Bow-Tie Cavity for Terahertz Radiation
Luigi Consolino, Annamaria Campa, Davide Mazzotti, Miriam Serena Vitiello, Paolo De Natale, Saverio Bartalini
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BowTie Cavity for Terahertz Radiation
Luigi Consolino * , Annamaria Campa , Davide Mazzotti , Miriam Serena Vitiello ,Paolo De Natale and Saverio Bartalini CNR–Istituto Nazionale di Ottica and LENS (European Laboratory for Nonlinear Spectroscopy), Via N.Carrara 1, 50019 Sesto Fiorentino (FI), Italy; [email protected] (A.C.); [email protected] (D.M.);[email protected] (P.D.N.); [email protected] (S.B.) NEST, CNR–Istituto Nanoscienze and Scuola Normale Superiore, Piazza San Silvestro 12, 56127 Pisa, Italy;[email protected]* Correspondence: [email protected]; Tel.: +390554572292Received: 23 November 2018; Accepted: 24 December 2018; Published: 25 December 2018
Abstract:
We report on the development, testing, and performance analysis of a bowtie resonantcavity for terahertz (THz) radiation, injected with a continuouswave 2.55 THz quantum cascadelaser. The bowtie cavity employs a wiregrid polarizer as input/output coupler and a pair of copperspherical mirrors coated with an unprotected 500 nm thick gold layer. The improvements with respectto previous setups have led to a measured finesse value F = 123, and a quality factor Q = 5.1 · . The resonator performances and the relevant parameters are theoretically predicted and discussed,and a comparison among simulated and experimental spectra is given.Keywords: resonant cavity; terahertz radiation; quantum cascade laser1. Introduction
Since their invention,optical resonators have represented an important optical tool for theirrole as a key element for laser action, for the investigation of coherent radiation properties, and forall purposes that require control and enhancement of laser light. For almost all the electromagneticspectrum, the physics of resonators has been well investigated with the experimental realization ofveryhighqualityfactor/finesse cavities, disclosing a large number of possible configurations [1–9] .However, among all possible applications, cavityenhanced spectroscopy has found increasingpopularity [ ]. In fact, thanks to the capability of confining and enhancing optical power inside a cell,and thanks to the development of advanced techniques, such as cavity ringdown spectroscopy (CRDS)or saturatedabsorption CRDS, highfinesse resonators have been able to reach sensitivity values down to parts per quadrillion (ppq) in trace gas sensing [11,12].In this regard, the possibility to develop resonant cavities for terahertz (THz) light has long been sought. Highsensitivity and highaccuracy spectroscopy of rotational and rovibrational moleculartransitions is indeed a key application in the terahertz (THz) spectral region, where transition lineintensities can be very high, even with respect to those in the IR and microwave regions. Nevertheless,if compared to other spectral regions, achievements of THz spectroscopy are still quite scarce, due to thelack of proper tools, such as highpower, tunable lasers, fast, sensitive, and reliable detectors, and also of a set of performing optical elements, such as optical isolators, highly reflective mirrors or coatings and so on. A number of experimental setups, based on different approaches,have been recentlydeveloped in order to push forward the limits of THz spectroscopy [ , ]. For example, in 2013,a Gunnoscillatorbased frequency multiplier chain provided 1 kHz accuracy in the determinationof a molecular transition line center (relative accuracy 1 · − ) [ ], but this setup could only be operated in the lower part of the THz spectrum. In 2014, frequency referenced THz quantum cascade Photonics hotonics , 1 2 of 8 lasers (QCLs) were successfully used for THz spectroscopy, achieving a relative accuracy of 4 · − [ ],and virtually giving access to the frequency window up to 4.5 THz, but with a limited tunability given by the characteristic of the single device. More recently, a novel setup based on differencefrequency generation has been reported, showing 10 − accuracy and a broad tunability from 1 to 7.5 THz [ , ], however, with the drawback of a low emitted power (~0.5 µ W). All these spectroscopic setups would hugely benefit from the development