Abstract-Direct Frequency-Comb-Driven Raman Transitions in the Terahertz Range

C. Solaro, S. Meyer, K. Fisher, M. V. DePalatis, M. Drewsen,

https://journals.aps.org/prl/abstract/10.1103/PhysRevLett.120.253601

We demonstrate the use of a femtosecond frequency comb to coherently drive stimulated Raman transitions between terahertz-spaced atomic energy levels. More specifically, we address the $3d{2D}_{3/2}$and $3d{2D}_{5/2}$ fine structure levels of a single trapped $40{\mathrm{Ca}}^{+}$ ion and spectroscopically resolve the transition frequency to be ${\nu }_D=1,819,599,021,534\pm 8\mathrm{Hz}$. The achieved accuracy is nearly a factor of five better than the previous best Raman spectroscopy, and is currently limited by the stability of our atomic clock reference. Furthermore, the population dynamics of frequency-comb-driven Raman transitions can be fully predicted from the spectral properties of the frequency comb, and Rabi oscillations with a contrast of 99.3(6)% and millisecond coherence time have been achieved. Importantly, the technique can be easily generalized to transitions in the sub-kHz to tens of THz range and should be applicable for driving, e.g., spin-resolved rovibrational transitions in molecules and hyperfine transitions in highly charged ions.

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A chip-scale broadband optical system that can sense molecules in the mid-infrared

https://www.nanowerk.com/nanotechnology-news/newsid=50270.php

(Nanowerk News) Researchers at Columbia Engineering have demonstrated, for the first time, a chip-based dual-comb spectrometer in the mid-infrared range, that requires no moving parts and can acquire spectra in less than 2 microseconds. The system, which consists of two mutually coherent, low-noise, microresonator-based frequency combs spanning 2600 nm to 4100 nm, could lead to the development of a spectroscopy lab-on-a-chip for real-time sensing on the nanosecond time scale.

“Our results show the broadest optical bandwidth demonstrated for dual-comb spectroscopy on an integrated platform,” said Alexander Gaeta, David M. Rickey Professor of Applied Physics and of Materials Science and senior author of the study, published in Nature Communications("Silicon-chip-based mid-infrared dual-comb spectroscopy").

Schematic of silicon microresonator generating a frequency comb that samples molecules for chemical identification. (Image: Alexander Gaeta/Columbia Engineering)

Creating a spectroscopic sensing device on a chip that can realize real-time, high-throughput detection of trace molecules has been challenging. A few months ago, teams led by Gaeta and Michal Lipson, Higgins Professor of Electrical Engineering, were the first to miniaturize dual-frequency combs by putting two frequency comb generators on a single millimeter-sized chip. They have been working on broadening the frequency span of the dual combs, and on increasing the resolution of the spectrometer by tuning the lines of the comb.

In this current study, the researchers focused on the mid-infrared (mid-IR) range, which, because its strong molecular absorption is typically 10 to 1,000 times greater than those in the visible or near-infrared, is ideal for detecting trace molecules. The mid-IR range effectively covers the “fingerprint” of many molecules.

The team performed mid-IR dual-comb spectroscopy using two silicon nanophotonic devices as microresonators. Their integrated devices enabled the direct generation of broadband mid-infrared light and fast acquisition speeds for characterizing molecular absorption.

“Our work is a critical advance for chip-based dual-comb spectroscopy for liquid/solid phase studies,” said Mengjie Yu, lead author of the paper and a PhD student in Gaeta’s lab. “Our chip-scale broadband optical system, essentially a photonic lab-on-a-chip, is well-suited for identification of chemical species and could find a wide range of applications in chemistry, biomedicine, material science, and industrial process control.”

Abstract-Intensity autocorrelation measurements of frequency combs in the terahertz range

Ileana-Cristina Benea-Chelmus, Markus Rösch, Giacomo Scalari, Mattias Beck, and Jérôme Faist

https://journals.aps.org/pra/abstract/10.1103/PhysRevA.96.033821

We report on direct measurements of the emission character of quantum cascade laser based frequency combs, using intensity autocorrelation. Our implementation is based on fast electro-optic sampling, with a detection spectral bandwidth matching the emission bandwidth of the comb laser, around 2.5 THz. We find the output of these frequency combs to be continuous even in the locked regime, but accompanied by a strong intensity modulation. Moreover, with our record temporal resolution of only few hundreds of femtoseconds, we can resolve correlated intensity modulation occurring on time scales as short as the gain recovery time, about 4 ps. By direct comparison with pulsed terahertz light originating from a photoconductive emitter, we demonstrate the peculiar emission pattern of these lasers. The measurement technique is self-referenced and ultrafast, and requires no reconstruction. It will be of significant importance in future measurements of ultrashort pulses from quantum cascade lasers.

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Speedy terahertz-based system could detect explosives

An artist’s embellishment of an image of the “gain medium” used to produce terahertz frequency combs. The different colors indicate that different wavelengths of oscillating terahertz radiation travel different distances through the medium, which has a different refractive index for each of them.

