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In a new feature on AZoQuantum, we speak with Associate Professor Kate Brown and Theoretical Physicist Harsh Mathur about their research investigating Modified Newtonian Dynamics and its implications for the Ninth Planet theory.
Portable QCL devices are being deployed for real-time air quality monitoring, revolutionizing environmental regulation. These robust, compact sensors can also continually monitor industrial facilities, exhaust stacks, and pipelines for process control, safety, and regulatory compliance without gas sampling.
Quantumcascade laser working principle
This could enable data transmission rates up to 100 gigabits per second for applications like ultra-fast wireless links between facilities.
While conventional semiconductor lasers rely on electron-hole recombination across bandgaps for stimulated emission, QCLs employ quantum energy wells to confine electrons into specific energy states.
LabOne Q is a new software framework that accelerates quantum computing progress on Zurich Instruments’ hardware. With LabOne Q, users can design complex quantum experiments with an intuitive, high-level programming language.
A key advantage of QCLs is their tunability across various wavelengths in the mid-infrared spectrum, from 5.5 to 11.0 µm. This tunability is achieved by controlling the structure of the layers rather than relying solely on the lasing material, providing greater flexibility in tailoring their emission wavelengths.
Applying voltage propels electrons across the device, transitioning them from one quantum well to the next within the "active region," where they descend to lower energy levels and release photons. As electrons proceed through subsequent active regions, they repeatedly transition and emit photons.
Quantum cascade lasers offer unique capabilities for mid-infrared sensing and spectroscopy applications due to their high-power output, wavelength agility, and narrow line widths. However, complex temperature control electronics and high production costs challenge their broader adoption.
Quantumcascade laser spectroscopy
This new topological bulk BIC design could enable more robust, single-mode QCL devices across infrared and THz frequencies and provide strong confinement for high beam quality without requiring large external cavities.
Edmund optics. (2023). Quantum Cascade Lasers. [Online]. Available at: https://www.edmundoptics.com/knowledge-center/application-notes/lasers/quantum-cascade-lasers/
Ali, Owais. "What are Quantum Cascade Lasers?". AZoQuantum. 21 November 2024. .
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Paschotta, R. (2008). Quantum Cascade Lasers-Field guide to laser pulse generation (Vol. 14). Bellingham: SPIE press. Available at: https://spie.org/publications/fg12_p45_quantum_cascade_lasers?SSO=1
QCLs can detect these molecules at concentrations up to 1000 times lower than conventional infrared sources while offering high selectivity due to their narrowband emission.
Raspa, A. & Moglia, F. (2021). Looking to the future of quantum cascade lasers. Available at: https://www.laserfocusworld.com/lasers-sources/article/14211918/looking-to-the-future-of-quantum-cascade-lasers
Quantumcascade laser PDF
They combined acoustic and light waves to modulate the quantum cascade laser output. This approach demonstrated the potential to control light output by a few percent, marking a significant step forward in developing fully controlled photon emissions from these lasers.
Fresnel Lenses replace the curved surface of a conventional lens with a series of concentric grooves, molded into the surface of a thin, lightweight plastic sheet. The grooves act as individual refracting surfaces, like tiny prisms when viewed in cross section, bending parallel rays in a very close approximation to a common focal length. Because the lens is thin, very little light is lost by absorption. Fresnel Lenses are a compromise between efficiency and image quality. High groove density allows higher quality images, while low groove density yields better efficiency (as needed in light gathering applications). In infinite conjugate systems, the grooved side of the lens should face the longer conjugate. Fresnel lenses are most often used in light gathering applications, such as condenser systems or emitter/detector setups. Fresnel lenses can also be used as magnifiers or projection lenses; however, due to the high level of distortion, this is not recommended.
The designed THz QCL uses topological bound states in the continuum (BIC states) to confine light, enabling the laser to operate in a stable single mode while producing a compact, high-quality beam.
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Ali, Owais. (2023, September 05). What are Quantum Cascade Lasers?. AZoQuantum. Retrieved on November 21, 2024 from https://www.azoquantum.com/Article.aspx?ArticleID=448.
This is achieved by creating a periodic structure of thin alternating semiconductor layers forming quantum wells. The quantum confinement in these nanoscale wells causes discrete quantized energy subbands to form in the conduction band.
Dr. Rüdiger Paschotta. (2021). Quantum Cascade Lasers. [Online]. Available at: https://www.rp-photonics.com/quantum_cascade_lasers.html
The SideKick QCL Controller offers a low-noise laser control solution, ensuring stable and precise operation for demanding laser applications.
A single QCL may consist of as many as 75 active regions, enabling each electron to generate multiple photons as it traverses the structure. This cascading effect amplifies photon emission and allows QCLs to emit high-power light at specific wavelengths.
John Durcan of IDA Ireland highlights the nation's surge in quantum computing, emphasizing R&D growth, key tech partnerships, and the need for skilled talent.
Xu, S., Zhang, S., Kirch, J. D., Gao, H., Wang, Y., Lee, M. L., ... & Mawst, L. J. (2023). 8.1 μm-emitting InP-based quantum cascade laser grown on Si by metal-organic chemical vapor deposition. Applied Physics Letters, 123(3). https://doi.org/10.1063/5.0155202
Han, S., Cui, J., Chua, Y., Zeng, Y., Hu, L., Dai, M., ... & Wang, Q. J. (2023). Electrically-pumped compact topological bulk lasers driven by band-inverted bound states in the continuum. Light: Science & Applications, 12(1), 145. https://doi.org/10.1038/s41377-023-01200-8
Similar to medical applications, QCL-based sensors are ideal for detecting greenhouse gases and airborne pollutants selectively.
This innovation could revolutionize silicon photonic integrated circuits (PICs), offering cost-effective and efficient mid-infrared optoelectronics.