of highperformance THz resonators, that could help, in principle, to tear down the presentday limit of 10 relative accuracy. Resonant cavities for terahertz frequency light have been only developed in the last few years, due to the challenging lack of suitable materials and optical components; the best results reported to daterelies on a wire grid polarizer (WGP) as inputoutput coupler. When the polarization of the incoming light is parallel to the wires of a WGP, it acts as a mirror, but the small fraction of light leaking throughthe WGP allow coupling of the external radiation to the cavity.The first results were published inreference [ ], achieving Q factors as large as 10 in the subTHz range (around 300 GHz). In 2015, our group proposed WGPbased resonators providing Q factors of the same order (2.5 · ), but at muchhigher frequencies, i.e., 2.55 THz [20]. In this work, two different cavity geometries were investigated, namely Vshaped and ringshaped resonators.The Vshaped cavity was composed by a WGP and two spherical mirrors, which helped to minimize beam profile distortion. The main limitation of this approach was the unavoidable onresonance optical feedback (OF) on the laser source, inherent in thecavity geometry. Conversely, the ringshaped cavity approach, allowed for a zerofeedback resonance,but its performances were mainly limited by the presence of two 90 ◦ offaxis parabolic mirrors, leading to distortion of both shape and polarization of the cavity beam.In this paper, we propose an alternative cavity setup that overcomes the limitations of previous geometries, achieving a higher finesse. The necessity to have a ring geometry that minimizes thepresence of feedback, and the use of optical elements working at very small angles, such as plane orspherical mirrors, suggested the solution of a bowtie configuration, which is, by the way, the most common configuration in other spectral regions. Here we report on the experimental realization of a THz WGPbased bowtie resonator, to whichradiation from a 2.55 THz QCL is coupled. The devised cavity has been characterized, and its relevant parameters have been compared with the prediction of a theoretical model.2. Materials and MethodsThe bowtie cavity (BTC), as its name suggests, is designed such that the light traverses a closed path, as shown in Figure 1.The light is injected through a WGP tilted at a small angle with respectto the direction of the beam propagation. A plane mirror (PM) is placed to reflect the beam towardsa couple of identical spherical mirrors (SM), with the same effective focal length (200 mm), put in a position that closes the path of the beam on the WGP.
The angle of incidence θ of the light in cavity on the WGP, is defined by the geometry,i.e., by the distances between each reflective element ( l i , i = . . . , 4 ) , yielding the following mathematical expression: θ = arccos l + l l which for our case ( l = mm , l = mm , l = mm ) is equal to 13.9 ◦ , with a total cavity length of 490 mm.It is straightforward that the use of small incidence angles minimizes the effect of aberrations and preserves the high reflectivity of the mirrors, which are designed and manufactured for normal incidence.The gold coating of all the mirrors of the setup is made by chemical deposition (electroplating), hasa thickness of about 500 nm, and has no protective dielectric layer.The reflectivity of these mirrorsis supposed to be close to 99.5% [ ], but the measurements performed in the laboratory resulted in R M = (99.0 ± R WGP , T WGP , A
WGP ) = (99.2%, 0.4%, 0.4%) [5]. hotonics , 1 3 of 8 The bow-tie cavity (BTC), as its name suggests, is designed such that the light traverses a closed path, as shown in Figure 1. The light is injected through a WGP tilted at a small angle with respect to the direction of the beam propagation. A plane mirror (PM) is placed to reflect the beam towards a couple of identical spherical mirrors (SM), with the same effective focal length (200 mm), put in a position that closes the path of the beam on the WGP.
Figure 1. Configuration of the bowtie cavity consisting in a plane gold mirror, two gold sphericalmirrors (SM), and a wire grid polarizer (WGP) as input/output coupler. The red arrows indicate themotorized translating stage for the plane gold mirror.
