of broadband terahertz radiation from an ultrashort laser pulse in a sandwich structure with nonlinear core,” J. Appl. Phys. 104(9), 093105 (2008). [CrossRef]

]. In Ref [13

S. B. Bodrov, A. N. Stepanov, M. I. Bakunov, B. V. Shishkin, I. E. Ilyakov, and R. A. Akhmedzhanov, “Highly efficient optical-to-terahertz conversion in a sandwich structure with LiNbO3 core,” Opt. Express 17(3), 1871–1879 (2009). [CrossRef] [PubMed]

], using a Si-LiNbO₃-glass structure, 40 μJ, 50 fs Ti:sapphire laser pulses were converted into terahertz pulses of ~3 THz bandwidth with a record efficiency of over 0.1%.

Optical generation of the reversed Cherenkov radiation in the sandwich structure offers a number of advantages as compared to the schemes with electron bunches. First, the radiation power of Cherenkov radiation increases with its frequency; therefore, the terahertz frequency range is more fitted for detection than the microwave range. Second, focusing the pump laser beam into a line allows one to scale up the generated terahertz energy (using laser pulses with higher energy and increasing the length of the line in order to keep the laser intensity below the damage threshold of the nonlinear core). Third, the radiation emitted by a line-source setup forms two beams having nearly flat wave fronts, i.e., Cherenkov wedge, rather than Cherenkov cone. The beams are linearly polarized with the electric field along the line source in the optimal case, as it will be shown below. This configuration fits well the typical design of metamaterials, for example, the dielectric rod-based metamaterial [14

L. Peng, L. Ran, H. Chen, H. Zhang, J. A. Kong, and T. M. Grzegorczyk, “Experimental observation of left-handed behavior in an array of standard dielectric resonators,” Phys. Rev. Lett. 98(15), 157403 (2007). [CrossRef] [PubMed]

], unlike the rotational symmetry of the Cherenkov radiation from an electron bunch. And, finally, the optical-to-terahertz conversion scheme does not require a vacuum.

Below we develop a theory that describes terahertz generation in the sandwich structure with nonlinear core and isotropic LH cladding. We analyze the generated terahertz field, terahertz spectrum, and conversion efficiency for a specific structure with LiNbO₃ core and model Lorentz-type cladding pumped by Ti:sapphire laser (800 nm wavelength).

2. Generation scheme and model

The geometry of the structure and generation scheme are shown in Fig. 1 . A thin layer (|x| < a/2, a ~10 − 100 μm) of a nonlinear material is sandwiched between two prisms (|x| > a/2) made of an isotropic metamaterial that exhibits negative permittivity and permeability at terahertz frequencies. For example, an array of high dielectric constant rods arranged along the y-axis can be used as a material of the prisms [14

]. For the terahertz waves polarized along the y-axis and propagating in the x,z-plane such a metamaterial behaves as an isotropic medium. The pump laser pulse focused in the x-direction by a cylindrical lens is incident on the facet of the nonlinear core. The beam width in this direction is chosen to be ≈(0.2 − 0.3)a to optimize the excitation of the fundamental mode of the dielectric slab waveguide [12

]. The laser pulse propagates in the + z-direction as the fundamental mode of the waveguide with the group velocity V and emits reversed (at the frequencies where the prism's material is left-handed) and direct (at other frequencies) Cherenkov radiation into the prisms. To transmit efficiently the terahertz waves into vacuum, the prisms are cut at the angles α and β (Fig. 1), which are to be defined below.

Fig. 1 Generation scheme. An optical pulse focused to a line propagates in the nonlinear core of the sandwich structure and excites Cherenkov wedge of terahertz waves in the output LH prisms. The arrows show the Poynting vector of the direct (S) _d ) and reversed (S) _r ) components of the Cherenkov radiation.

We use the same approximations as in Ref [12

]. The structure, optical pulse, and terahertz fields are treated as two-dimensional [independent of y (Fig. 1)]. The optical pulse propagates in the core without distortions and has a Gaussian temporal envelope F(ξ) = exp(–ξ²/τ²), where ξ = t – z/V and τ is the pulse duration [the standard full-width at half maximum (FWHM) is τ_FWHM =

2 \sqrt{\ln 2} τ \approx 1.7 τ

]. The dielectric slab waveguide is assumed to be oversized (a exceeds significantly the optical wavelength), therefore, the transverse intensity profile of the fundamental mode can be approximated as G(x) = cos²(πx/a), |x| < a/2 and the velocity V is defined practically only by the material dispersion of the core: V = c/n _g, where n _g is the optical group refractive index of the core and c is the velocity of light. Transient effects at the entrance and exit boundaries of the sandwich are neglected.

The nonlinear polarization produced by optical rectification of the laser pulse in the core (|x| < a/2) can be written in the Fourier domain as

{\tilde{P}}^{NL} = p (ω) \tilde{F} (ω) G (x), \tilde{F} = τ / (2 \sqrt{π}) e^{- ω^{2} τ^{2} / 4},

(1)

where ω is the Fourier variable (frequency), which corresponds to ξ, and ^~ denotes quantities in the Fourier domain. We assume the optimal orientation of the amplitude vector p(ω) – along the y axis, i.e., for LiNbO₃ core both the optical axis of LiNbO₃ and the laser pulse polarization are along the y axis. Such orientation of p(ω) provides, first, most efficient terahertz generation [12

] and, second, an appropriate polarization of the terahertz waves (with electric E_y and magnetic H_x , H_z field components) for the dielectric rod-based metamaterial [14

]. The absolute value of p(ω) is

p (ω) = d_{e f f} (ω) E_{0}^{2}

, where d_eff (ω) is the effective nonlinear coefficient of the core's material (d_eff = d ₃₃ for LiNbO₃) and E ₀ is the maximum of the optical field envelope in the core.

