- OSA | International Quantum Electronics Conference.
- Quantum Electronics.
- Deconstructing Sammy: Music, Money, Madness, and the Mob.
- Optical and Quantum Electronics - Springer;
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The Editorial Office of the journal is located at V. Address: 41 Nauky prospekt, office , Kyiv , Ukraine. SPQEO was founded in All articles are accepted and published in English. Issued quarterly, one volume and 4 issues per year. After that the corresponding author receives a copy of an article manuscript with reviewers remarks.
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Reprint version revised by the author and agreed with reviewers is considered the final one and must be signed by the reviewers and authors. Heterostructures consisting of multiple layers of different types of material are also investigated, with the goal of understanding how the structure of the device including imperfections and defects determines its electronic properties.
Recent studies have been performed on gallium nitride and epitaxial graphene. Monodisperse nanoparticles coated with organic surfactants can self-assemble into ordered arrays.
Optical and Quantum Electronics 1/ | tisolofo.tk
The collective magnetic behavior of the arrays has been studied using electron holography and Lorentz microscopy to image domains, and using polarized small angle neutron scattering to investigate the magnetic shell structure due to symmetry breaking at the particle surface. Monolayer arrays are also used as nanoscale templates for pattern transfer into thin films, which could be used to prepare arrays of magnetic devices for data storage media or microwave generation.
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Her group has recently demonstrated the ability of conductive atomic force microscopy to detect the state of a magnetic tunnel junction nanopillar, and switch it using a spin polarized current. They are also developing a method to control the motion of nanoparticles with magnetic tweezers that could later be used to probe within living cells. His group is also interested in understanding new pathways and fundamental mechanisms for solar energy conversion devices.
Pushing the Boundaries in Quantum Electronics
Current focus is on the use of phenomena such as three-dimensional quantum-confinement effects in nanometer-scale structures in the study of novel devices. Examples include: quantum-dot infrared detectors and imaging sensors, electrically-pumped photonic crystal micro-cavity lasers with quantum-dot active regions, multi-spectral solar energy conversion devices, plasmonic bio-sensors, and fluorescence bio-sensing devices.
By combining quantum-based total energy calculations with classical statistical mechanics one can model the free energy of bulk phases and nanostructures in order to predict structures and properties of compounds as functions of chemical composition and temperature.
ysibedeb.tk Recent studies considered the structures of thin films at surfaces and grain boundary complexions, as well as nanocrystalline models of bulk metallic glass. One major direction of his research is to understand and predict material properties transport, magnetic, and optical from the viewpoint of Berry phase and topology. In particular, he is interested in topological phenomena arising from spin-orbit coupling and many-body interactions.
These phenomena are often characterized by novel electromagnetic responses, which may be useful for applications in quantum electronics and quantum computing. He is also interested in innovative designs of magnetic random access memory MRAM. The research focuses on novel MRAM designs that offer robust and repeatable magnetic switching characteristic, low operation power capability, and sufficient thermal-magnetic stability.
Micromagnetic modeling on computers is utilized to aid the design process and the devices are fabricated using the state-of-the-art e-beam and optical lithographic fabrication technology. His group is also working to understand noise in nano-magnetic systems, arising from thermally excited magnetization precession or spin current induced chaotic spin waves.
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Theoretical analysis and experimental measurements are performed in order to obtain a good understanding of the noise and the corresponding underlying physics. Quantum Electronics. Conduction electrons interact with spin waves, domain walls, film interfaces and other disturbances of the magnetic spin system through the s-d exchange energy and through hydromagnetic forces.
The conduction electrons also undergo anisotropic scattering by magnetized chemical impurities through the spin-orbit energy.