Broadband terahertz pulse emission from ZnGeP_2

Rowley, J.; Pierce, Jacob; Brant, A. T.; Halliburton, L. E.; Giles, N. C.; Schunemann, Peter G.; Bristow, Alan D.

doi:10.1364/ol.37.000788

Cited by 33 publications

(17 citation statements)

References 19 publications

(31 reference statements)

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“…We use α to denote the polarization of the measured THz field, and for this work orthogonal components at α = β (parallel) and α = β + π/2 (perpendicular) were recorded. Detection was calibrated using a strong OR source [35]. The ω and 2ω pulses transmitted first through the substrate and then the TI to avoid stretching of the THz emission by the substrate [36].…”

Section: Methodsmentioning

confidence: 99%

Identification of photocurrents in topological insulators

Bas¹,

Muniz²,

Babakiray³

et al. 2016

Opt. Express

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Optical injection and detection of charge currents can complement conventional transport and photoemission measurements without the necessity of invasive contact that may disturb the system being examined. This is a particular concern for the surface states of a topological insulator. In this work one-and two-color sources of photocurrents are examined in epitaxial, thin films of Bi2Se3. We demonstrate that optical excitation and terahertz detection simultaneously captures one-and twocolor photocurrent contributions, as previously not required in other material systems. A method is devised to isolate the two components, and in doing so each can be related to surface or bulk excitations through symmetry. This strategy allows surface states to be examined in a model system, where they have independently been verified with angle-resolved photoemission spectroscopy.

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Section: Methodsmentioning

confidence: 99%

Identification of photocurrents in topological insulators

Bas¹,

Muniz²,

Babakiray³

et al. 2016

Opt. Express

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“…The quasi-static electric field of the THz induces birefringence in the ZnTe that is seen by the gate pulse and measured by projecting the orthogonal polarization components onto balanced photodetectors. 22 The signal is extracted using lock-in detection referenced to a mechanical chopper placed close to the laser source, which modulates the light at 250 Hz. The THz signal is mapped out in the time domain by varying the relative time delay between the emitted THz and the gate pulse.…”

mentioning

confidence: 99%

Coherent control of injection currents in high-quality films of Bi2Se3

Bas

Vargas-Velez

Babakiray

et al. 2015

Applied Physics Letters

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Films of the topological insulator Bi 2 Se 3 are grown by molecular beam epitaxy with in-situ reflection high-energy electron diffraction. The films are shown to be high-quality by X-ray reflectivity and diffraction and atomic-force microscopy. Quantum interference control of photocurrents is observed by excitation with harmonically related pulses and detected by terahertz radiation. The injection current obeys the expected excitation irradiance dependence, showing linear dependence on the fundamental pulse irradiance and square-root irradiance dependence of the frequency-doubled optical pulses. The injection current also follows a sinusoidal relative-phase dependence between the two excitation pulses.These results confirm the third-order nonlinear optical origins of the coherently controlled injection current. Experiments are compared to a tight-binding band structure to illustrate the possible optical transitions that occur in creating the injection current.2 Bi 2 Se 3 is a well-known thermoelectric material 1 and currently of great interest in condensed matter physics because the surface states exhibit massless Dirac dispersions in the gaps between the bulk valence and conduction bands. 2 The surface states have an electron spin structure defined by strong spin-orbit coupling which locks the spin vector perpendicular to the momentum vector. 3,4 Fundamental properties of Bi 2 Se 3 have been widely investigated because of the potential opportunities for developing spintronic and optically controlled devices.A great deal of attention has been paid to the light-matter interactions because the surface states of Bi 2 Se 3 are obscured in electrical measurements, due to inherent n-doping in the as-grown material. This means that the Fermi level is in the bulk conduction band above the 0.3-eV band gap. Despite this fact, optical measurements have been widely explored in the near infrared, revealing anomalous absorption coefficients with film thickness, 5 strong coupling between electrons and phonons 6,7 and a second set of massless surface states at about 1.7 eV above the commonly studied Dirac point below the Fermi level. 8 These developments, among others, 9 indicate that near-infrared optical interactions provide mechanisms that can be exploited for photonic devices and also access surface-surface state excitations. In which case, coupling of optical radiation to inject and control photocurrents is then relevant for the performance of this material system and coupling to the all-important surface states.Photocurrents in Bi 2 Se 3 have been predicted 10 and measured 11 using circular polarization, through the circular photogalvanic effect. Experimental studies have been performed in exfoliated Bi 2 Se 3 patterned with contacts that are sensitive to both photocurrents and photo-thermal currents. Nonetheless, this study has demonstrated that photocurrents can indeed be controlled. A more discrete scheme has been proposed for coherent control of the surface states using two-color quantum interference. 12 Quant...

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“…Power and Length Scalability Figure 2 (a) shows THz transients collected from the 0.33-mm, 0.92-mm and 3.03-mm ZGP(012) crystals, which are pumped with 1.28-μm radiation with intensity < 1 GW/cm 2 . The pump wavelength and intensity ensure the best phase-matching condition and that nonlinear absorption is negligible [24]. ZGP(012) is studied, because ZGP(110) is phase matched at the edge of the OPA tuning range; see Section 4B.…”

Section: Resultsmentioning

confidence: 99%

“…where z is the position inside the crystal, t is time, opt is the linear optical absorption and  is the 3PA coefficient. 2PA is neglected due to selected excitation wavelength [24].…”

Section: Resultsmentioning

confidence: 99%

“…OR in chalcopyrite ZnGeP2 (ZGP) shares attractive qualities with zincblende III-V semiconductors [24,25], including much lower FCA below ~3 THz compared with ZnTe and LiNbO3, smaller velocity mismatch in the near IR (NIR), large 2 nd -order nonlinear coefficients, and a 2PA edge at 1.1 μm. Thus, 2PA can be avoided in ZGP at phase-matched pump wavelengths, as is the case in GaP.…”

Section: Introductionmentioning

confidence: 99%

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Terahertz emission from ZnGeP_2: phase-matching, intensity, and length scalability

et al. 2013

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Collinear phase-matched optical rectification is studied in ZnGeP2 pumped with near-infrared light. The pumpintensity dependence is presented for three crystal lengths (0.3, 1.0 and 3.0 mm) to determine the effects of linear optical absorption, nonlinear optical absorption and terahertz free-carrier absorption on the generation. Critical parameters such as the coherence length (for velocity matching), dispersion length (for linear pulse broadening) and nonlinear length (for self-phase modulation) are determined for this material. These parameters provide insight into the upper limit of pulse intensity and crystal length required to generate intense terahertz pulse without detriment to the pulse shape. It is found that for 1-mm thick ZnGeP2(012), pumped at 1.28 m with intensity of ~15 GW/cm 2 will produce intense undistorted pulses, whereas longer crystals or larger intensities modify the pulse shape to varying degrees. Moreover, phase-matching dispersion maps are presented for the terahertz generation over a large tuning range (1.1-2.4 m) in longer (3 mm) crystal, demonstrating the phasematching bandwidth and phase mismatch that leads to fringing associated with multi-pulse interference. All observed results are simulated numerically showing good qualitative agreement.

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Broadband terahertz pulse emission from ZnGeP_2

Cited by 33 publications

References 19 publications

Identification of photocurrents in topological insulators

Identification of photocurrents in topological insulators

Coherent control of injection currents in high-quality films of Bi2Se3

Terahertz emission from ZnGeP_2: phase-matching, intensity, and length scalability

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