Abstract-Spectrally resolved far-fields of terahertz quantum cascade lasers

Martin Brandstetter, Sebastian Schönhuber, Michael Krall, Martin A. Kainz, Hermann Detz, Tobias Zederbauer, Aaron M. Andrews, Gottfried Strasser, Karl Unterrainer

(Submitted on 18 Aug 2016)

https://arxiv.org/abs/1608.05257

We demonstrate a convenient and fast method to measure the spectrally resolved far-fields of multimode terahertz quantum cascade lasers by combining a microbolometer focal plane array with an FTIR spectrometer. Far-fields of fundamental TM0 and higher lateral order TM1 modes of multimode Fabry-P\'erot type lasers have been distinguished, which very well fit to the results obtained by a 3D finite-element simulation. Furthermore, multimode random laser cavities have been investigated, analyzing the contribution of each single laser mode to the total far-field. The presented method is thus an important tool to gain in-depth knowledge of the emission properties of multimode laser cavities at terahertz frequencies, which become increasingly important for future sensing applications.

Abstract-InAs based terahertz quantum cascade lasers

Martin Brandstetter^1,a), Martin A. Kainz¹, Tobias Zederbauer²,Michael Krall¹, Sebastian Schönhuber¹, Hermann Detz³, Werner Schrenk², Aaron Maxwell Andrews², Gottfried Strasser² and Karl Unterrainer¹
 HIDE AFFILIATIONS
1 Photonics Institute and Center for Micro- and Nanostructures, Technische Universität Wien, Gusshausstrasse 27-29, 1040 Vienna, Austria
2 Institute for Solid State Electronics and Center for Micro- and Nanostructures, Technische Universität Wien, Floragasse 7, 1040 Vienna, Austria
3 Austrian Academy of Sciences, Dr. Ignaz Seipel-Platz 2, 1010 Vienna, Austria
a) Electronic mail: martin.brandstetter@tuwien.ac.at
Appl. Phys. Lett. 108, 011109 (2016); http://dx.doi.org/10.1063/1.4939551

http://scitation.aip.org/content/aip/journal/apl/108/1/10.1063/1.4939551?TRACK=RSS

We demonstrate terahertz lasing emission from a quantum cascade structure, realized with InAs/AlAs0.16Sb0.84heterostructures. Due to the lower effective electron mass, InAs based active regions are expected to provide a higher optical gain compared to structures consisting of GaAsor InGaAs. The growth by molecular beam epitaxy enabled the fabrication of monolayer-thick barriers, required for the active region, which is based on a 3-well resonantphonon depletion design. Devices were processed in a double-metal waveguide geometry to ensure high mode confinement and low optical losses. Lasing emission at 3.8 THz was observed at liquid helium temperatures by applying a magnetic field perpendicular to the layered structure in order to suppress parasitic scattering channels. These results demonstrate the feasibility of InAs based active regions for terahertz quantum cascade lasers, potentially enabling higher operating temperatures.

Abstract-Coupled cavity terahertz quantum cascade lasers with integrated emission monitoring

Coupled cavity terahertz quantum cascade lasers with integrated emission monitoring Michael Krall, Michael Martl, Dominic Bachmann, Christoph Deutsch, Aaron M. Andrews, Werner Schrenk, Gottfried Strasser, and Karl Unterrainer  »View Author Affiliations

http://www.opticsinfobase.org/oe/abstract.cfm?uri=oe-23-3-3581

Optics Express, Vol. 23, Issue 3, pp. 3581-3588 (2015)
http://dx.doi.org/10.1364/OE.23.003581

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We demonstrate the on-chip generation and detection of terahertz radiation in coupled cavity systems using a single semiconductor heterostructure. Multiple sections of a terahertz quantum cascade laser structure in a double-metal waveguide are optically coupled and operate either as a laser or an integrated emission monitor. A detailed analysis of the photon-assisted carrier transport in the active region below threshold reveals the detection mechanism for photons emitted by the very same structure above threshold. Configurations with a single laser cavity and two coupled laser cavities are studied. It is shown that the integrated detector can be used for spatial sensing of the light intensity within a coupled cavity.

© 2015 Optical Society of America

Abstract-Subwavelength micropillar array terahertz lasers

Michael Krall, Martin Brandstetter, Christoph Deutsch, Hermann Detz, Aaron Maxwell Andrews, Werner Schrenk, Gottfried Strasser, and Karl Unterrainer  »View Author Affiliations

We report on micropillar-based terahertz lasers with active pillars that are much smaller than the emission wavelength. These micropillar array lasers correspond to scaled-down band-edge photonic crystal lasers forming an active photonic metamaterial. In contrast to photonic crystal lasers which use significantly larger pillar structures, lasing emission is not observed close to high-symmetry points in the photonic band diagram, but in the effective medium regime. We measure stimulated emission at 4 THz for micropillar array lasers with pillar diameters of 5 µm. Our results not only demonstrate the integration of active subwavelength optics in a terahertz laser, but are also an important step towards the realization of nanowire-based terahertz lasers.