The absorption in air at 2.55 THz due to water vapor should be included in the total losses of the
BTC, but it can be strongly reduced by purging the cavity with nitrogen. In absence of absorption from air and by taking into account the physical properties of the WGP and of the mirrors, we can define atheoretical finesse for the BTC as [22,23]: F = π − q R WGP R M returning a value of about 166. The estimation of the main BTC parameters has been made with the simulation programFinesse [ ], which requires an exact description of the geometry and properties of each elementof the cavity. The QCL beam can be described by a Gaussian beam (TEM ) and transverse modes (TEM nm ) that contribute with a small fraction of power and enlarge the beam waist from 1.8 mm (for TEM ) to 3.5 mm. The main theoretical parameters of the cavity are reported in Table 1, and are compared with the values retrieved from our previous geometries. At the same time Figure 2 shows a simulation of the BTC spectrum where the first higherorder transverse modes have been excited,besides the fundamental one. This general simulation will be used, in the following, for the analysis of the experimental BTC spectrum. Table 1. Main paramen comparison with the ones for the Vshapedters calculated for the bowtie cavity,i and ring cavities [20] (FSR: Free spectral range). All parameters are calculated in vacuum, apart fromcolumn F air reporting the finesse values taking into account the water vapor absorption coefficient of~0.0038 cm − [20].Cavity l (mm) FSR (MHz) F air F ∆ν (MHz) QFactorVshape 480 625 24 83 7.5 3.4 · Ring 480 625 22 65 9.6 2.7 · BTC 490 612 30 166 3.7 6.9 · hotonics , 1 4 of 8 Photonics , , x FOR PEER REVIEW of fundamental one. This general simulation will be used, in the following, for the analysis of the experimental BTC spectrum. Figure 2.
Simulation of the bow tie cavity (BTC) spectrum, showing contributions from higher-order transverse modes.
Table 1.
Main parameters calculated for the bow-tie cavity, in comparison with the ones for the V-shaped and ring cavities [20] (FSR: Free spectral range). All parameters are calculated in vacuum, apart from column F air reporting the finesse values taking into account the water vapor absorption coefficient of ~0.0038 cm −1 [20]. Cavity l (mm) FSR (MHz) F air F (MHz) Q-factor V-shape 480 625 24 83 7.5 3.4 · 10 Ring 480 625 22 65 9.6 2.7 · 10 BTC 490 612 30 166 3.7 6.9 · 10
3. Results
A sketch of the experimental setup is shown in Figure 3. The laser source is a QCL, with a bound-to-bound active region, emitting at 2.55 THz and mounted on the cold finger of a liquid helium cryostat. The QCL is driven in continuous-wave mode by a low-noise current driver at 370 mA with a fixed heat sink temperature T = 25 K. At this temperature the QCL threshold current is I th = 340 mA. The divergent QCL emission is collimated by an off-axis parabolic gold mirror, with an effective focal length of 25.4 mm, and guided by two plane mirrors to inject the cavity. To this purpose, the mode-matching conditions had to be satisfied by slightly focusing the beam towards the cavity with the parabolic mirror. Furthermore, the light emitted from a QCL can be described by an elliptical Gaussian beam with different divergences in the planes parallel and orthogonal to the epitaxial growth axis of its semiconductor heterostructure. Consequently, the mode-matching conditions had to be satisfied for both axes of the elliptical beam section. Between the collimating parabolic mirror and the cavity WGP, an optical system made of a half-wave plate (HWP) and a second wire-grid polarizer (WGP2) allows to choose the polarization of the electric field that will inject the cavity. In particular, the HWP allows us to rotate the linear QCL polarization, which is orthogonal to the growth axis, while the WGP2 cleans the polarization from residual components. The spectrum reflected by the cavity is then detected by a pyroelectric sensor aligned on the beam reflected by the Figure 2. Simulation of the bow tie cavity (BTC) spectrum, showing contributions from higherordertransverse modes.
