Angular Tuning Research Articles

Noncollinear optical parametric oscillator with periodically poled KTP

We demonstrate efficient noncollinear low-threshold optical parametric oscillation in periodically poled KTP crystal pumped by the second harmonic of the Q-switched Nd:YAG laser. The noncollinear geometry provides an angular frequency tuning at fixed temperature.

Theoretical evaluation of LiGaO_2 for frequency upconversion to ultraviolet

First-principles calculations of the frequency-dependent birefringence, second-harmonic generation, and linear electro-optic response are reported for LiGaO2 (which is transparent to as small as 222 nm). Good agreement is obtained with available experimental data in the visible region of the spectrum. The calculated frequency-dependent nonlinear optical responses are surprisingly constant in the entire energy region below the gap and small in absolute value (of the order of 0.2–1.2 pm/V for the various structures considered). Although the birefringence is insufficient for second-harmonic generation into the ultraviolet, opportunities may exist for sum-frequency generation. Angular phase-matching tuning curves are provided. The reasons for the low values of χ(2) are discussed. It is found to be not very sensitive to the structure and to arise in part from a large degree of cancellation between pure interband and mixed intra- and interband contributions.

Mid-infrared optical parametric generator with extra-wide (3–19-μm) tunability: applications for spectroscopy of two-dimensional electrons in quantum wells

Using a λ=2.8 µm pump makes it possible to take full advantage of notable nonlinear optical properties of the infrared crystals ZnGeP2, CdSe, and GaSe to achieve efficient mid-infrared frequency downconversion. Traveling-wave optical parametric generators with angular tuning were pumped by single 100-ps 2.8-µm Er,Cr:YSGG laser pulses. The continuous tuning range achieved was 3.9–10 µm (ZnGeP2), 3.57–4.3 and 8–13 µm (CdSe), and 3.3–19 µm (GaSe), with a quantum conversion efficiency of typically 10% and the lowest, to the author’s knowledge, threshold ever obtained for a traveling-wave optical parametric generator. A dual-wavelength optical parametric generator was used for nonlinear spectroscopy of intersubband transitions of conduction-band electrons, quantum confined in semiconductor quantum wells, as well as for the study of intersubband-based resonantly enhanced χ(2) in quantum wells.

Optimized blue light generation in optically contacted walk-off compensated RbTiOAsO 4 and KTiOP 1− yAs yO 4

We study type II 1.32 μm second harmonic generation (SHG) in a RbTiOAsO 4 optically contacted walk-off compensated device. The reduction of the effective walk-off angle by a factor of 3.7 with respect to KTiOPO 4 for the same interaction leads to an enhancement by a factor of 10 of the conversion efficiency. A model is proposed for both type I and type II SHG in such a structure. The angular tuning curve is a multi-peaked one, as predicted by the model. The enhancement of the SHG conversion efficiency allows us to optimize the generation of blue laser light at 440 nm: a specially designed KTiOP 0.98As 0.02O 4 solid solution crystal achieves angular non-critical phase matching at room temperature for type II sum frequency generation 1.32 μm+0.66 μm→0.44 μm.

Angular and temperature tuning characteristics of an optical parametric oscillator based on a KTiOPO4 crystal

Measurements were made of the wavelengths of the radiation generated in an optical parametric oscillator based on a KTiOPO4 crystal. This was done for nonlinear elements with different cuts in the XY plane. The crystal was pumped with radiations from Nd3+:YAG and Nd3+:YA lasers. The temperature dependences of the output wavelengths were calculated and determined experimentally. There was a disagreement between the experimental and calculated angular and temperature tuning characteristics, which resulted from the influence of the absorption edge of the KTiOPO4 crystal at the idler-wave tuning wavelengths 3.26–3.52 μm.

Nonlinear alignment between conical emissions generated in a four-wave parametric mixing process

P levels. A numerical model developed to describe mechanisms involved in the conical emission generation processes indicates that the saturation observed is due to the opposite angular tuning of the near-infrared and yellow conical emission generated in the same process. The mechanisms responsible are assigned to (self)induced phase modulation processes of the waves involved.

Variations in photoreceptor directionality across the central retina

Cones show a differential sensitivity to light coming from different portions of the pupil, typically being most sensitive to light from the center of the pupil. We measured the directional properties of the cones across the central 6 deg of the retina, using an optical imaging technique. We find that the cones in the center of the fovea have the broadest tuning. The width of the angular tuning changes rapidly from 0 deg to 1 deg retinal eccentricity, with cones at 1 deg being much more narrowly tuned that the cones in the center of the fovea. Directional tuning of the cones remains relatively constant from 1 deg to 3 deg retinal eccentricity. Receptoral disarray contributes minimally to the measured directional properties of the foveal cones, and there is no evidence of asymmetry between horizontal and vertical retinal locations. There are only small differences among the five subjects in the change in angular tuning of the cones with retinal location. We find that at the foveal center the directional tuning of the cones is limited by the diameter of the cone apertures.

