New lasers that fire terahertz beams could propel medical imaging and contraband detection

 

  A terahertz laser sits on top of a small square cooler. The laser could enable new portable medical       diagnostics and explosive detectors.

 

ALI KHALATPOUR/MASSACHUSETTS INSTITUTE OF TECHNOLOGY

https://www.sciencemag.org/news/2020/11/new-lasers-fire-terahertz-beams-could-propel-medical-imaging-and-contraband-detection

 Robert F. Service

Compact, chip-based lasers have conquered much of the electromagnetic spectrum, from ultraviolet to infrared, enabling technologies from digital communications and barcode readers to laser pointers and printers. But one key region of the spectrum remained untamed: the terahertz band, which lies between infrared light and microwaves. Engineers hankered for a ready source of terahertz radiation, which can penetrate opaque objects and probe chemical fingerprints inside. But compact terahertz lasers have only worked at ultralow temperatures, limiting them mostly to laboratory settings.

No longer. In today’s issue of Nature Photonics, researchers report creating a grain-of-rice–size terahertz laser on a chip that operates at 250 K, or –23°C, within reach of a plug-in cooler the size of a cracker.

“This is a great achievement,” says Miriam Vitiello, a condensed matter physicist at the Nanoscience Institute of Italy’s National Research Council. “It has been a long-term goal in the community to push up the temperature of terahertz lasers,” she adds. “There is now a plethora of applications that can be done,” from medical imaging to explosives detection at airports

Standard chip-based lasers generate their photons when electrons fall into electron vacancies within a semiconductor alloy, whose makeup determines the color. Gallium nitride, for example, emits blue light, whereas gallium arsenide emits red. However, no semiconductor alloys emit photons in the terahertz range. (“Terahertz” refers to the light’s frequency: trillions of cycles per second.) In 1994, researchers at AT&T Bell Labs created a new kind of laser in which the semiconductor’s structure, not just its chemistry, determined the wavelength. Called a quantum cascade laser (QCL), it contained hundreds of layers of semiconductors of precise thicknesses. Electrons injected into the structure cascade down hundreds of energy steps, shedding a photon at each one. Those photons were infrared in the first QCL, but in 2002 researchers in Italy and the United Kingdom created QCL lasers that emitted terahertz photons.

Those devices needed to be chilled to 50 K, but last year, researchers led by physicist Jérôme Faist at ETH Zurich unveiled a terahertz QCL made up of hundreds of alternating layers of gallium arsenide and aluminum gallium arsenide (AlGaAs) that works at 210 K. It still required bulky and expensive cryogenic coolers, however.

At higher temperature the electrons leap the barriers between layers rather than cascading through the structure one step at a time. “Over-the-barrier electron leakage was the killer,” says Qing Hu, an electrical engineer at the Massachusetts Institute of Technology. So Hu and his colleagues added more aluminum to the AlGaAs barriers in hopes of better confining the electrons. Hu’s team also had to prevent electrons from interacting in a way that caused them to leak through the AlGaAs barriers.

Now, Hu’s team has shown that by tailoring its layered structure even more precisely—some layers were just seven atoms thick—it could make electrons behave at temperatures warm enough to be reached with standard compact thermoelectric coolers. What’s more, Hu says, the same strategy should enable the team to eventually make room temperature terahertz lasers.

Room temperature terahertz sources could be paired with terahertz detectors that also work at room temperature, which Vitiello and other researchers are now developing. That marriage could lead to technologies such as terahertz imagers able to distinguish skin cancer from normal tissue without a biopsy or watch airline passengers and cargo for hidden explosives, illegal drugs, and even pharmaceutical fakes. Faist says: “We have hoped for this for a very long time. 

Terahertz (THz), Mid InfraRed (MIR) and Near InfraRed (NIR) Technologies for Protection of Critical Infrastructures against Explosives & CBRN

Liblice, Czech Republic
05 - 09 Nov 2018
Prof. Mauro F. Pereira
Dr. Leonid Culiuc

https://www.nato.int/cps/en/natohq/news_157810.htm

The objective of this Advanced Research Workshop is to bring together recognized experts on critical Infrastructure protection with academic and developers in the field of sensors. State-of-the-art technologies will be presented and discussed in a workshop that will bring together a wide range of experts from a high number of NATO and Partner countries. A poster session with the opportunity for young students to present their research is envisaged.

Identified for the first time what kind of explosive has been used after the device has been detonated

http://www.basqueresearch.com/berria_irakurri.asp?Berri_Kod=5061&hizk=I#.U3ybL9q9KSM

There are objects we cannot see within the range of the visible but which we can with imaging systems that use the terahertz (THz) wavelength. Within this range we can detect, for example, not only a foreign body hidden under clothing, but also determine what material it is made of. David Etayo, a telecommunications engineer and PhD holder of the NUP/UPNA-Public University of Navarre, has been able to identify explosive components not only in their pure state, but also, and for the first time, after the detonation has taken place. What is more, he has worked on other terahertz applications for agriculture and the food industry. His PhD thesis is entitled “New developments in the THz field for imaging applications”.

