What is he best known for?
The fields of study Amir Boag is best known for:
- Kelvin probe force microscope
- Photon
- Piezoresponse force microscopy
His Mathematical analysis study frequently draws parallels with other fields, such as Integral equation, Discretization, Exponential function, Boundary (topology) and Domain (mathematical analysis).
Amir Boag incorporates Domain (mathematical analysis) and Mathematical analysis in his research.
His research on Geometry often connects related areas such as Rotation (mathematics), Regular polygon, Surface (topology) and Grid.
His Surface (topology) study frequently draws connections between adjacent fields such as Geometry.
Amir Boag is involved in relevant fields of research such as Computational complexity theory, Computation and Iterative method in the field of Algorithm.
By researching both Computation and Algorithm, Amir Boag produces research that crosses academic boundaries.
Many of his studies on Programming language apply to Reflection (computer programming) and Interpretation (philosophy) as well.
His Interpretation (philosophy) study frequently draws connections to other fields, such as Programming language.
Sagnac effect and Ring laser gyroscope are inextricably linked to his Gyroscope research.
His most cited work include:
- Highly Efficient and Broadband Wide-Angle Holography Using Patch-Dipole Nanoantenna Reflectarrays (130 citations)
- Multilevel evaluation of electromagnetic fields for the rapid solution of scattering problems (80 citations)
- The role of the cantilever in Kelvin probe force microscopy measurements (65 citations)
What are the main themes of his work throughout his whole career to date
Amir Boag applies the principles of Scattering and Electromagnetic field in his work under Quantum mechanics.
With his scientific publications, his incorporates both Scattering and Quantum mechanics.
Amir Boag links relevant research areas such as Boundary value problem and Boundary (topology) in the realm of Mathematical analysis.
His work in Boundary (topology) is not limited to one particular discipline; it also encompasses Mathematical analysis.
His Telecommunications research is intertwined with Antenna (radio) and Frame (networking).
Amir Boag connects Frame (networking) with Telecommunications in his study.
Amir Boag merges many fields, such as Optics and Optoelectronics, in his writings.
Amir Boag undertakes multidisciplinary studies into Optoelectronics and Optics in his work.
His study on Geometry is mostly dedicated to connecting different topics, such as Grid.
Amir Boag most often published in these fields:
- Optics (66.07%)
- Quantum mechanics (53.57%)
- Mathematical analysis (46.43%)
What were the highlights of his more recent work (between 2017-2022)?
- Telecommunications (57.14%)
- Optics (57.14%)
- Wireless (28.57%)
In recent works Amir Boag was focusing on the following fields of study:
In the field of Composite material Amir Boag connects related research areas like Electrical conductor, Compression (physics) and Matrix (chemical analysis).
His Matrix (chemical analysis) study frequently links to other fields, such as Composite material.
His study of Embedded system brings together topics like Field-programmable gate array and Computer architecture.
While working on this project, he studies both Computer architecture and Embedded system.
He is involved in relevant fields of research such as Compression (physics) and Compressibility in the realm of Thermodynamics.
He performs integrative Compressibility and Thermodynamics research in his work.
He merges Telecommunications with Wireless in his research.
In his articles, he combines various disciplines, including Wireless and Telecommunications.
By researching both Optics and Specular reflection, he produces research that crosses academic boundaries.
Between 2017 and 2022, his most popular works were:
- Artificial localized magnon resonances in subwavelength meta-particles (16 citations)
- Volumetric 3D‐Printed Antennas, Manufactured via Selective Polymer Metallization (15 citations)
- Shadow Radiation Iterative Physical Optics Method for High-Frequency Scattering (13 citations)
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