Markus Müller discusses a new qubit design using rare-earth ions for dense, coherent quantum systems, advancing quantum computing scalability.
Subsequently, Kazarinov and Suris proposed the idea of quantum cascade lasers, and it wasn't until 1994 that Faist and colleagues at Bell Laboratories successfully demonstrated the first working QCL device.
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In a study published in Nature Communications, researchers successfully controlled terahertz quantum cascade lasers, potentially enabling data transmission rates of 100 gigabits per second.
Quantum cascade lasers offer groundbreaking capabilities in optical communications. Compact QCL transceivers could enable wireless links to surpass 100 Gbps over short distances, while in long-haul fiber networks, QCLs efficiently amplify signals at specific wavelengths.
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The origins of QCLs trace back to the early 1970s when Esaki and Tsu designed the first one-dimensional periodic potential multilayer using epitaxial growth, resulting in a superlattice structure. This marked a crucial step in the development of QCLs.
Quantum cascade lasers (QCLs) are an emerging laser technology unlocking advanced spectroscopy, healthcare, and communications applications. These ultra-compact semiconductor lasers are based on unique quantum effects and can be engineered to emit specialized wavelengths from the mid-infrared to the terahertz range. This article offers insights into QCLs, their working principle, applications, and recent advancements in the field.
Quantumcascade laser applications
When exposed to mid-infrared light emitted by a QCL, biological tissues exhibit unique absorption patterns, creating a distinctive "fingerprint" spectrum. Analyzing this fingerprint allows the identification of proteins, sugars, and biomarkers related to diseases such as cancer.
NEBOSH certified Mechanical Engineer with 3 years of experience as a technical writer and editor. Owais is interested in occupational health and safety, computer hardware, industrial and mobile robotics. During his academic career, Owais worked on several research projects regarding mobile robots, notably the Autonomous Fire Fighting Mobile Robot. The designed mobile robot could navigate, detect and extinguish fire autonomously. Arduino Uno was used as the microcontroller to control the flame sensors' input and output of the flame extinguisher. Apart from his professional life, Owais is an avid book reader and a huge computer technology enthusiast and likes to keep himself updated regarding developments in the computer industry.
Dunn, A., Poyser, C., Dean, P., Demić, A., Valavanis, A., Indjin, D., ... & Kent, A. (2020). High-speed modulation of a terahertz quantum cascade laser by coherent acoustic phonon pulses. Nature communications, 11(1), 835. https://doi.org/10.1038/s41467-020-14662-w
Quantum cascade lasers (QCLs) are a special type of semiconductor laser that emits single charge carrier (electrons) photons in the mid-to-far infrared region of the electromagnetic spectrum. Unlike traditional semiconductor lasers, QCLs operate on intersubband transitions within quantum wells, enabling them to achieve efficient and precise unipolar light emission.
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As a result, QCL components will become essential for meeting the increasing bandwidth demands of 5G networks, video streaming, cloud computing, and other high-speed applications.
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Ali, Owais. "What are Quantum Cascade Lasers?". AZoQuantum. https://www.azoquantum.com/Article.aspx?ArticleID=448. (accessed November 21, 2024).
Despite these challenges, the global quantum cascade laser market is projected to exhibit substantial growth, with a projected value of USD 533 million by 2028 and a CAGR of 4.4%. This growth trajectory underscores the growing recognition of QCLs as a transformative technology with promising prospects for various industries.
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In addition, QCLs offer rapid response times and exceptional spectral brightness, outperforming other light sources such as synchrotrons.
The designed QCL device demonstrated structural integrity without cracking due to the modest sample size and the thick silicon substrate that mitigated curvature accumulation.
QCLs' narrow laser light bandwidth in automobiles enables direct real-time measurement of critical nitrogen-containing exhaust gas components (NO, N2O, NO2, and NH3) with high precision and sensitivity.
Nanyang Technological University (NTU) researchers have achieved a significant breakthrough in developing electrically pumped, topological, bulk quantum cascade lasers operating in the terahertz (THz) frequency range. The results are published in Light: Science & Applications.
"We believe that with further refinement, we will be able to develop a new mechanism for complete control of the photon emissions from the laser, and perhaps even integrate structures generating sound with the terahertz laser so that no external sound source is needed." Professor Cunningham, co-author of the study.
The team demonstrated that exploiting these topological bulk BICs enables vertical and lateral confinement of the lasing mode in a very compact cavity. As a result, the miniaturized design (~10 microns wide) produced a narrow, single-mode THz beam with circular polarization.
Frąckiewicz, M. (2023). The Future of Quantum Cascade Lasers: Applications and Advancements. [Online]. Available at: https://ts2.space/en/the-future-of-quantum-cascade-lasers-applications-and-advancements/
Terahertz QCLs, operating at longer wavelengths, are now being commercialized for intricate gas analysis, providing heightened measurement accuracy in the 100 to 150 µm range.
According to the researchers, this achievement stands out as: "There are no prior reports of QCLs grown by metal-organic chemical vapor deposition (MOCVD) on silicon substrates."
In recent research published in Applied Physics Letters, US scientists achieved a major milestone by growing 8.1 μm wavelength quantum cascade lasers on silicon using metal-organic chemical vapor deposition (MOCVD).
Previously, most topological lasers have relied on edge states confined to surfaces or interfaces. However, the NTU researchers focused on topological bulk band edges inside the QCL's active region.
Pecharroman-Gallego, R. (2017). An Overview on Quantum Cascade Lasers: Origins and Development. InTech. https://doi.org/10.5772/65003
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Ali, Owais. 2023. What are Quantum Cascade Lasers?. AZoQuantum, viewed 21 November 2024, https://www.azoquantum.com/Article.aspx?ArticleID=448.