To find the terahertz radiation generated by the nonlinear polarization (1), we use Maxwell's equations written in the frequency domain (all formulas in the paper are in cgs units),

\nabla_{ω} \times \tilde{E} = - \frac{i ω}{c} μ \tilde{H}, \nabla_{ω} \times \tilde{H} = \frac{i ω}{c} ε \tilde{E} + \frac{4 π i ω}{c} {\tilde{P}}^{NL},

(2)

where the nabla operator

\nabla_{ω}

has components

(\partial / \partial x, 0, - i ω V^{- 1})

and the complex permittivity ε(ω, x) and complex permeability μ(ω, x) in the terahertz range are ε _c (ω) and 1 in the core (|x |< a/2) and ε _p (ω) and μ _p (ω) in the prisms (|x| > a/2), respectively.

For the permittivity and permeability of the metamaterial we use the generic forms [15

R. A. Shelby, D. R. Smith, and S. Schultz, “Experimental verification of a negative index of refraction,” Science 292(5514), 77–79 (2001). [CrossRef] [PubMed]

]

ε_{p} (ω) = 1 - \frac{ω_{e p}^{2} - ω_{e 0}^{2}}{ω^{2} - ω_{e 0}^{2} - i ω γ_{e}}, μ_{p} (ω) = 1 - \frac{ω_{m p}^{2} - ω_{m 0}^{2}}{ω^{2} - ω_{m 0}^{2} - i ω γ_{m}},

(3)

with the resonance frequencies ω _e ₀ and ω _m ₀, plasma frequencies ω _ep and ω _mp , and damping rates γ _e and γ _m . Equations (3) are the standard Drude-Lorentz forms that are widely used for modeling of both metallic and dielectric metamaterials [3

Yu. O. Averkov and V. M. Yakovenko, “Cherenkov radiation by an electron bunch that moves in a vacuum above a left-handed material,” Phys. Rev. B 72(20), 205110 (2005). [CrossRef]

,15

R. A. Shelby, D. R. Smith, and S. Schultz, “Experimental verification of a negative index of refraction,” Science 292(5514), 77–79 (2001). [CrossRef] [PubMed]

–17

C. M. Soukoulis, M. Kafesaki, and E. N. Economou, “Negative-index materials: new frontiers in optics,” Adv. Mater. 18(15), 1941–1952 (2006). [CrossRef]

]. In particular, the effective permittivity and permeability of the dielectric-rod metamaterial exhibit the Lorentz-type resonance and isotropic behavior [14

3. General solution

Projecting Eq. (2) into the coordinate system and eliminating

{\tilde{H}}_{x}

and

{\tilde{H}}_{z}

with use of

{\tilde{H}}_{x} = - \frac{n_{g}}{μ} {\tilde{E}}_{y}, {\tilde{H}}_{z} = - \frac{c}{i ω μ} \frac{\partial {\tilde{E}}_{y}}{\partial x},

(4)

we obtain an equation for

{\tilde{E}}_{y},

μ \frac{\partial}{\partial x} (\frac{1}{μ} \frac{\partial {\tilde{E}}_{y}}{\partial x}) + κ^{2} {\tilde{E}}_{y} = - \frac{4 π μ ω^{2} p}{c^{2}} \tilde{F} (ω) G (x) .

(5)

In Eq. (5), we introduced the transverse wave vector

κ (ω, x)

given by

κ^{2} = {(ω / c)}^{2} [ε (ω, x) μ (ω, x) - n_{g}^{2}] .

(6)

We solve Eq. (5) in the homogeneous regions |x| < a/2 and |x| > a/2 and match the solutions by the boundary conditions of continuity of

{\tilde{E}}_{y}

and

{\tilde{H}}_{z}

that arise after integrating Eq. (5) across the boundaries at x = ± a/2.

We arrive at the following expressions for the electric field transform:

{\tilde{E}}_{y} = {\begin{cases} C_{1} e^{- i κ_{p} (x - a / 2)}, x > a / 2 \\ C_{2} e^{- i κ_{c} x} + C_{3} e^{i κ_{c} x} + R (x), | x | < a / 2 \\ C_{4} e^{i κ_{p} (x + a / 2)}, x < - a / 2 \end{cases}

(7)

with

R (x) = \frac{2 π ω^{2} p}{i κ_{c} c^{2}} \tilde{F} \int_{- a / 2}^{a / 2} d x^{'} G (x^{'}) e^{- i κ_{c} | x - x^{'} |},

(8a)

C_{2} = C_{3} = C_{1} e^{- i k_{c} a / 2} [1 - κ_{p} {(κ_{c} μ_{p})}^{- 1}] / 2,

(8b)

C_{1} = C_{4} = \frac{2 π ω^{2} p \tilde{F} (e^{i κ_{c} a / 2} - e^{- i κ_{c} a / 2})}{κ_{c} c^{2} Λ [{(κ_{c} a)}^{2} {(2 π)}^{- 2} - 1]},

(8c)

Λ = (κ_{p} μ_{p}^{- 1} + κ_{c}) e^{i κ_{c} a / 2} + (κ_{p} μ_{p}^{- 1} - κ_{c}) e^{- i κ_{c} a / 2} .

(8d)

The coefficient κ _p is κ taken with ε = ε _p and μ = μ _p and κ _c is κ taken with ε = ε_c and μ = 1 [see Eq. (6)]. To ensure decay of the fields at x → ± ∞, Im κ _p should be taken negative for all frequencies. This also defines the sign of Re κ _p consistent with the condition of energy outflow from the core to x → ± ∞.

It follows from Eqs. (7) and (8c) that the emission of terahertz waves to the prisms is symmetric, C ₁ = C ₄.

To transform the solution (7)-(8) to the ξ domain we take inverse transform in the form

E_{y} (ξ, x) = \int_{- \infty}^{\infty} d ω {\tilde{E}}_{y} (ω, x) e^{i ω ξ}

(9)

and the same formulas used for the other fields.

