Few picosecond dynamics of intraband transitions in THz HgTe nanocrystals

Abstract Optoelectronic devices based on intraband or intersublevel transitions in semiconductors are important building blocks of the current THz technology. Large nanocrystals (NCs) of Mercury telluride (HgTe) are promising semiconductor candidates owing to their intraband absorption peak tunable from 60 THz to 4 THz. However, the physical nature of this THz absorption remains elusive as, in this spectral range, quantum confinement and Coulomb repulsion effects can coexist. Further, the carrier dynamics at low energy in HgTe NCs, which strongly impact the performances of THz optoelectronic devices, is still unexplored. Here, we demonstrate a broad THz absorption resonance centered at ≈4.5 THz and fully interpret its characteristics with a quantum model describing multiple intraband transitions of single carriers between quantized states. Our analysis reveals the absence of collective excitations in the THz optical response of these self-doped large NCs. Furthermore, using optical pump-THz probe experiments, we report on carrier dynamics at low energy as long as 6 ps in these self-doped THz HgTe NCs. We highlight evidence that Auger recombination is irrelevant in this system and attribute the main carrier recombination process to direct energy transfer from the electronic transition to the ligand vibrational modes and to nonradiative recombination assisted by surface traps. Our study opens interesting perspectives for the use of large HgTe NCs for the development of advanced THz optoelectronic devices such as emitters and detectors and for quantum engineering at THz frequencies.

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The effect of the combined application of a low-intensity infrared laser and normobaric hypoxia on the clinical picture of chronic generalized periodontitis

Fizioterapevt (Physiotherapist) ◽

10.33920/med-14-2110-05 ◽

2021 ◽

pp. 40-47

Author(s):

Ilona Vasilievna Dzgoeva ◽

Anna Aleksandrovna Remizova ◽

Valeriy Konstantinovich Frolkov ◽

Sergey Nikolaevich Nagornev

Keyword(s):

Therapeutic Effect ◽

Clinical Signs ◽

Physical Nature ◽

Infrared Laser ◽

Low Energy ◽

Normobaric Hypoxia ◽

Hypoxic Exposure ◽

Combined Application ◽

Biological Potential ◽

Leading Position

Chronic generalized periodontitis still occupies a leading position among dental diseases, but the effectiveness of drug therapy is insufficient. One of the promising methods of non-drug treatment is the use of factors of various physical nature, which allows to have a therapeutic effect on various functional systems. The combined use of normobaric hypoxia and a low-energy infrared laser significantly increases the effectiveness of complex treatment of patients with chronic generalized periodontitis. At the same time, the regression of clinical signs of the disease was noted to a greater extent when using laser radiation compared to hypoxic exposure. Taking into account the fundamentally different mechanisms of realization of the biological potential of a low-energy infrared laser and normobaric hypoxia, it can be assumed that the increase in the effectiveness of treatment of patients with chronic generalized periodontitis is due to the additive or potentiating nature of the therapeutic effect when they are combined.

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Phase Stable and Less-Defect Perovskite Quantum Dots: Optical Property, Photoexcited Hot Carrier Dynamics, Charge Transfer and Application to Optoelectronic Devices

10.29363/nanoge.nfm.2019.278 ◽

2019 ◽

Author(s):

Qing Shen ◽

Feng Liu ◽

Chao Ding ◽

Yaohong Zhang ◽

Taro Toyoda ◽

...

Keyword(s):

Quantum Dots ◽

Charge Transfer ◽

Optical Property ◽

Optoelectronic Devices ◽

Carrier Dynamics ◽

Hot Carrier ◽

Perovskite Quantum Dots

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Carrier dynamics in self-assembled ErAs nanoislands measured by optical-pump THz-probe spectroscopy

2005 Quantum Electronics and Laser Science Conference ◽

10.1109/qels.2005.1548811 ◽

2005 ◽

Author(s):

R.P. Prasankumar ◽

A. Scopatz ◽

D.J. Hilton ◽

A.J. Taylor ◽

R.D. Averitt ◽

...

