Reversible Amorphous‐to‐Amorphous Transitions in Chalcogenide Films: Correlating Changes in Structure and Optical Properties

Wang

Physica Rapid Research Ltrs

2019

Neuromorphic computing based on a non‐von Neumann architecture is a promising way for the efficient implementation of artificial intelligence. A neuromorphic computing system is mainly composed of artificial synapses and neurons. Various electronic neuromorphic devices have been developed by different technologies. Neuromorphic photonics combines the efficiency of neural networks and the speed of photonics to build computing systems. Compared with their electronic counterparts, photonic neurons and synapses have the potential advantages of ultrafast operation speed, large bandwidth, and no electrical interconnect power loss, inherent to the computing by optical means. Therefore, photonic neuromorphic devices are attracting more and more attention. This work reviews the recent advances in the development of photonic synapses. Both purely photonic synapses and photoelectric synapses are described. Their structures and working mechanisms are discussed in detail.

Section: Purely Photonic Synapsesmentioning

confidence: 99%

Photonic Synapses for Ultrahigh‐Speed Neuromorphic Computing

Wang

Physica Rapid Research Ltrs

2019

“…Thin film materials have specific properties enabling important technological advances, particularly in the fields of solar cells , micro‐electronics , displays and lighting , and information storage . The implementation of these materials is sometimes limited by the lack of knowledge on how changes in the composition and structure of the thin film can affect its properties, such as thermal conductivity.…”

Section: Introductionmentioning

confidence: 99%

Thermal conductivity measurements of thin films at high temperature modulated photothermal radiometry at LNE

Fleurence

Hay

Davée

et al. 2015

Phys. Status Solidi A

A new metrological facility devoted to the thermal conductivity measurements up to 1000 °C for thin films (from few tens nanometers to few micrometers thick) deposited on substrate has been recently designed at LNE. Its measurement principle is based on the infrared modulated photothermal radiometry technique (MPTR). This device has been applied to the thermal characterization of industrially relevant chalcogenide thin films (Ge2Sb2Ti5) up to 400 °C. This work, performed in the frame of the European joint research project “Thin Films,” seeks to improve the traceability to the International System of Units (SI) as well as the reliability of this type of measurements at sub‐micrometer scale.

Journal of Applied Physics

“…12 On the contrary, in the limit of the chalcogen-poor composition regime, the structure is self-organized into molecular units (e.g., cage-like molecules) where the presence of homopolar (metal-metal) bonds is the key ingredient of photosensitivity. 13 The hallmark of several chalcogenides, which is ultimately related to their enhanced photosensitivity, is the simultaneous presence of strong covalent and weak van der Waals interactions, both in the crystalline phases and their amorphous counterparts. 7,11 The "sub-lattice" of the weak bonds is the one that contains the entities that are easily responsive to light.…”

Section: Introductionmentioning

confidence: 99%

Photo-induced oxidation and amorphization of trigonal tellurium: A means to engineer hybrid nanostructures and explore glass structure under spatial confinement

Vasileiadis

Yannopoulos

2014

Self Cite

Controlled photo-induced oxidation and amorphization of elemental trigonal tellurium are achieved by laser irradiation at optical wavelengths. These processes are monitored in situ by time-resolved Raman scattering and ex situ by electron microscopies. Ultrathin TeO2 films form on Te surfaces, as a result of irradiation, with an interface layer of amorphous Te intervening between them. It is shown that irradiation, apart from enabling the controllable transformation of bulk Te to one-dimensional nanostructures, such as Te nanotubes and hybrid core-Te/sheath-TeO2 nanowires, causes also a series of light-driven (athermal) phase transitions involving the crystallization of the amorphous TeO2 layers and its transformation to a multiplicity of crystalline phases including the γ-, β-, and α-TeO2 crystalline phases. The kinetics of the above photo-induced processes is investigated by Raman scattering at various laser fluences revealing exponential and non-exponential kinetics at low and high fluence, respectively. In addition, the formation of ultrathin (less than 10 nm) layers of amorphous TeO2 offers the possibility to explore structural transitions in 2D glasses by observing changes in the short- and medium-range structural order induced by spatial confinement.