To find the terahertz energy emitted to the prisms from the unit area of the core-prism interfaces, i.e., the terahertz fluence, we integrate the ± x-components of the Poynting vector

S_{\pm x} = \pm (c / 4 π) E_{y} H_{z}

at x = ± a/2 over infinite interval -∞ < ξ < ∞. This yields the fluence in one of the ± x-directions,

W = \int_{0}^{\infty} d ω w (ω),

(10)

where w(ω) is the spectral density of fluence,

w (ω) = (c^{2} / ω) | C_{1} |^{2} Re (κ_{p} / μ_{p}) .

(11)

The total terahertz fluence is 2W.

We introduce the optical-to-terahertz conversion efficiency per unit length of the sandwich structure (along the z-axis) as

η = W / W_{opt},

(12)

where

W_{opt} = π^{1 / 2} I_{0} a τ / 2

is the energy of the pump optical pulse per unit length along the y-axis [

I_{0} = (c n_{c} / 8 π) E_{0}^{2}

is the peak optical intensity and n_c is the optical refractive index of the core].

4. Results and discussion

Let us now apply the general theory developed in Sec. 3 to a sandwich structure with LiNbO₃ core and metamaterial cladding [see Eq. (3)] pumped with Ti:sapphire laser (800 nm wavelength).

For LiNbO₃, we use the parameters of 0.68 mol% Mg-doped stoichiometric LiNbO₃ at room temperature, as in Ref [12

]. The refractive index

n_{LN} = Re ε_{c}^{1 / 2}

and amplitude absorption coefficient

β_{LN} = (ω / c) Im ε_{c}^{1 / 2}

of LiNbO₃ in the terahertz range are approximated by the following formulas (ν is in THz):

n_{LN} = 4.94 + 0.021 ν^{2} + 0.0012 ν^{4}

[18

L. Pálfalvi, J. Hebling, J. Kuhl, Á. Péter, and K. Polgár, “Temperature dependence of the absorption and refraction of Mg-doped congruent and stoichiometric LiNbO₃ in the THz range,” J. Appl. Phys. 97(12), 123505 (2005). [CrossRef]

] and

β_{LN} [{cm}^{- 1}] = 24.83 - 12.68 ν + 15.91 ν^{2}

(fitting of the data of Ref [18

].). The optical refractive index and group refractive index of LiNbO₃ at 800 nm wavelength are n_c = 2.16 and n_g = 2.23, respectively [19

J. Hebling, A. G. Stepanov, G. Almási, B. Bartal, and J. Kuhl, “Tunable THz pulse generation by optical rectification of ultrasort laser pulses with tilted pulse fronts,” Appl. Phys. B 78, 593–599 (2004). [CrossRef]

]. The nonlinear coefficient of LiNbO₃ is

d_{33} [pm/V] = 25 + 158 \times | 1 - ω^{2} / ω_{TO}^{2} - i γ ω / ω_{TO}^{2} |^{- 1}

with ω_TO/(2π) = 7.68 THz and γ/(2π) = 0.1 THz [20

B. Bartal, I. Z. Kozma, A. G. Stepanov, G. Almási, J. Kuhl, E. Riedle, and J. Hebling, “Toward generation of μJ range sub-ps THz pulses by optical rectification,” Appl. Phys. B 86(3), 419–423 (2007). [CrossRef]

For the metamaterial, we set ω _e ₀ = ω _m ₀ = 2π × 1 THz, ω _ep = ω _mp = 2π × 4 THz, and γ _e = γ _m = 2π × 0.01 THz in Eq. (3). Using the model with ε _p (ω) = μ _p (ω), like in Ref [3

], simplifies the analysis without changing the characteristic features of the radiation. A brief discussion of the case ε _p (ω) ≠ μ _p (ω) will be given in the end of the section. Figure 2 shows the real and imaginary parts of the refractive index

n_{p} = {(ε_{p} μ_{p})}^{1 / 2} = ε_{p}

as functions of ω. The condition of left-handedness Re n_p < 0 is fulfilled in the frequency interval 1 < ω/(2π) < 4 THz. The conditions Re n_p > n_g and Re n_p < −n_g define the frequency intervals 0 < ω/(2π) < 1 THz and 1 < ω/(2π) < 2.37 THz where the direct and reversed Cherenkov radiations, respectively, occur. In the vicinity of the resonance, at ω/(2π) ≈1 THz, the radiation is suppressed by a large (negative) value of Im n_p .

Fig. 2 Real (solid) and imaginary (dashed) parts of n_p = ε _p = μ _p as functions of ω.

Figure 3(a) shows the spatial distribution of the electric field E_y calculated numerically on the basis of Eqs. (7), (8), and (9) for a sandwich structure with a = 40 μm. The radiation pattern in Fig. 3(a) is a superposition of the wavefronts corresponding to the direct [with frequencies of 0 < ω/(2π) < 1 THz] and reversed [with frequencies of 1 < ω/(2π) < 2.37 THz] components of Cherenkov radiation. To get an insight into the radiation pattern, it is instructive to plot separately the wavefronts of the direct [Fig. 3(b)] and reversed [Fig. 3(c)] components of the Cherenkov radiation.

Fig. 3 (a) Snapshot of the electric field E_y (x,z,t) at t = 0 produced in a sandwich structure with a = 40 μm by a Ti:sapphire laser pulse with duration τ_FWHM = 100 fs and peak intensity I ₀ = 40 GW/cm² (W _opt = 8.5 μJ/cm). The core boundaries are shown with the horizontal lines. (b,c) The components of the radiation pattern in the output prism corresponding to direct (b) and reversed (c) Cherenkov radiation.

The radiation pattern of the direct component [Fig. 3(b)] resembles that for a Si-LiNbO₃-Si structure [12

]. The pattern in Fig. 3(b) is, however, affected by the dispersion of the metamaterial prisms, contrary to practically dispersionless Si in Ref [12

]. Indeed, in Fig. 3(b) the wavefronts of partial plane waves with higher frequencies are oriented at smaller angles θ with respect to the z-axis, in accord with the formula

\tan θ = ω n_{g} / [c Re κ_{p} (ω)]

[see also Fig. 4(a) ]. The opening angle of the direct Cherenkov cone θ _d ≈8° corresponds to zero frequency,

\sin θ_{d} = n_{g} / ε_{p} (0)

with

ε_{p} (0) = {(ω_{e p} / ω_{e 0})}^{2} = 16

Fig. 4 The frequency ω of a partial plane wave (a) and the stationary frequency ω_s (b) as functions of θ.