© 2014 Optical Society of America

The world's most powerful terahertz quantum cascade laser

 

http://www.sciencecodex.com/the_worlds_most_powerful_terahertz_quantum_cascade_laser-122027

Terahertz waves are invisible, but incredibly useful; they can penetrate many materials which are opaque to visible light and they are perfect for detecting a variety of molecules. Terahertz radiation can be produced using tiny quantum cascade lasers, only a few millimetres wide. This special kind of lasers consists of tailor made semiconductor layers on a nanometer scale. At the Vienna University of Technology (TU Vienna) a new world record has now been set; using a special merging technique, two symmetrical laser structures have been joined together, resulting in a quadruple intensity of laser light.

Jumping Electrons Create Terahertz Light

For the electrons in each layer of the quantum cascade laser, only certain discrete energy levels are allowed. If the right electrical current is applied, the electrons jump from layer to layer, in each step emitting energy in the form of light. This way, the exotic terahertz radiation with wavelengths in the sub-millimetre regime (between microwaves and infrared) can be produced with high efficiency.

Christoph Deutsch, Martin Brandstetter and Michael Krall in the cleanroom at Vienna University of Technology (TU Vienna).

(Photo Credit: TU Vienna)

 

Many molecules absorb light of this spectral region in a very characteristic way – they can be considered to have an "optical fingerprint". Because of this, terahertz radiation can be used for chemical detectors. It also plays an important role for medical imaging; one the one hand, it is non-ionizing radiation, its energy is considerably lower than that of roentgen radiation, therefore it is not dangerous. On the other hand, its wavelength is shorter than that of microwave radiation, which means that it can be used to create higher resolution images.

These applications may bring back memories of the legendary "Tricorder" from Star Trek, a portable multi-purpose analytical instrument. For measuring objects at a distance and for medical imaging, compact light sources with a very high optical power are required.

A possible way to increase the laser power is to use more semiconductor layers. A higher number of layers means that the electron changes its energy states when it passes through the structure, and therefore the number of emitted photons increases. The production of such multi-layer structures, however, is extremely difficult. Prof. Karl Unterrainer's team at the Institute of Photonics at the Vienna University of Technology has now succeded in merging two separate quantum cascade lasers in a so-called bonding process.

 

 

The newly developed quantum cascade laser (QCL) at the Vienna University of Technology is displayed.

(Photo Credit: TU Vienna)

"This only works for a very specific design of the quantum cascade structure", says Christoph Deutsch (TU Vienna), "With standard quantum cascade lasers, this would definitely be impossible." Symmetrical lasers are required, through which electrons can pass in both directions. The team had to study and compensate for the asymmetries which usually arise in the laser.

The World Record Laser

The higher the number of layers, the more photons are produced. In addition to that, the efficiency is increased due to improved optical properties. "This is why doubling the number of layers eventually leads to quadruple power", explains Martin Brandstetter (TU Vienna). The previous world record for terahertz quantum cascade lasers of almost 250 milliwatts was held by the Massachussetts Institute of Technology (MIT). The laser of TU Vienna now produces one watt of radiation. This is not only another record for TU Vienna, breaking the one-watt barrier is considered to be an important step for the application of terahertz lasers in a variety of technological fields.

Two lasers are connected, creating a larger and much more efficient one.

(Photo Credit: TU Vienna)

Abstract-Magnetic-field assisted performance of InGaAs/GaAsSb terahertz quantum cascade lasers

Simon Maëro¹, Louis-Anne de Vaulchier¹, Yves Guldner¹,Christoph Deutsch², Michael Krall², Tobias Zederbauer³,Gottfried Strasser³, and Karl Unterrainer^{2
http://apl.aip.org/resource/1/applab/v103/i5/p051116_s1?isAuthorized=no&}

We report on a magnetic-field investigation of a In_0.53Ga_0.47As/GaAs_0.51Sb_0.49terahertz quantum cascade laser. Owing to the suppression of inter-Landau level non-radiative scattering, the device performances are strongly improved at high magnetic field. Working temperature up to 190 K and current threshold of 450 A/cm² are measured at 11 T, comparable to the state-of-the-art GaAs/AlGaAs terahertz lasers. The nominally symmetric three-well structure presents significantly better performance with negative bias polarisation because of the inverted-interface roughness impact on the laser action.

© 2013 AIP Publishing LLC

Abstract-Influence of the facet type on the performance of terahertz quantum cascade lasers with double-metal waveguides

Werner Schrenk², Gottfried Strasser²,  Karl Unterrainer¹
Martin Brandstetter¹, Michael Krall¹, Christoph Deutsch¹, Hermann Detz², Aaron M. Andrews²,

¹Photonics Institute and Center for Micro- and Nanostructures, Vienna University of Technology, Gusshausstrasse 29, A-1040 Vienna, Austria
²Institute of Solid-State Electronics and Center for Micro- and Nanostructures, Vienna University of Technology, Floragasse 7, A-1040 Vienna, Austria 

http://apl.aip.org/resource/1/applab/v102/i23/p231121_s1?isAuthorized=no

We investigate the influence of cleaved and dry chemically etched facets on the performance of terahertz quantum cascade lasers with double-metal waveguides. We theoretically show that the reflectivity and therefore also the mirror losses depend on the facet type. We fabricated devices employing both a cleaved and an etched facet, which show an asymmetric output characteristic. Furthermore, we compare the performance in terms of maximum operation temperature of lasers with each facet configuration. The results suggest that the devices are operated in a mirror loss dominated regime.

© 2013 © 2013 Author(s).