Terahertz acoustic laser (saser) devices: fabrication and characterisation
Lead Research Organisation:
University of Nottingham
Department Name: Sch of Physics & Astronomy
Abstract
SASER is the acronym for Sound Amplification by Stimulated Emission of Radiation and is the acoustic analogue of the optical laser [http://en.wikipedia.org/wiki/Sound_Amplification_by_Stimulated_Emission_of_Radiation]. A terahertz (THz) saser device would produce an intense beam of coherent acoustic waves with nanometre wavelengths. As well as being a subject of pure scientific curiosity, the acoustic beams produced by saser could have a number of scientific and technological applications: e.g. probing and imaging of nanometre scale objects, and conversion to THz electromagnetic waves, which may be used for medical imaging and security screening.Recently, we have demonstrated a device which displays some of the key characteristics expected of a saser. The work was published in a scientific journal and subsequently reported in a number of academic and popular science magazines, including the science and technology pages of The Economist [10-16 June 2006, p96]. The device was based on a semiconductor superlattice: a man-made nanostructure consisting of many (typically 40 or 50) alternating layers of two different semiconductor materials, in this particular case Gallium Arsenide and Aluminium Arsenide, each a few nanometres thick. In the superlattice, the conditions for phonon amplification can be achieved when electrons are made to travel vertically through the stack of layers. The electrons hop between neighbouring Gallium Arsenide layers and, to conserve energy, emit a phonon (quantum of sound) as they go. These phonons can stimulate further electron hops and emission of phonons giving rise to phonon amplification. In addition to acoustic gain, a saser requires an acoustic cavity to confine the phonons so that they are available to take part in further stimulated emission processes. This is analogous to the optical cavity formed between the two mirrors of a laser. Superlattices can be used as phonon mirrors: owing to the differences of the speed of sound and density between the two materials making up the superlattice, phonons are partly reflected and partly transmitted at each interface. Constructive interference of all the reflections, which occurs when the sound wavelength matches the thickness of a single pair of layers, leads to a strong reflection and confinement of the phonons.In this project, we plan to carry out a detailed investigation of the physics of the separate elements of a THz saser device based on semiconductor superlattices. These include: the gain medium and the process of phonon amplification within it; the pumping schemes, both electrical and optical, for achieving the necessary population inversion; and the acoustic mirrors and cavities for confining phonons. The main goal of the work is to develop a milliwatt per square centimetre class saser device emitting coherent phonons in the range 0.5 - 1 THz and to characterise the saser sound emitted.
Publications
Beardsley R
(2010)
Optical detection of folded mini-zone-edge coherent acoustic modes in a doped GaAs/AlAs superlattice
in Physical Review B
Beardsley R
(2011)
A GaAs/AlAs superlattice as an electrically pumped THz acoustic phonon amplifier
in New Journal of Physics
Beardsley R.
(2011)
Terahertz phonon amplification and sasing in semiconductor superlattice structures
in Structural Health Monitoring 2011: Condition-Based Maintenance and Intelligent Structures - Proceedings of the 8th International Workshop on Structural Health Monitoring
Beardsley RP
(2010)
Coherent terahertz sound amplification and spectral line narrowing in a stark ladder superlattice.
in Physical review letters
Brüggemann C
(2012)
Modulation of a surface plasmon-polariton resonance by subterahertz diffracted coherent phonons
in Physical Review B
Casiraghi A
(2011)
Fast switching of magnetization in the ferromagnetic semiconductor (Ga,Mn)(As,P) using nonequilibrium phonon pulses
in Applied Physics Letters
Farmer D
(2013)
Quantized phonon modes in loaded polymer films
in Journal of Applied Physics
Farmer DJ
(2014)
High-frequency acousto-optic effects in Bragg reflectors.
in Optics express
Greenaway M
(2010)
Using acoustic waves to induce high-frequency current oscillations in superlattices
in Physical Review B
Lee S
(2014)
Polarized infrared reflectance study of free standing cubic GaN grown by molecular beam epitaxy
in Materials Chemistry and Physics
Description | We have developed a THz saser (acoustic equivalent of a laser). It is a device that generates coherent acoustic waves in a similar way to how a laser generated coherent light. We have measured the characteristics of the acoustic waves generated by a vertical-cavity saser. |
Exploitation Route | They may be used as the basis to develop more efficient devices which could be used for hypersonic probing of nanostructures. Or to generate THz electromagnetic signals. |
Sectors | Aerospace, Defence and Marine,Digital/Communication/Information Technologies (including Software),Electronics |
URL | https://en.wikipedia.org/wiki/Sound_amplification_by_stimulated_emission_of_radiation |
Description | Open BAA |
Amount | $450,000 (USD) |
Organisation | US Army Research Lab |
Department | Army Research Office |
Sector | Public |
Country | United States |
Start | 09/2014 |
End | 09/2017 |
Description | Saser (Sound Laser) Based On-Chip Hypersonic Device for Nanosensing Applications |
Amount | $200,000 (USD) |
Funding ID | Open-BAA-FP-114 |
Organisation | Defense Advanced Research Projects Agency (DARPA) |
Sector | Public |
Country | United States |
Start |
Description | Collaboration with Dr B Glavin of the V E Lashkaryov Institute, Kiev, Ukraine |
Organisation | V E Lashkaryov Institute of Semiconductor Physics |
Country | Russian Federation |
Sector | Academic/University |
PI Contribution | Dr Glavin and his team have provided theoretical support for the project. He has contributed to four of the listed published outputs. |
Collaborator Contribution | Theoretical support |
Impact | Joint publications |
Start Year | 2009 |