Image: Yan Liang/L2Molecule.com

Larry Hardesty | MIT News Office
May 20, 2016

http://news.mit.edu/2016/speedy-terahertz-based-system-could-detect-explosives-0520

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Spectroscopic system with chip-scale lasers cuts detection time from minutes to microseconds.

Terahertz spectroscopy, which uses the band of electromagnetic radiation between microwaves and infrared light, is a promising security technology because it can extract the spectroscopic “fingerprints” of a wide range of materials, including chemicals used in explosives.

But traditional terahertz spectroscopy requires a radiation source that’s heavy and about the size of a large suitcase, and it takes 15 to 30 minutes to analyze a single sample, rendering it impractical for most applications.

In the latest issue of the journal Optica, researchers from MIT’s Research Laboratory of Electronics and their colleagues present a new terahertz spectroscopy system that uses a quantum cascade laser, a source of terahertz radiation that’s the size of a computer chip. The system can extract a material’s spectroscopic signature in just 100 microseconds.

The device is so efficient because it emits terahertz radiation in what’s known as a “frequency comb,” meaning a range of frequencies that are perfectly evenly spaced.

“With this work, we answer the question, ‘What is the real application of quantum-cascade laser frequency combs?’” says Yang Yang, a graduate student in electrical engineering and computer science and first author on the new paper. “Terahertz is such a unique region that spectroscopy is probably the best application. And QCL-based frequency combs are a great candidate for spectroscopy.”

Different materials absorb different frequencies of terahertz radiation to different degrees, giving each of them a unique terahertz-absorption profile. Traditionally, however, terahertz spectroscopy has required measuring a material’s response to each frequency separately, a process that involves mechanically readjusting the spectroscopic apparatus. That’s why the method has been so time consuming.

Because the frequencies in a frequency comb are evenly spaced, however, it’s possible to mathematically reconstruct a material’s absorption fingerprint from just a few measurements, without any mechanical adjustments.

Getting even

The trick is evening out the spacing in the comb. Quantum cascade lasers, like all electrically powered lasers, bounce electromagnetic radiation back and forth through a “gain medium” until the radiation has enough energy to escape. They emit radiation at multiple frequencies that are determined by the length of the gain medium.

But those frequencies are also dependent on the medium’s refractive index, which describes the speed at which electromagnetic radiation passes through it. And the refractive index varies for different frequencies, so the gaps between frequencies in the comb vary, too.

To even out their lasers’ frequencies, the MIT researchers and their colleagues use an oddly shaped gain medium, with regular, symmetrical indentations in its sides that alter the medium’s refractive index and restore uniformity to the distribution of the emitted frequencies.

Yang; his advisor, Qing Hu, the Distinguished Professor in Electrical Engineering and Computer Science; and first author David Burghoff, who received his PhD in electrical engineering and computer science from MIT in 2014 and is now a research scientist in Hu’s group, reported this design in Nature Photonics in 2014. But while their first prototype demonstrated the design’s feasibility, it in fact emitted two frequency combs, clustered around two different central frequencies, with a gap between them, which made it less than ideal for spectroscopy.

In the new work, Yang and Burghoff, who are joint first authors; Hu; Darren Hayton and Jian-Rong Gao of the Netherlands Institute for Space Research; and John Reno of Sandia National Laboratories developed a new gain medium that produces a single, unbroken frequency comb. Like the previous gain medium, the new one consists of hundreds of alternating layers of gallium arsenide and aluminum gallium arsenide, with different but precisely calibrated thicknesses.

Getting practical

As a proof of concept, the researchers used their system to measure the spectral signature of not a chemical sample but an optical device called an etalon, made from a wafer of gallium arsenide, whose spectral properties could be calculated theoretically in advance, providing a clear standard of comparison. The new system’s measurements were a very good fit for the etalon’s terahertz-transmission profile, suggesting that it could be useful for detecting chemicals.

Although terahertz quantum cascade lasers are of chip scale, they need to be cooled to very low temperatures, so they require refrigerated housings that can be inconveniently bulky. Hu’s group continues to work on the design of increasingly high-temperature quantum cascade lasers, but in the new paper, Yang and his colleagues demonstrated that they could extract a reliable spectroscopic signature from a target using only very short bursts of terahertz radiation. That could make terahertz spectroscopy practical even at low temperatures.

“We used to consume 10 watts, but my laser turns on only 1 percent of the time, which significantly reduces the refrigeration constraints,” Yang explains. “So we can use compact-sized cooling.”

“This paper is a breakthrough, because these kinds of sources were not available in terahertz,” says Gerard Wysocki, an assistant professor of electrical engineering at Princeton University. “Qing Hu is the first to actually present terahertz frequency combs that are semiconductor devices, all integrated, which promise very compact broadband terahertz spectrometers.”

“Because they used these very inventive phase correction techniques, they have demonstrated that even with pulsed sources you can extract data that is reasonably high resolution already,” Wysocki continues. “That’s a technique that they are pioneering, and this is a great first step toward chemical sensing in the terahertz region.”