The honeybee ( Apis mellifera) detects bilateral symmetry and discriminates its axis

Honeybees were trained and tested with a choice between a black and white pattern composed of two pairs of equal orthogonal bars with bilateral symmetry and the same or a similar pattern with a different symmetry. The targets subtended < 50 ° at the point of choice. Earlier results with the chevron pattern revealed that discrimination of rotation is improved when one of the patterns is bilaterally symmetrical about a vertical axis. Bees were trained on 7 different pairs of 4-bar patterns at the same time, taken successively to prevent the bees from learning any one pattern. The bees learned to discriminate a pattern with bilateral symmetry from one without symmetry, irrespective of the orientation of the axis of symmetry. They also discriminate between a pattern with one axis of bilateral symmetry and the same pattern rotated by 90 °, irrespective of the actual pattern. Although the patterns are regularly changed during the training, the bees distinguish the axis of bilateral symmetry. When trained on one set of patterns, the bees also discriminate the axis in the same or other patterns rotated through 180 °, when all bars have moved over to the other side, showing that they have not remembered one side of the pattern with each eye. For one pattern, the angular tuning curve for the discrimination of the axis of symmetry falls from a score of 80% correct on-axis to near 67% at 15 ° off-axis and 50% (random) at 30 ° off-axis.

Spatial gradients and inhibitory summation in the rat whisker barrel system

1. Extracellular single-unit recordings and controlled whisker stimuli were used to compare response properties of cells in the barreloids of the ventral posterior medial nucleus of the thalamus and the barrels in the rat primary somatosensory cortex. Whiskers were deflected alone or in combinations involving up to four immediately adjacent whiskers to assess their relative inhibitory and excitatory contributions to individual receptive fields. Quantitative data were obtained from 51 thalamocortical units (TCUs), 79 "regular-spiking" barrel neurons (RSUs), and 5 "fast-spiking" barrel neurons (FSUs) in 28 normal female adult rats. 2. A random-noise generator was used to produce small, continuously varying whisker movements that were applied to one to four adjacent whiskers while the principal (columnar) whisker was displaced with the use of a ramp-and-hold deflection. RSUs displayed adjacent whisker-evoked inhibition that increased as the number of adjacent whiskers stimulated was incremented. Asymptotic levels of inhibition were reached with the application of the noise stimulus to two or three adjacent whiskers depending on which particular combinations were deflected. By contrast, TCUs and FSUs showed weak, or no, surround inhibition. 3. As the number of adjacent whiskers stimulated increased, the background (prestimulus) activity in TCUs and FSUs increased, whereas displayed background activity in RSUs was relatively unaffected. The increase in background activity observed in the FSUs is hypothesized to mediate adjacent whisker-evoked inhibition in the RSUs. 4. A spatial gradient of adjacent whisker inhibition was observed in RSUs. The caudally adjacent whisker evoked more inhibition than the rostrally adjacent whisker, and the ventral more than the dorsal. A cortical origin for the gradient is suggested by the finding that TCUs did not show a spatial inhibitory gradient. 5. As the noise stimulus was applied to an increasing number of adjacent whiskers, RSUs became more sharply tuned for deflection angles. Neither TCUs nor FSUs showed increases in angular tuning. 6. Inhibition worked disproportionately in RSUs to inhibit those responses that were initially the least robust. For example, inhibition was most effective at reducing responses to nonpreferred versus preferred whisker deflection angles. 7. To assess the principal whisker's effect on adjacent whisker excitatory responses, the noise stimulus was applied to the principal whisker. In RSUs, principal whisker-evoked inhibition was more potent than adjacent whisker-evoked inhibition. FSUs were excited to a greater extent by the application of the noise stimulus to the principal whisker than to adjacent whiskers. TCUs did not display principal whisker-evoked inhibition. 8. Inhibition within the barrel serves as a contrast enhancement mechanism to differentiate small versus large magnitude responses. Less vigorous responses, such as those associated with perturbations of noncolumnar whiskers and inputs from nonoptimal deflection angles, are more strongly suppressed. During active touch, when many whiskers simultaneously palpate an object, these inhibitory interactions could effectively increase the "principal whiskerness" of the cortical column.

Quantitative effects of GABA and bicuculline methiodide on receptive field properties of neurons in real and simulated whisker barrels.