The radiation pattern of the reversed component of the Cherenkov radiation [Fig. 3(c)] differs significantly from the ones in Ref [12

]. and in Fig. 3(b). The wavefronts of the reversed component are almost perpendicular to the Cherenkov cone [cf. Figure 3(b)]. This corresponds to negative values of

Re κ_{p} (ω)

in the formula for partial plane waves

\tan θ = ω n_{g} / [c Re κ_{p} (ω)]

[see also Fig. 4(a)]. The radiation pattern as a whole moves with time along the z-axis with the optical pulse velocity. The component of this velocity along the normal to a wavefront, which determines the phase velocity of a partial plane wave, is directed towards the z-axis, in accord with the predictions of Pafomov [1

V. E. Pafomov, “On transition radiation and the Vavilov-Cherenkov radiation,” Zh. Eksp. Teor. Fiz. 36, 1853–1858 (1959) (Sov. Phys. JETP 9, 1321 (1959)).

] and Veselago [2

V. G. Veselago, “The electrodynamics of substances with simultaneously negative values of ε and μ,” Usp. Fiziol. Nauk 92, 517–526 (1967) (Sov. Phys. USPEKHI 10, 509–514 (1968)).

]. For the parameters used, the reversed component of the Cherenkov radiation has stronger fields than the direct component [cf. Figures 3(b) and (c)] and, as a result, it dominates in the total radiation pattern [Fig. 3(a)].

In the far field zone (at large ξ) integral (9) can be asymptotically evaluated using the stationary phase method [21

M. I. Bakunov, S. B. Bodrov, A. V. Maslov, and M. Hangyo, “Theory of terahertz generation in a slab of electro-optic material using an ultrashort laser pulse focused to a line,” Phys. Rev. B 76(8), 085346 (2007). [CrossRef]

]. The most informative for interpreting the radiation patterns in Fig. 3 is the dependence of the stationary frequency ω _s on the angle θ, a half-apex angle of a cone with its apex on the moving laser pulse ξ = 0 [21

V \frac{d}{d ω} Re κ_{p} = \frac{V ξ}{| x |} = \cot θ .

(13)

The dependence ω _s (θ) is shown in Fig. 4(b). For the direct component of the Cherenkov radiation [0 < ω/(2π) < 1 THz], the dependence ω _s (θ) is similar to ω(θ) in Fig. 4(a), i.e., ω _s decreases with θ tending to zero at the maximal angle (the opening angle of the direct Cherenkov cone) θ _d ≈8°. For the reversed component of the Cherenkov radiation [ω/(2π) > 1 THz], the maximal angle θ _r , i.e., the opening angle of the reversed Cherenkov cone, is θ _r ≈10°, which agrees well with Fig. 3(c). For θ < θ _r , the function ω _s (θ) is double-valued. The higher-frequency branch defines the fine structure of the wavefronts in Fig. 3(c), whereas the lower-frequency branch gives rise to the large-scale modulation of the radiation pattern visible in Fig. 3(c).

Completing the discussion of the radiation pattern, to output efficiently the direct and reversed components of the Cherenkov radiation to vacuum the metamaterial prism should be cut with its edges parallel to the wavefronts of the components, i.e., at α ≈20° – 60° (depending on the frequency to be outputted most efficiently) for the reversed component and β ≈8° for the direct component (Fig. 1). To specify the optimal angle α more accurately, one needs to calculate the spectrum of the reversed Cherenkov component and tune α to its maximal frequency.

Figure 5 shows the spectral density of terahertz fluence w(ω) calculated using Eq. (11) for different core thicknesses a and fixed peak optical intensity I ₀ (for convenience of practical use, we plot 2πw[ω/(2π)] rather than w(ω) in Fig. 5). For a ≈30 – 67 μm, w(ω) has a pronounced peak in the frequency band of the reversed Cherenkov radiation 1 < ω/(2π) < 2.37 THz; the thicker the core, the lower the peak's frequency. For a = 67 μm, the peak falls at 1 THz. Due to strong resonant absorption in the prisms at 1 THz (Fig. 2) the peak will split rapidly into two with distance from the core (similar splitting at 1 THz will be experienced by the wings of the other curves in Fig. 5). For a > 67 μm, the peak shifts to the frequency band of the direct Cherenkov radiation 0 < ω/(2π) < 1 THz and, for a > 150 μm, it quits the terahertz frequency range. For a < 30 μm, the spectrum exhibits no peaks. For 30 < a < 150 μm, the height of the peak varies with a only slightly. Mathematically, the peak in the spectrum appears due to the factor |Λ(ω)|⁻² in Eq. (11). From the physical point of view, the existence of the peak can be attributed to constructive interference of the terahertz waves emitted from the core directly and after multiple reflections at the core-prism boundaries. For a < 30 μm, the peak falls into the frequency band ω/(2π) > 2.37 THz, where Cherenkov radiation is prohibited (Fig. 2), and the contribution of |Λ(ω)|⁻² into w(ω) is suppressed by the factor

Re (κ_{p} / μ_{p}),

which is negligible in this frequency band. If we fix the optical pulse energy W _opt, rather than the intensity I ₀, the peak will decrease with increasing a due to decrease of I ₀ and, therefore, of p in Eq. (11).

Fig. 5 The spectral density of terahertz fluence 2πw[ω/(2π)] for different a (shown near the corresponding curves). The peak optical intensity is fixed to I ₀ = 40 GW/cm² for all curves and τ_FWHM = 100 fs.