A sketch of the experimental setup is shown in Figure 3. The laser source is a QCL, with aboundtobound active region, emitting at 2.55 THz and mounted on the cold finger of a liquid heliumcryostat. The QCL is driven in continuouswave mode by a lownoise current driver at 370 mA with a fixed heat sink temperature T = 25 K. At this temperature the QCL threshold current is I th = 340 mA. The divergent QCL emission is collimated by an offaxis parabolic gold mirror,with an effectivefocal length of 25.4 mm, and guided by two plane mirrors to inject the cavity.To this purpose, themodematching conditions had to be satisfied by slightly focusing the beam towards the cavity with theparabolic mirror. Furthermore, the light emitted from a QCL can be described by an elliptical Gaussian beam with different divergences in the planes parallel and orthogonal to the epitaxial growth axis of its semiconductor heterostructure. Consequently, the modematching conditions had to be satisfied forboth axes of the elliptical beam section. Between the collimating parabolic mirror and the cavity WGP,an optical system made of a halfwave plate (HWP) and a second wiregrid polarizer (WGP2) allows to choose the polarization of the electric field that will inject the cavity. In particular, the HWP allows usto rotate the linear QCL polarization, which is orthogonal to the growth axis, while the WGP2 cleans the polarization from residual components. The spectrum reflected by the cavity is then detected by a pyroelectric sensor aligned on the beam reflected by the WGP input coupler (QMC Instruments Ltd.,Cardiff, UK, mod. QWG/RT), composed by tungsten wires with a diameter of 10 µ m and spaced by µ m. The cavity is enclosed, by means of a plastic membrane, in nitrogen atmosphere, in order to purge out the water vapor that would induce additional intracavity losses. In order to tune the cavity length, the plane mirror of the cavity is mounted on a motorizedtranslation stage (Thorlabs Ltd., Ely, UK, mod. MTS25) controlled by a LabVIEW program, capableof setting the scanning speed (typical value 1.5 µ m/s), the total scan length (typically 200 µ m), the total scan time, and the acquisition rate. A chopper beam modulator and a lockin amplifier allow usto acquire the reflected spectrum. In particular, when the cavity is offresonance, the collected signalcorresponds to the total incoming power on the WGP, while, when it is in resonance, a fraction of the light will be coupled to the cavity and a power dip is expected to appear in the signal. A different kindof acquisition can be performed by substituting the chopper modulation with a modulation of the hotonics , 1 5 of 8 QCL driving current. In this case, when the BTC translation stage is tuned, the first derivative of thereflected spectrum is retrieved from the lockin demodulation. translation stage (Thorlabs Ltd., Ely, UK, mod. MTS25) controlled by a LabVIEW program, capable of setting the scanning speed (typical value 1.5 μm/s), the total scan length (typically 200 μm), the total scan time, and the acquisition rate. A chopper beam modulator and a lock-in amplifier allow us to acquire the reflected spectrum. In particular, when the cavity is off-resonance, the collected signal corresponds to the total incoming power on the WGP, while, when it is in resonance, a fraction of the light will be coupled to the cavity and a power dip is expected to appear in the signal. A different kind of acquisition can be performed by substituting the chopper modulation with a modulation of the QCL driving current. In this case, when the BTC translation stage is tuned, the first derivative of the reflected spectrum is retrieved from the lock-in demodulation.
Figure 3.
Experimental set-up. WGP and WGP2: Wire grid-polarizers, HWP: Half-wave plate.
4. Discussion
By measuring the beam waist at different distances from the cryostat it is possible to characterize the input beam parameters that can be regulated by finely moving the collimating parabolic mirror, in order to approach the mode-matching condition with the optical cavity. At that point, the alignment procedure is performed by looking at the experimental spectrum and comparing it with the simulated one reported in Figure 2. In this way, the transverse modes can be recognized, and the right corrections to the beam parameters can be applied, thus compensating either a wrong beam size or an off-axis alignment. Moreover, as said before, in our setup it is possible to rotate the linear polarization of the field injected into the cavity. This allows making a systematic measurement of the width of the resonance peak for different orientations of the polarization, and therefore of the corresponding WGP wires direction, as shown in Figure 4. In this way it is possible to identify two different effects, appearing in the two orthogonal orientations. On one side, when the polarization is set to vertical, the presence of partial reflection from the cylindrical wires is expected to generate a disturbing optical feedback (OF) to the QCL. Indeed, we can experimentally observe the presence of this OF in the configuration with vertical polarization, as shown in Figure 4 (large angles) and in the right-inset. Here, a clear broadening of the resonance peak is present, due to the typical laser frequency pulling effect. The effect of OF is expected to disappear for horizontal orientation of the WGP wires, as shown in the left inset of Figure 4. However, in this configuration, there is an angle θ between the beam polarization
Figure 3. Experimental setup. WGP and WGP2: Wire gridpolarizers, HWP: Halfwave plate.