Keyword(s):

Carrier Dynamics ◽

Optical Pump ◽

Self Assembled ◽

Probe Spectroscopy

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Defect Engineering in 2D Materials: Precise Manipulation and Improved Functionalities

Research ◽

10.34133/2019/4641739 ◽

2019 ◽

Vol 2019 ◽

pp. 1-14 ◽

Cited By ~ 10

Author(s):

Jie Jiang ◽

Tao Xu ◽

Junpeng Lu ◽

Litao Sun ◽

Zhenhua Ni

Keyword(s):

High Performance ◽

2D Materials ◽

Optoelectronic Devices ◽

Deep Understanding ◽

Building Blocks ◽

Research Progress ◽

Defect Engineering ◽

Plasma Chemical ◽

Design And Optimization ◽

Novel Structure

Two-dimensional (2D) materials have attracted increasing interests in the last decade. The ultrathin feature of 2D materials makes them promising building blocks for next-generation electronic and optoelectronic devices. With reducing dimensionality from 3D to 2D, the inevitable defects will play more important roles in determining the properties of materials. In order to maximize the functionality of 2D materials, deep understanding and precise manipulation of the defects are indispensable. In the recent years, increasing research efforts have been made on the observation, understanding, manipulation, and control of defects in 2D materials. Here, we summarize the recent research progress of defect engineering on 2D materials. The defect engineering triggered by electron beam (e-beam), plasma, chemical treatment, and so forth is comprehensively reviewed. Firstly, e-beam irradiation-induced defect evolution, structural transformation, and novel structure fabrication are introduced. With the assistance of a high-resolution electron microscope, the dynamics of defect engineering can be visualized in situ. Subsequently, defect engineering employed to improve the performance of 2D devices by means of other methods of plasma, chemical, and ozone treatments is reviewed. At last, the challenges and opportunities of defect engineering on promoting the development of 2D materials are discussed. Through this review, we aim to build a correlation between defects and properties of 2D materials to support the design and optimization of high-performance electronic and optoelectronic devices.

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Determination of Dynamic Brain Connectivity via Spectral Analysis

Frontiers in Human Neuroscience ◽

10.3389/fnhum.2021.655576 ◽

2021 ◽

Vol 15 ◽

Author(s):

Peter A. Robinson ◽

James A. Henderson ◽

Natasha C. Gabay ◽

Kevin M. Aquino ◽

Tara Babaie-Janvier ◽

...

Keyword(s):

Spectral Analysis ◽

Brain Structure ◽

Brain Connectivity ◽

Spatial Scales ◽

Effective Connectivity ◽

Physical Nature ◽

Building Blocks ◽

Brain Dynamics ◽

Compact Representation ◽

The Brain

Spectral analysis based on neural field theory is used to analyze dynamic connectivity via methods based on the physical eigenmodes that are the building blocks of brain dynamics. These approaches integrate over space instead of averaging over time and thereby greatly reduce or remove the temporal averaging effects, windowing artifacts, and noise at fine spatial scales that have bedeviled the analysis of dynamical functional connectivity (FC). The dependences of FC on dynamics at various timescales, and on windowing, are clarified and the results are demonstrated on simple test cases, demonstrating how modes provide directly interpretable insights that can be related to brain structure and function. It is shown that FC is dynamic even when the brain structure and effective connectivity are fixed, and that the observed patterns of FC are dominated by relatively few eigenmodes. Common artifacts introduced by statistical analyses that do not incorporate the physical nature of the brain are discussed and it is shown that these are avoided by spectral analysis using eigenmodes. Unlike most published artificially discretized “resting state networks” and other statistically-derived patterns, eigenmodes overlap, with every mode extending across the whole brain and every region participating in every mode—just like the vibrations that give rise to notes of a musical instrument. Despite this, modes are independent and do not interact in the linear limit. It is argued that for many purposes the intrinsic limitations of covariance-based FC instead favor the alternative of tracking eigenmode coefficients vs. time, which provide a compact representation that is directly related to biophysical brain dynamics.

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Semiconductor Quantum Dots

Materials Research Foundations - Quantum Dots - Properties and Applications ◽

10.21741/9781644901250-12 ◽

2021 ◽

pp. 305-330

Keyword(s):

Quantum Dots ◽

Optoelectronic Devices ◽

Building Blocks ◽

Semiconductor Quantum Dots ◽

Continuous Absorption ◽

Semiconductor Particles ◽

Spatial Dimensions ◽

Definition Of ◽

Narrow Emission

Semiconductor particles in the range of 2-10 nm are known as quantum dots (QDs) and nano-crystals where in all the three spatial dimensions, excitons are confined. Because of very small size and special electronic properties, QDs are expected to be building blocks of many electronic and optoelectronic devices. These particles possess tunable quantum efficiency, continuous absorption spectra, narrow emission and long term photostability. These are important for various biomedical applications. In this chapter definition of semiconductor QDs, their methods of preparation and characterization along with their properties and applications have been discussed.

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