Let us now calculate the terahertz fluence and optical-to-terahertz conversion efficiency per unit length of the structure. Dividing the integration range in Eq. (10) into two intervals 0 < ω/(2π) < 1 THz and 1 < ω/(2π) < 2.37 THz [w(ω) is negligible at ω/(2π) > 2.37 THz] we represent the total terahertz fluence W as a sum of the fluences provided by the direct (W_d ) and reversed (W_r ) components of the Cherenkov radiation: W = W_d + W_r . Correspondingly, the efficiency η can be written as a sum of efficiencies η = η _d + η _r with η _d = W_d /W _opt and η _r = W_r /W _opt [see Eq. (12)].

Figure 6 shows the terahertz fluences W_r [Fig. 6(a)] and W_d [Fig. 6(b)], evaluated using Eqs. (10) and (11), as functions of a and τ_FWHM for the fixed peak optical intensity I ₀ = 40 GW/cm². According to Fig. 6(a), the fluence W_r has a broad maximum with W_r ≈50 – 60 nJ/cm at a ≈40 – 60 μm (this agrees with Fig. 5) and τ_FWHM ≈200 – 400 fs. In this range of the parameters, W_d < W_r [Fig. 6(b)]. For a > 65 μm, W_d dominates over W_r ; maximal W_d is reached at a value of a that increases from 75 to 110 μm with increasing τ_FWHM from 100 to 500 fs, respectively.

Fig. 6 The terahertz fluences (a) W_r and (b) W_d as functions of a and τ_FWHM for the fixed peak optical intensity I ₀ = 40 GW/cm².

Figure 7 shows the conversion efficiencies η _r [Fig. 7(a)] and η _d [Fig. 7(b)], evaluated using Eqs. (10), (11), and (12), as functions of a and τ_FWHM for the fixed energy of the optical pulse W _opt = 8.5 μJ/cm. Both efficiencies η _r and η _d decrease with increasing τ_FWHM due to a decrease in the peak optical intensity I ₀ and, therefore, in p. For a given τ_FWHM, there is a narrow interval of a around a ≈30 μm (for example, 28 < a < 32 μm for τ_FWHM = 100 fs), where η _r reaches a maximum and significantly exceeds η _d . This interval shrinks to a ≈30 μm with increasing τ_FWHM [Fig. 7(a)]. According to Fig. 7(a), even for a moderate peak optical intensity of I ₀ ≈50 GW/cm² (W _opt = 8.5 μJ/cm, τ_FWHM = 100 fs, and a = 30 μm), the efficiency η _r can be as high as η _r ≈0.005 cm^–1. A boost of η _r and η _d at a ≈10 μm can be explained by a growth of I ₀ with decreasing a. For a ≈10 μm, the generated terahertz spectrum exhibits no peaks, it becomes flat in the frequency band of 0.5 < ω/(2π) < 2 THz. However, so thin cores are inconvenient for practical use because of difficulties with focusing the pump laser beam onto the core facet.

Fig. 7 The conversion efficiencies (a) η _r and (b) η _d as functions of a and τ_FWHM for the fixed optical pulse energy W _opt = 8.5 μJ/cm.

Let us discuss briefly the case ε_p(ω) ≠ μ_p(ω). Assuming for definiteness that the characteristic frequencies in Eq. (3) are ω _m ₀/(2π) = 1 THz, ω _e ₀/(2π) = 2 THz, ω _mp /(2π) = 4 THz, and ω _ep /(2π) = 5 THz, we obtain that a stop band 1 < ω/(2π) < 2 THz, where Re ε _p > 0 and Re μ _p < 0, appears between the frequency bands of the direct [0 < ω/(2π) < 1 THz] and reversed [2 < ω/(2π) < 2.8 THz] Cherenkov radiation. For a < 40 μm, the spectral density w(ω) is concentrated mainly in the frequency band of the reversed radiation, reaching maximum values at a ≈20 – 30 μm (for a fixed peak optical intensity). In the frequency band of the direct radiation, w(ω) becomes noticeable for a > 40 μm. For another set of characteristic frequencies ω _m ₀/(2π) = 2 THz, ω _e ₀/(2π) = 1 THz, ω _mp /(2π) = 5 THz, and ω _ep /(2π) = 4 THz, the frequency bands of the direct/reversed radiation and the stop band remain the same as in the previous example but distribution of w(ω) between the frequency bands becomes somewhat different. Whereas the reversed radiation is maximized at the same value of a ≈30 μm, w(ω) in the frequency band of the direct radiation is now considerable in the wide range of a, i.e., for a > 10 μm, and dominates over the reversed radiation for a > 35 μm. For both sets of the characteristic frequencies the radiation patterns remain qualitatively similar to Fig. 3(a).

5. Conclusion

To conclude, we have proposed a scheme for experimental verification of the reversed Cherenkov effect. This scheme uses emission of terahertz waves by optical rectification of the femtosecond laser pulse propagating in a sandwichlike structure with nonlinear core and LH cladding. The scheme offers a number of advantages as compared to the schemes with electron bunches: (i) exploiting the terahertz frequency range instead of microwaves increases the radiation power, (ii) focusing the pump laser beam into a line allows one to scale up the generated terahertz energy and (iii) forms more convenient for practical implementation Cherenkov wedge, rather than Cherenkov cone, (iv) the generated spectrum can be tuned by changing the thickness of the nonlinear core, and (v) the scheme does not require a vacuum. A proper cutting of the output metamaterial prism allows one to output the direct and reversed components of the Cherenkov radiation in separate (almost perpendicular) directions.

To demonstrate the efficiency of the scheme, we developed a theory that describes Cherenkov radiation in a sandwich structure with LH cladding. The theory allows one to calculate spatial distribution of the generated terahertz field, terahertz energy spectrum, and optical-to-terahertz conversion efficiency.