By measuring the beam waist at different distances from the cryostat it is possible to characterizethe input beam parameters that can be regulated by finely moving the collimating parabolic mirror, in order to approach the modematching condition with the optical cavity. At that point, the alignment procedure is performed by looking at the experimental spectrum and comparing it with the simulatedone reported in Figure 2. In this way, the transverse modes can be recognized, and the rightcorrections to the beam parameters can be applied, thus compensating either a wrong beam size or an offaxis alignment.
Moreover, as said before, in our setup it is possible to rotate the linear polarization of the field injected into the cavity. This allows making a systematic measurement of the width of the resonance peak for different orientations of the polarization, and therefore of the corresponding WGP wiresdirection, as shown in Figure 4. In this way it is possible to identify two different effects, appearing in the two orthogonal orientations. On one side, when the polarization is set to vertical, the presence ofpartial reflection from the cylindrical wires is expected to generate a disturbing optical feedback (OF)to the QCL. Indeed, we can experimentally observe the presence of this OF in the configuration with vertical polarization, as shown in Figure 4 (large angles) and in the rightinset. Here, a clear broadeningof the resonance peak is present, due to the typical laser frequency pulling effect.The effect of OFis expected to disappear for horizontal orientation of the WGP wires, as shown in the left inset ofFigure 4. However, in this configuration, there is an angle θ between the beam polarization and thehorizontal orientation of the wires of the WGP. As a consequence, a fraction of the total field is not properly reflected, resulting in additional cavity losses, i.e., in a reduction of the finesse, as confirmed in Figure 4 (small angles). The tradeoff between the two effects results in maximum measured finessearound an operation angle of 70 ◦ , in order to minimize OF on the laser, while being as close as possible to the vertical position, i.e., maximum WGP reflectivity. In these conditions, i.e., with the nitrogenpurged air and with an orientation of the polarization at70 ◦ inside the cavity, the BTC achieves a measured finesse of 123, corresponding to a Qfactor of 5.1 · and an enhancement factor of 11.6. An experimental acquisition in these conditions is shown in Figure 5.The retrieved finesse value is considerably lower than the theoretically expected one of 166, which couldbe measured at 90 ◦ polarization angle.This effect can be confirmed by comparing an experimental spectrum and a simulated one, shown in Figure 5 as well. The behavior of the acquired spectrum can hotonics , 1 6 of 8 be reproduced exactly by considering a HermiteGauss profile with transverse electromagnetic modesTEM01, TEM01, and TEM11, and by using the parameters R M = 99% , R WGP = 97.9% . This alteration in the WGP characteristic value is due to the 70 ◦ at which we are operating. as close as possible to the vertical position, i.e., maximum WGP reflectivity. In these conditions, i.e., with the nitrogen-purged air and with an orientation of the polarization at 70° inside the cavity, the BTC achieves a measured finesse of 123, corresponding to a Q-factor of 5.1·10 and an enhancement factor of 11.6. An experimental acquisition in these conditions is shown in Figure 5. The retrieved finesse value is considerably lower than the theoretically expected one of 166, which could be measured at 90° polarization angle. This effect can be confirmed by comparing an experimental spectrum and a simulated one, shown in Figure 5 as well. The behavior of the acquired spectrum can be reproduced exactly by considering a Hermite-Gauss profile with transverse electromagnetic modes TEM01, TEM01, and TEM11, and by using the parameters R m = 99%, R WGP = 97.9%. This alteration in the WGP characteristic value is due to the 70° at which we are operating.
Figure 4.