1. Carbon fiber multibarrel glass microelectrodes were used to record extracellular single-unit activity during microiontophoretic application of gamma-aminobutyric acid (GABA) or bicuculline methiodide (BMI) onto layer IV barrel neurons in the somatosensory cortex of fentanyl-sedated rats. Excitatory and inhibitory aspects of the neurons' receptive fields were quantified with the use of controlled whisker stimuli. The principally activating whisker and one of its immediately adjacent neighbors were deflected alone or in paired combinations involving a condition-test paradigm. 2. Units were distinguished electrophysiologically on the basis of the time course of their action potential waveforms. Data were obtained from 26 regular-spike units (RSUs; presumed spiny stellate cells) and 7 fast-spike units (FSUs; presumed GABAergic neurons). An average of 15.0 nA of GABA produced a one-third to one-half reduction in RSU responses evoked by the maximally effective stimulus. An average of 8.7 nA of BMI was needed to counteract this reduction. This amount of BMI, in the absence of exogenous GABA, was found to increase average RSU and FSU responses by 98 and 53%, respectively, relative to predrug levels. 3. For RSUs, the BMI-induced twofold increase in responses evoked by moving the principal whisker at the neuron's best deflection angle was accompanied by an almost threefold increase in responses evoked by similarly moving an adjacent whisker. Disproportionately large percentage increases were also seen for responses to nonpreferred directions of principal and adjacent whisker movement. BMI thus effectively increased receptive field size and decreased angular tuning. Similarly, responses to stimulus offsets, which are normally smaller than ON responses, were increased proportionally more. 4. Predrug responses of FSUs were more vigorous than those of RSUs. However, FSUs showed a similar inverse relationship between percentage increase with BMI and initial response magnitude, although the proportional increases were less pronounced. 5. GABA, like BMI, had the greatest proportional effects on those responses that were initially smallest. It produced results opposite those of BMI, effectively decreasing receptive field size and sharpening angular tuning. 6. A previously described computational model of a barrel was tested for its ability to reproduce quantitatively the effects of BMI and GABA. The application of BMI was simulated by decreasing the strength of the inhibitory inputs onto the particular cell under study in the model network. GABA microiontophoresis was simulated by adding a constant hyperpolarizing voltage. The model RSUs and FSUs displayed proportional changes in response magnitude that were quantitatively similar to those of their biological counterparts. 7. Surround inhibition was greatly attenuated by BMI application, both for the real and simulated barrel neurons. Disinhibition was less pronounced for the former, perhaps because, unlike the simulated neurons, they also possess GABAB receptors, which are unaffected by BMI. 8. We conclude that the inhibitory receptive field properties of barrel neurons can be explained by intrabarrel inhibition and that the expansion of receptive field size and loss of angular tuning with BMI is due to an enhanced effectiveness of convergent, multi-whisker thalamocortical input. Examination of the model neurons' behavior suggests that the altered activity in response to GABA or BMI application, respectively, can be explained by the nonlinear effects of shifting somal membrane potential away from or toward the neuron's firing threshold.

Fixed-exit double-crystal monochromator for the diffraction beamline at ELETTRA: A new concept for crystal movements

A fixed-exit double-crystal x-ray monochromator has been constructed for use at the macromolecular crystallography beamline at the Sincrotrone Trieste. For its design a new concept has been developed, which is based on a single rotational stage to control the ϑ or Bragg angle for both the first and second crystal. The stage rotation axis lies in the center of the surface of the first crystal, thus the incoming photon beam remains centered on it over the whole tuning range, which opens the possibility to, e.g., optimize the crystal cooling system. The fixed-exit aspect of the monochromator is achieved by translating the second crystal on one slide only forming an angle α with the surface of this crystal. In this way the translation distance can be kept small thus minimizing detuning effects of the monochromator due to not-perfect slides. The cost is, that during energy scans the beam footprint will wander somewhat on the second crystal surface. It is demonstrated that, by choosing a suitable angle α, both the translation distance T and the length of the second crystal can be reasonably minimized. In fact, e.g., a monochromator having a vertical beam offset of 17 mm and an angular tuning range 5°–30°, T can be kept as small as 25 mm by not even doubling the length of the second crystal with respect to the first one.

Parametric generation of tunable infrared radiation in ZnGeP_2 and GaSe pumped at 3 μm

Traveling-wave parametric generators with angular tuning with the use of ZnGeP2 and GaSe crystals pumped by 100-ps pulses from an actively mode-locked Er laser (λ ≈ 3 μm) are reported. The continuous-tuning range achieved was 4–10 μm (ZnGeP2; length, 12 mm) and 3.5–18 μm (GaSe; length, 12 mm) in a type-I interaction, with a quantum conversion efficiency of a few percent. In the case of ZnGeP2 (length, 42 mm) and type-II phase matching, the pump threshold was 0.35 GW/cm2 and the quantum efficiency achieved was 17.6%, corresponding to an output peak power of 3 MW near 5–6 μm.