Applying the developed theory to a structure with LiNbO₃ core and cladding made of a metamaterial with Lorentzian dielectric permittivity and permeability we predicted the internal conversion efficiency into the reversed component of Cherenkov radiation of up to 0.5% in a 1 cm long and 1 cm wide structure with a 30 μm thick core pumped by Ti:sapphire laser with ~100 fs pulse duration and 8.5 μJ pulse energy. The generated frequency spectrum has a peak of ~0.4 THz width at ~2 THz.

The proposed structure can be a useful tool for characterization of the electromagnetic properties of metamaterials in the terahertz frequency range.

Acknowledgments

This work was supported in part by RFBR Grant Nos. 08-02-92216 and 09-02-12324. Two of the authors (M.I.B. and B.S.L.) gratefully acknowledge support from the THz S&T Inter-RI Program, project 082 141 0039 funded by A*STAR-SERC, Singapore.

References and links

1.	V. E. Pafomov, “On transition radiation and the Vavilov-Cherenkov radiation,” Zh. Eksp. Teor. Fiz. 36, 1853–1858 (1959) (Sov. Phys. JETP 9, 1321 (1959)).
2.	V. G. Veselago, “The electrodynamics of substances with simultaneously negative values of ε and μ,” Usp. Fiziol. Nauk 92, 517–526 (1967) (Sov. Phys. USPEKHI 10, 509–514 (1968)).
3.	J. Lu, T. Grzegorczyk, Y. Zhang, J. Pacheco Jr, B.-I. Wu, J. A. Kong, and M. Chen, “Cerenkov radiation in materials with negative permittivity and permeability,” Opt. Express 11(7), 723–734 (2003). [CrossRef] [PubMed]
4.	Yu. O. Averkov and V. M. Yakovenko, “Cherenkov radiation by an electron bunch that moves in a vacuum above a left-handed material,” Phys. Rev. B 72(20), 205110 (2005). [CrossRef]
5.	Z. Y. Duan, Y. B. Gong, Y. Y. Wei, W. X. Wang, B.-I. Wu, J. A. Kong, and M. Chen, “Theoretical investigation into Cherenkov radiation in an anisotropic double-negative medium,” in Proceedings of 33rd International Conference on Infrared, Millimeter, and Terahertz Waves, (Pasadena, Calif., 2008).
6.	Z. Y. Duan, B.-I. Wu, J. Lu, J. A. Kong, and M. Chen, “Reversed Cherenkov radiation in a waveguide filled with anisotropic double-negative metamaterials,” J. Appl. Phys. 104(6), 063303 (2008). [CrossRef]
7.	Z. Y. Duan, B.-I. Wu, J. Lu, J. A. Kong, and M. Chen, “Cherenkov radiation in anisotropic double-negative metamaterials,” Opt. Express 16(22), 18479–18484 (2008). [CrossRef] [PubMed]
8.	S. Antipov, L. Spentzouris, W. Gai, M. Conde, F. Franchini, R. Konecny, W. Liu, J. G. Power, Z. Yusof, and C. Jing, “Observation of wakefield generation in left-handed band of metamaterial-loaded waveguide,” J. Appl. Phys. 104(1), 014901 (2008). [CrossRef]
9.	S. Xi, H. Chen, T. Jiang, L. Ran, J. Huangfu, B.-I. Wu, J. A. Kong, and M. Chen, “Experimental verification of reversed Cherenkov radiation in left-handed metamaterial,” Phys. Rev. Lett. 103(19), 194801 (2009). [CrossRef]
10.	Z. Y. Duan, B.-I. Wu, S. Xi, H. S. Chen, and M. Chen, “Research progress in reversed Cherenkov radiation in double-negative metamaterials,” Progress In Electromagnetic Research PIER 90, 75–87 (2009). [CrossRef]
11.	G. A. Askar’yan, “Cherenkov radiation from optical pulses,” Phys. Rev. Lett. 57(19), 2470 (1986). [CrossRef] [PubMed]
12.	S. B. Bodrov, M. I. Bakunov, and M. Hangyo, “Efficient Cherenkov emission of broadband terahertz radiation from an ultrashort laser pulse in a sandwich structure with nonlinear core,” J. Appl. Phys. 104(9), 093105 (2008). [CrossRef]
13.	S. B. Bodrov, A. N. Stepanov, M. I. Bakunov, B. V. Shishkin, I. E. Ilyakov, and R. A. Akhmedzhanov, “Highly efficient optical-to-terahertz conversion in a sandwich structure with LiNbO3 core,” Opt. Express 17(3), 1871–1879 (2009). [CrossRef] [PubMed]
14.	L. Peng, L. Ran, H. Chen, H. Zhang, J. A. Kong, and T. M. Grzegorczyk, “Experimental observation of left-handed behavior in an array of standard dielectric resonators,” Phys. Rev. Lett. 98(15), 157403 (2007). [CrossRef] [PubMed]
15.	R. A. Shelby, D. R. Smith, and S. Schultz, “Experimental verification of a negative index of refraction,” Science 292(5514), 77–79 (2001). [CrossRef] [PubMed]
16.	S. O’Brien and J. B. Pendry, “Photonic band-gap effects and magnetic activity in dielectric composites,” J. Phys. Condens. Matter 14(15), 4035–4044 (2002). [CrossRef]
17.	C. M. Soukoulis, M. Kafesaki, and E. N. Economou, “Negative-index materials: new frontiers in optics,” Adv. Mater. 18(15), 1941–1952 (2006). [CrossRef]
18.	L. Pálfalvi, J. Hebling, J. Kuhl, Á. Péter, and K. Polgár, “Temperature dependence of the absorption and refraction of Mg-doped congruent and stoichiometric LiNbO₃ in the THz range,” J. Appl. Phys. 97(12), 123505 (2005). [CrossRef]
19.	J. Hebling, A. G. Stepanov, G. Almási, B. Bartal, and J. Kuhl, “Tunable THz pulse generation by optical rectification of ultrasort laser pulses with tilted pulse fronts,” Appl. Phys. B 78, 593–599 (2004). [CrossRef]
20.	B. Bartal, I. Z. Kozma, A. G. Stepanov, G. Almási, J. Kuhl, E. Riedle, and J. Hebling, “Toward generation of μJ range sub-ps THz pulses by optical rectification,” Appl. Phys. B 86(3), 419–423 (2007). [CrossRef]
21.	M. I. Bakunov, S. B. Bodrov, A. V. Maslov, and M. Hangyo, “Theory of terahertz generation in a slab of electro-optic material using an ultrashort laser pulse focused to a line,” Phys. Rev. B 76(8), 085346 (2007). [CrossRef]