Abstract-Terahertz multi-heterodyne spectroscopy using laser frequency combs

Yang Yang, David Burghoff, Darren J. Hayton, Jian-Rong Gao, John L. Reno, Qing Hu

http://www.mathpubs.com/detail/1604.01048v1/Terahertz-multi-heterodyne-spectroscopy-using-laser-frequency-combs

Frequency combs based on terahertz quantum cascade lasers feature broadband coverage and high output powers in a compact package, making them an attractive option for broadband spectroscopy. Here, we demonstrate the first multi-heterodyne spectroscopy using two terahertz quantum cascade laser combs. With just 100 μ$\mu$s of integration time, we achieve peak signal-to-noise ratios exceeding 60 dB and a spectral coverage greater than 250 GHz centered at 2.8 THz. Even with room-temperature detectors we are able to achieve peak signal-to-noise ratios of 50 dB, and as a proof-of-principle we use these combs to measure the broadband transmission spectrum of etalon samples. Finally, we show that with proper signal processing, it is possible to extend the multi-heterodyne spectroscopy to quantum cascade laser combs operating in pulsed mode, greatly expanding the range of quantum cascade lasers that could be suitable for these techniques.

Abstract-High density terahertz frequency comb produced by coherent synchrotron radiation

S. Tammaro,

O. Pirali,

P. Roy,

J.-F. Lampin,

G. Ducournau,

A. Cuisset,

F. Hindle

& G. Mouret

http://www.nature.com/ncomms/2015/150720/ncomms8733/full/ncomms8733.html

Frequency combs have enabled significant progress in frequency metrology and high-resolution spectroscopy extending the achievable resolution while increasing the signal-to-noise ratio. In its coherent mode, synchrotron radiation is accepted to provide an intense terahertz continuum covering a wide spectral range from about 0.1 to 1 THz. Using a dedicated heterodyne receiver, we reveal the purely discrete nature of this emission. A phase relationship between the light pulses leads to a powerful frequency comb spanning over one decade in frequency. The comb has a mode spacing of 846 kHz, a linewidth of about 200 Hz, a fractional precision of about 2 × 10⁻¹⁰ and no frequency offset. The unprecedented potential of the comb for high-resolution spectroscopy is demonstrated by the accurate determination of pure rotation transitions of acetonitrile.

Abstract-Decade-Spanning High-Precision Terahertz Frequency Comb

Ian A. Finneran, Jacob T. Good, Daniel B. Holland, P. Brandon Carroll, Marco A. Allodi, and Geoffrey A. Blake

Phys. Rev. Lett. 114, 163902 – Published 21 April 2015

http://journals.aps.org/prl/abstract/10.1103/PhysRevLett.114.163902

The generation and detection of a decade-spanning terahertz (THz) frequency comb is reported using two Ti:sapphire femtosecond laser oscillators and asynchronous optical sampling THz time-domain spectroscopy. The comb extends from 0.15 to 2.4 THz, with a tooth spacing of 80 MHz, a linewidth of 3.7 kHz, and a fractional precision of 1.8×10−9. With time-domain detection of the comb, we measure three transitions of water vapor at 10 mTorr between 1–2 THz with an average Doppler-limited fractional accuracy of 6.1×10−8. Significant improvements in bandwidth, resolution, and sensitivity are possible with existing technologies.

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A new scheme to generate terahertz frequency combs features unprecedented bandwidth and frequency accuracy

       Lance Hayashida/California Institute of Technology

http://physics.aps.org/synopsis-for/10.1103/PhysRevLett.114.163902
Matteo Rini

Frequency combs—light sources whose spectra are made of a series of discreet, equally spaced frequencies—can be used as rulers that measure the light emitted by atoms or molecules with extraordinarily high precision. Most frequency combs work in the visible or infrared, but terahertz combs would allow more precise measurements of rotational and vibrational resonances of molecules and materials. A team led by Geoffrey Blake at the California Institute of Technology, Pasadena, has now demonstrated a terahertz comb that features greater bandwidth and better frequency precision than current technologies.

The most common way to make a frequency comb is through so called “mode-locked” lasers. Such lasers emit a train of short pulses, whose spectrum is a frequency comb. The authors started with an infrared mode-locked laser and used it to excite currents in an “antenna,” which emitted lower frequency terahertz pulses. A second infrared laser detected the electric field of the terahertz pulses by “sensing” how they modified the index of refraction of a crystal in which the two beams co-propagated. Although this approach is not new, the authors found new ways to stabilize the frequencies of the two lasers and minimize noise. As a result, they were able to achieve, over a spectral range extending up to 2.4 terahertz, a frequency precision of a few parts per billion—over two orders of magnitude better than existing schemes for this spectral region.

With their setup, Blake and his co-workers determined the frequency of several rovibrational transitions of water vapor with a precision that was limited only by the molecules’ motion. The researchers plan to use the setup to measure precise reference spectra of molecules, which will help interpret astrophysical spectra measured by the Hershel Space Observatory and the Atacama Large Millimeter Array.

This research is published in Physical Review Letters.