Broadband second-harmonic generation in SrxBa1−xNb2O6 by spread spectrum phase matching with controllable domain gratings

We have demonstrated, for the first time to our knowledge, second-harmonic generation for a broad input wavelength range of 750–1064 nm in SrxBa1−xNb2O6 crystals, with a controllable spread spectrum of quasiphase matching. Second-harmonic conversion efficiencies of up to ∼1% were observed. This was done without any temperature or angular tuning of the crystal. The phase matching was obtained by inducing alternating ferroelectric domains in the crystal in real time, using a novel fixing process which is based on screening. The broadband capability of the conversion is allowed by a spread in the range of the domain widths.

Second-harmonic generation in KNbO3 crystals

Efficient second-harmonic generation from a pulsed parametric laser to 427 to 470 nm has been obtained in a KNbO3 crystal only 1.5 mm in length by angular tuning at room temperature. The energy conversion efficiency is over 40%. Single pulse blue light output reaches 60 kW in peak power. The angular dependence of a phase matching wavelength, the relation between conversion efficiency and fundamental intensity, and acceptable angular phase mismatch are studied and discussed.

Growth and optical properties of nonlinear silver selenogallate single crystals

Large crystals of silver selenogallate were grown. Generation of the second harmonic of CO2 laser radiation in these crystals was studied. An energy conversion efficiency of 19.8% was achieved. Calculations were made of the angular tuning characteristics of optical parametric oscillators using type I and II processes at various pump wavelengths.

Comparison between collinear and noncollinear phase matching for second-harmonic and sum-frequency generation in 3-methyl-4-nitropyridine-1-oxide

The effects of finite beamwidth and absorption on the collinear and one-beam noncritical noncollinear phase-matched second-harmonic generation (SHG) and sum-frequency generation (SFG) processes in 3-methyl-4-nitropyridine-1-oxide (POM) are investigated. Expressions for the generated powers from the collinear and noncollinear phase-matching configurations are given and compared for near-field Gaussian nondepleted input beams. Two ways to improve the efficiency of general type II phase-matched SHG or SFG processes are suggested. The angular tuning characteristics of collinear and noncollinear phase-matched processes in POM are discussed theoretically and experimentally.

Sellmeier equation and tuning characteristics of KTP crystal frequency converters in the 0.4–4.0 μm range

Constants of the Sellmeier equations were determined for a KTP crystal in the 0.4–4.0 μm wavelength range. Calculations were made of the angular tuning characteristics for various types of interaction in the principal crystal planes. Some of the tuning characteristics were checked experimentally.

High-efficiency picosecond parametric superradiance emitted by a ZnGeP2crystal in the 5–6.3 µ range

Highly efficient (quantum efficiency 17%) parametric superradiance was generated in a nonlinear ZnGeP2 crystal of length 4.2 cm pumped by single (of energy ~1 mJ) ultrashort pulses (τ = 150 psec) from an erbium laser (λ = 2.79 µ). High-power (~1 MW) continuously tunable infrared radiation of wavelengths 5–5.3 and 5.9–6.3 µ was obtained. The energy and angular tuning characteristics, line width, divergence, and gain of this superradiance were determined. The nonlinear coefficient d36 was found for ZnGeP2. Depletion of the laser pumping had to be allowed for already for parametric superradiance efficiency of just 0.1%.

Spatial, angular, and spectral changes of radiation emitted from lasers utilizing vapors of complex organic compounds

An analysis is made of whether, in principle, it is possible to utilize the observed rapid displacement of a lasing zone in a vapor under the action of pumping for the purpose of continuous angular and spectral tuning of laser radiation at rates of 109 rad/sec and 1010 nm/sec and to transmit data by means of such a medium at a velocity higher than the velocity of light in this medium.

Band structure dependent damping in photoemission from copper

A simple model of damping of excited electrons in crystals is investigated, and the consequent broadening of angular resolved photoemission spectra is discussed. For a photon energy of 11.7 eV the exit angle dependence of the peak width of photoelectrons emanating from the sp band of Cu(111) is estimated from lifetime and band structure data and compared with the authors previously published spectra. A predicted sharp linewidth enhancement and maximum for k/sub /// approximately=0.83 pi /a along Gamma M is seen experimentally by a more gradual rise saturating at k/sub /// approximately=0.75 pi /a. Finally, angular tuning is used to obtain electron inverse lifetimes in copper of 2.7+or-0.4 eV and 3.5+or-0.4 eV at energies of 16.6 and 20.7 eV above the Fermi level, respectively.