OCIS Codes
(190.7110) Nonlinear optics : Ultrafast nonlinear optics
(230.4320) Optical devices : Nonlinear optical devices
(260.3090) Physical optics : Infrared, far

ToC Category:
Nonlinear Optics

History
Original Manuscript: December 3, 2009
Revised Manuscript: December 24, 2009
Manuscript Accepted: January 4, 2010
Published: January 14, 2010

Citation
M. I. Bakunov, R. V. Mikhaylovskiy, S. B. Bodrov, and B. S. Luk'yanchuk, "Reversed Cherenkov emission of terahertz waves from an ultrashort laser pulse in a sandwich structure with nonlinear core and left-handed cladding," Opt. Express 18, 1684-1694 (2010)
http://www.opticsinfobase.org/oe/abstract.cfm?URI=oe-18-2-1684

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References

V. E. Pafomov, “On transition radiation and the Vavilov-Cherenkov radiation,” Zh. Eksp. Teor. Fiz. 36, 1853–1858 (1959) (Sov. Phys. JETP 9, 1321 (1959)).
V. G. Veselago, “The electrodynamics of substances with simultaneously negative values of ε and μ,” Usp. Fiziol. Nauk 92, 517–526 (1967) (Sov. Phys. USPEKHI 10, 509–514 (1968)).
J. Lu, T. Grzegorczyk, Y. Zhang, J. Pacheco, B.-I. Wu, J. A. Kong, and M. Chen, “Cerenkov radiation in materials with negative permittivity and permeability,” Opt. Express 11(7), 723–734 (2003). [CrossRef] [PubMed]
Yu. O. Averkov and V. M. Yakovenko, “Cherenkov radiation by an electron bunch that moves in a vacuum above a left-handed material,” Phys. Rev. B 72(20), 205110 (2005). [CrossRef]
Z. Y. Duan, Y. B. Gong, Y. Y. Wei, W. X. Wang, B.-I. Wu, J. A. Kong, and M. Chen, “Theoretical investigation into Cherenkov radiation in an anisotropic double-negative medium,” in Proceedings of 33rd International Conference on Infrared, Millimeter, and Terahertz Waves, (Pasadena, Calif., 2008).
Z. Y. Duan, B.-I. Wu, J. Lu, J. A. Kong, and M. Chen, “Reversed Cherenkov radiation in a waveguide filled with anisotropic double-negative metamaterials,” J. Appl. Phys. 104(6), 063303 (2008). [CrossRef]
Z. Y. Duan, B.-I. Wu, J. Lu, J. A. Kong, and M. Chen, “Cherenkov radiation in anisotropic double-negative metamaterials,” Opt. Express 16(22), 18479–18484 (2008). [CrossRef] [PubMed]
S. Antipov, L. Spentzouris, W. Gai, M. Conde, F. Franchini, R. Konecny, W. Liu, J. G. Power, Z. Yusof, and C. Jing, “Observation of wakefield generation in left-handed band of metamaterial-loaded waveguide,” J. Appl. Phys. 104(1), 014901 (2008). [CrossRef]
S. Xi, H. Chen, T. Jiang, L. Ran, J. Huangfu, B.-I. Wu, J. A. Kong, and M. Chen, “Experimental verification of reversed Cherenkov radiation in left-handed metamaterial,” Phys. Rev. Lett. 103(19), 194801 (2009). [CrossRef]
Z. Y. Duan, B.-I. Wu, S. Xi, H. S. Chen, and M. Chen, “Research progress in reversed Cherenkov radiation in double-negative metamaterials,” Progress In Electromagnetic Research PIER 90, 75–87 (2009). [CrossRef]
G. A. Askar’yan, “Cherenkov radiation from optical pulses,” Phys. Rev. Lett. 57(19), 2470 (1986). [CrossRef] [PubMed]
S. B. Bodrov, M. I. Bakunov, and M. Hangyo, “Efficient Cherenkov emission of broadband terahertz radiation from an ultrashort laser pulse in a sandwich structure with nonlinear core,” J. Appl. Phys. 104(9), 093105 (2008). [CrossRef]
S. B. Bodrov, A. N. Stepanov, M. I. Bakunov, B. V. Shishkin, I. E. Ilyakov, and R. A. Akhmedzhanov, “Highly efficient optical-to-terahertz conversion in a sandwich structure with LiNbO3 core,” Opt. Express 17(3), 1871–1879 (2009). [CrossRef] [PubMed]
L. Peng, L. Ran, H. Chen, H. Zhang, J. A. Kong, and T. M. Grzegorczyk, “Experimental observation of left-handed behavior in an array of standard dielectric resonators,” Phys. Rev. Lett. 98(15), 157403 (2007). [CrossRef] [PubMed]
R. A. Shelby, D. R. Smith, and S. Schultz, “Experimental verification of a negative index of refraction,” Science 292(5514), 77–79 (2001). [CrossRef] [PubMed]
S. O’Brien and J. B. Pendry, “Photonic band-gap effects and magnetic activity in dielectric composites,” J. Phys. Condens. Matter 14(15), 4035–4044 (2002). [CrossRef]
C. M. Soukoulis, M. Kafesaki, and E. N. Economou, “Negative-index materials: new frontiers in optics,” Adv. Mater. 18(15), 1941–1952 (2006). [CrossRef]
L. Pálfalvi, J. Hebling, J. Kuhl, Á. Péter, and K. Polgár, “Temperature dependence of the absorption and refraction of Mg-doped congruent and stoichiometric LiNbO3 in the THz range,” J. Appl. Phys. 97(12), 123505 (2005). [CrossRef]
J. Hebling, A. G. Stepanov, G. Almási, B. Bartal, and J. Kuhl, “Tunable THz pulse generation by optical rectification of ultrasort laser pulses with tilted pulse fronts,” Appl. Phys. B 78, 593–599 (2004). [CrossRef]
B. Bartal, I. Z. Kozma, A. G. Stepanov, G. Almási, J. Kuhl, E. Riedle, and J. Hebling, “Toward generation of μJ range sub-ps THz pulses by optical rectification,” Appl. Phys. B 86(3), 419–423 (2007). [CrossRef]
M. I. Bakunov, S. B. Bodrov, A. V. Maslov, and M. Hangyo, “Theory of terahertz generation in a slab of electro-optic material using an ultrashort laser pulse focused to a line,” Phys. Rev. B 76(8), 085346 (2007). [CrossRef]