Characterising (identifying) a material means finding out its distinctive features so that when the substance is subsequently subjected to a detector system, the system will indicate what it is. As this researcher pointed out, “what we have done is gone a step further in the imaging system: besides detecting that an object is there, we have characterised different materials to see how they react within the THz range. We have characterised explosives and, for the first time, a type of explosive like gunpowder, which was a material present, for example, in the March 11 attack”. He has also characterised other materials like TNT, hexogen and pentrite.

One of the achievements of this PhD thesis has been the characterising also of explosives that have already been detonated. "The normal thing is to characterise explosives in their recently produced laboratory form, when they are safe, but what happens, for example, after an attack, is that only a few remains are left behind and are totally different from the original materials."

In the course of his research and in collaboration with the Guardia Civil (Spanish Gendarmerie) samples were taken before and after detonation. Furthermore, the materials were characterised in different forms: pure, commercial and homemade explosive materials, for example. That way, it has been possible to detect explosives in minimum sample quantities of between 5 and 10 milligrams. Blends of different explosives were also analysed and in all the cases it was possible to identify each of the components.

"Using the remains of a detonation as a sample, we can find out almost immediately what kind of explosive has been detonated. In the end, it is a chemical process that modifies the initial product, but the good thing is that in the pure as well as in the detonated state is it possible in the terahertz range to characterise, determine and find out what it is." The use of this technology could also allow these systems to be incorporated into crawler robots employed to dispose of devices, and thus enable them to detect the explosive involved.

Various applications

Another part of the thesis focussed on THz technology applications in the fields of agriculture and the food industry. In the first case, work was done on vines since THz are very sensitive to the water content of a sample: “Although at first sight no variations can be detected, if you analyse the imaging of a vine leaf in terahertz you can see perfectly how the water content varies from one day to the next. This allows one to exercise greater control over the plants, cut irrigation costs and that way improve the quality of the wine, etc.”

As regards the food industry, work was done in collaboration with a chorizo producing plant. On the one hand, the amount of water in the product was measured during the drying process which enables one to estimate how much longer the chorizo curing process will take. “The good thing about THz technology is that it is non-destructive; you don’t need to cut the chorizo to carry out the measuring, all you have to do is bring the sensor up to the product," explained David Etayo. Furthermore, the most direct application they have found is the use of the system to detect remains or foreign bodies that may have ended up in the production chain of sliced chorizo.

Finally, during the work a double band was designed; it allows two different frequency ranges (infrared and terahertz) to be combined into a single measurement so that hidden objects can be detected and identified. Within the electromagnetic spectrum, THz radiation is located between microwaves and infrared light waves. The infrared range works at a higher frequency and provides resolution and greater imaging quality, while the THz part is the one that is used to identify and characterise the materials. “The idea is that a single detector can provide us with the resolution of the imaging and the identification of the material at the same time,” pointed out the researcher. In this thesis we have designed and manufactured a detector that enables us to make this measurement. What is more, the use of Fresnel zones has enabled us to achieve a gain increase in the infrared band."

Notes

David Etayo-Salinas did his university and PhD studies at the NUP/UPNA-Public University of Navarre, where he has lectured in subjects on the Engineering degree course in Telecommunications Technologies. During his training as a researcher he spent a period of time at the German University of Siegen, at the Institute for High Frequency Technology and Quantum Electronics. He has participated in about fifteen congresses and conferences and is the co-author of half a dozen scientific papers.

Internet reference

www.unavarra.es/actualidad/berriak?contentId=181367

References

D. Etayo, I. Maestrojuan, J. Teniente, I. Ederra, R. Gonzalo. (2013). "Experimental Explosive Characterization for Counterterrorist Investigation". Journal of Infrared, Millimeter, and Terahertz Waves, 34, 7-8: 468-479

Additional information

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TeraView terahertz spectroscopic system characterizes small explosive samples

09/18/2013

By John Wallace
Senior Editor

http://www.laserfocusworld.com/articles/2013/09/teraview-terahertz-spectroscopic-system-characterizes-small-explosive-samples.html

(Image: TeraView)

Cambridge, England--In the August, 2013 issue of the Journal of Infrared, Millimeter, and Terahertz Waves, researchers at TeraView described carrying out terahertz spectral characterization of different explosives of special interest to the Spanish National Security Forces ("Guardia Civil"). The researchers used terahertz radiation from 0.060 THz to 3.5 THz, using a TeraView TPS Spectra 3000 system in the lab to determine the refractive index, absorbance, and complex permittivity of the explosive samples.

The samples included bullet gunpowder, mine gunpowder, PETN (C₅H₈N₄O₁₂), TNT, and RDX (also called cyclonite). The TeraView researchers determined that differing fabrication processes for the explosives lead to the same spectral behaviors and characteristics, and additives in the samples did not alter their primary electromagnetic properties.

The TeraView system could measure samples down to 10 mg in mass. TeraView says the results will be used to design future terahertz imaging systems that allow to detect and identify explosives in security and defense applications, and/or to do laboratory studies after a terrorism event.

Source: http://terahertzspectroscopyandimaging.blogspot.co.uk/2013/09/experimental-explosive-characterization.html?goback=.gde_2955260_member_274296872#!