Systematic analysis of the measured BTC finesse for different polarization orientations inside the cavity, i.e., different orientation of the WGP wires. The reported finesse values are still non-perfectly optimized. However, the two effects of optical feedback (OF) and additional cavity losses are visible. The insets show in detail the analysis of the peak width for different beam attenuations, corresponding to different feedback levels, when the wires of the WGP are vertically (inset-right) and horizontally (inset-left) oriented.
Figure 4. Systematic analysis of the measured BTC finesse for different polarization orientations insidethe cavity, i.e., different orientation of the WGP wires. The reported finesse values are still nonperfectlyoptimized. However, the two effects of optical feedback (OF) and additional cavity losses are visible.The insets show in detail the analysis of the peak width for different beam attenuations, correspondingto different feedback levels, when the wires of the WGP are vertically (insetright) and horizontally(insetleft) oriented.
Photonics , , x FOR PEER REVIEW of Figure 5.
Comparison between experimental (yellow) and simulated spectrum (blue) of the BTC in the experimental condition (R m = 99%, R WGP = 97.9%), achieving a finesse value of 123. The simulation is performed with the Finesse [24] software, and by using the parameters Rm = 99%, RWGP = 97.9%.
5. Conclusions
In conclusion, in this work a new geometry of a THz resonant cavity, i.e., a bow-tie cavity, is presented and tested by coupling it to the radiation of a 2.55 THz QCL. The resonator is based on gold mirrors and a free-standing WGP acting as an input/output coupler. After a theoretical discussion of the properties of the cavity, a complete characterization is reported, and the experimentally retrieved parameters are compared with the calculated ones. A measured finesse value of F = 123 proves that this is the first resonator with Q = 5.1·10 at THz frequencies, doubling the result previously achieved with different cavity geometries. The discrepancy between the measured and the expected finesse value is to be attributed to the non-perfectly vertical direction of the WGP wires, that, due to OF on the laser, represents the main limitation to the measurement. From Figure 5. Comparison between experimental (yellow) and simulated spectrum (blue) of the BTC in theexperimental condition ( R M = 99%, R WGP = 97.9%), achieving a finesse value of 123. The simulation isperformed with the Finesse [24] software, and by using the parameters R M = 99%, R WGP = 97.9%.
In conclusion, in this work a new geometry of a THz resonant cavity, i.e., a bowtie cavity, ispresented and tested by coupling it to the radiation of a 2.55 THz QCL. The resonator is based on gold mirrors and a freestanding WGP acting as an input/output coupler. After a theoretical discussion of hotonics , 1 7 of 8 the properties of the cavity, a complete characterization is reported, and the experimentally retrieved parameters are compared with the calculated ones. A measured finesse value of F = 123 proves that thisis the first resonator with Q = 5.1 · at THz frequencies, doubling the result previously achieved with different cavity geometries. The discrepancy between the measured and the expected finesse value isto be attributed to the nonperfectly vertical direction of the WGP wires, that, due to OF on the laser, represents the main limitation to the measurement.From the theoretical predictions the presentedcavity setup would be able to reach a finesse value of 166, while the limitation to the measurement can be overcome by trying a different input/output coupler, e.g., thin film plastic beam splitters with a thin gold layer on top.This should in principle return a reflection around 99%, and should avoid feedback effects on the laser, resulting in a measured finesse value of more than 158. Author Contributions: Experimental setup realization, L.C., A.C. and S.B.; conceptualization, L.C., D.M., P.D.N.and S.B.; software, A.C. and S.B.; validation, L.C., D.M. and S.B.; data curation, L.C. and S.B.; QCL fabricationsupervision, M.S.V.; writing—original draft preparation, L.C. and A.C.; writing—review and editing, all authors;supervision, P.D.N. and S.B.Funding: The authors acknowledge financial support by: European Union FETOpen grant 665,158—ULTRAQCLproject; European Union ERC Consolidator grant 681,379–SPRINT; European ESFRI Roadmap “Extreme LightInfrastructure”–ELI project; European Commission–H2020 LaserlabEurope, EC grant agreement number: 654148.Conflicts of Interest: The authors declare no conflict of interest.
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