Adv. Mater.

C. M. Soukoulis, M. Kafesaki, and E. N. Economou, “Negative-index materials: new frontiers in optics,” Adv. Mater. 18(15), 1941–1952 (2006). [CrossRef]

Appl. Phys. B

J. Hebling, A. G. Stepanov, G. Almási, B. Bartal, and J. Kuhl, “Tunable THz pulse generation by optical rectification of ultrasort laser pulses with tilted pulse fronts,” Appl. Phys. B 78, 593–599 (2004). [CrossRef]
B. Bartal, I. Z. Kozma, A. G. Stepanov, G. Almási, J. Kuhl, E. Riedle, and J. Hebling, “Toward generation of μJ range sub-ps THz pulses by optical rectification,” Appl. Phys. B 86(3), 419–423 (2007). [CrossRef]

J. Appl. Phys.

L. Pálfalvi, J. Hebling, J. Kuhl, Á. Péter, and K. Polgár, “Temperature dependence of the absorption and refraction of Mg-doped congruent and stoichiometric LiNbO3 in the THz range,” J. Appl. Phys. 97(12), 123505 (2005). [CrossRef]
S. B. Bodrov, M. I. Bakunov, and M. Hangyo, “Efficient Cherenkov emission of broadband terahertz radiation from an ultrashort laser pulse in a sandwich structure with nonlinear core,” J. Appl. Phys. 104(9), 093105 (2008). [CrossRef]
Z. Y. Duan, B.-I. Wu, J. Lu, J. A. Kong, and M. Chen, “Reversed Cherenkov radiation in a waveguide filled with anisotropic double-negative metamaterials,” J. Appl. Phys. 104(6), 063303 (2008). [CrossRef]
S. Antipov, L. Spentzouris, W. Gai, M. Conde, F. Franchini, R. Konecny, W. Liu, J. G. Power, Z. Yusof, and C. Jing, “Observation of wakefield generation in left-handed band of metamaterial-loaded waveguide,” J. Appl. Phys. 104(1), 014901 (2008). [CrossRef]

J. Phys. Condens. Matter

S. O’Brien and J. B. Pendry, “Photonic band-gap effects and magnetic activity in dielectric composites,” J. Phys. Condens. Matter 14(15), 4035–4044 (2002). [CrossRef]

Opt. Express

Phys. Rev. B

Yu. O. Averkov and V. M. Yakovenko, “Cherenkov radiation by an electron bunch that moves in a vacuum above a left-handed material,” Phys. Rev. B 72(20), 205110 (2005). [CrossRef]
M. I. Bakunov, S. B. Bodrov, A. V. Maslov, and M. Hangyo, “Theory of terahertz generation in a slab of electro-optic material using an ultrashort laser pulse focused to a line,” Phys. Rev. B 76(8), 085346 (2007). [CrossRef]

Phys. Rev. Lett.

S. Xi, H. Chen, T. Jiang, L. Ran, J. Huangfu, B.-I. Wu, J. A. Kong, and M. Chen, “Experimental verification of reversed Cherenkov radiation in left-handed metamaterial,” Phys. Rev. Lett. 103(19), 194801 (2009). [CrossRef]
L. Peng, L. Ran, H. Chen, H. Zhang, J. A. Kong, and T. M. Grzegorczyk, “Experimental observation of left-handed behavior in an array of standard dielectric resonators,” Phys. Rev. Lett. 98(15), 157403 (2007). [CrossRef] [PubMed]
G. A. Askar’yan, “Cherenkov radiation from optical pulses,” Phys. Rev. Lett. 57(19), 2470 (1986). [CrossRef] [PubMed]

Progress In Electromagnetic Research

Z. Y. Duan, B.-I. Wu, S. Xi, H. S. Chen, and M. Chen, “Research progress in reversed Cherenkov radiation in double-negative metamaterials,” Progress In Electromagnetic Research PIER 90, 75–87 (2009). [CrossRef]

Science

R. A. Shelby, D. R. Smith, and S. Schultz, “Experimental verification of a negative index of refraction,” Science 292(5514), 77–79 (2001). [CrossRef] [PubMed]

Usp. Fiziol. Nauk

V. G. Veselago, “The electrodynamics of substances with simultaneously negative values of ε and μ,” Usp. Fiziol. Nauk 92, 517–526 (1967) (Sov. Phys. USPEKHI 10, 509–514 (1968)).

Zh. Eksp. Teor. Fiz.

V. E. Pafomov, “On transition radiation and the Vavilov-Cherenkov radiation,” Zh. Eksp. Teor. Fiz. 36, 1853–1858 (1959) (Sov. Phys. JETP 9, 1321 (1959)).

Other

Z. Y. Duan, Y. B. Gong, Y. Y. Wei, W. X. Wang, B.-I. Wu, J. A. Kong, and M. Chen, “Theoretical investigation into Cherenkov radiation in an anisotropic double-negative medium,” in Proceedings of 33rd International Conference on Infrared, Millimeter, and Terahertz Waves, (Pasadena, Calif., 2008).

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