What is he best known for?
The fields of study he is best known for:
- Semiconductor
- Ceramic
- Aluminium
K. Sreenivas mostly deals with Thin film, Sputtering, Analytical chemistry, Optoelectronics and Mineralogy.
K. Sreenivas is studying Sputter deposition, which is a component of Thin film.
The Sputtering study which covers Amorphous solid that intersects with Tellurium oxide and Barium titanate.
His work in Analytical chemistry tackles topics such as Pulsed laser deposition which are related to areas like Surface phonon.
His Mineralogy research includes elements of Ceramic and Dielectric, Permittivity.
His work in Dielectric addresses subjects such as Composite material, which are connected to disciplines such as Carbon film and Ferroelectricity.
His most cited work include:
- Analysis of ultraviolet photoconductivity in ZnO films prepared by unbalanced magnetron sputtering (276 citations)
- Investigation of Pt/Ti bilayer metallization on silicon for ferroelectric thin film integration (247 citations)
- Cholesterol biosensor based on rf sputtered zinc oxide nanoporous thin film (212 citations)
What are the main themes of his work throughout his whole career to date?
His scientific interests lie mostly in Analytical chemistry, Thin film, Dielectric, Optoelectronics and Ferroelectricity.
As part of one scientific family, K. Sreenivas deals mainly with the area of Analytical chemistry, narrowing it down to issues related to the Doping, and often Pulsed laser deposition.
His biological study spans a wide range of topics, including Amorphous solid, Layer and Surface acoustic wave.
His Dielectric research is multidisciplinary, relying on both Composite material, Ceramic and Mineralogy.
In his study, Electromechanical coupling coefficient is strongly linked to Substrate, which falls under the umbrella field of Optoelectronics.
His Ferroelectricity study also includes fields such as
- Orthorhombic crystal system which is related to area like Ferroelectric ceramics,
- Piezoelectric coefficient that connect with fields like Bismuth.
He most often published in these fields:
- Analytical chemistry (48.69%)
- Thin film (45.03%)
- Dielectric (34.55%)
What were the highlights of his more recent work (between 2016-2021)?
- Analytical chemistry (48.69%)
- Ceramic (16.75%)
- Dielectric (34.55%)
In recent papers he was focusing on the following fields of study:
His primary areas of study are Analytical chemistry, Ceramic, Dielectric, Raman spectroscopy and Doping.
His Analytical chemistry study combines topics in areas such as Tetragonal crystal system, Fourier transform infrared spectroscopy and Dopant.
K. Sreenivas combines subjects such as Sintering, Grain growth and Calcination with his study of Ceramic.
His work in the fields of Dielectric, such as Ferroelectricity and Dielectric loss, overlaps with other areas such as Atmospheric temperature range.
His Dielectric loss study integrates concerns from other disciplines, such as Charge carrier, Microstructure, Grain boundary, Variable-range hopping and Crystallite.
His Raman spectroscopy research is multidisciplinary, incorporating perspectives in Thermogravimetric analysis, Bond length and Infrared spectroscopy.
Between 2016 and 2021, his most popular works were:
- 980 nm excited Er 3+ /Yb 3+ /Li + /Ba 2+ : NaZnPO 4 upconverting phosphors in optical thermometry (61 citations)
- Enhanced infrared-to-visible up-conversion emission and temperature sensitivity in (Er3+,Yb3+, and W6+) tri-doped Bi4Ti3O12 ferroelectric oxide (23 citations)
- Structural and electrical properties of Dy3+ substituted NiFe2O4 ceramics prepared from powders derived by combustion method (9 citations)
In his most recent research, the most cited papers focused on:
- Semiconductor
- Ceramic
- Aluminium
K. Sreenivas mainly investigates Analytical chemistry, Ferroelectricity, Tetragonal crystal system, Raman spectroscopy and Ceramic.
K. Sreenivas interconnects Fourier transform infrared spectroscopy, Dielectric loss, Dielectric and Doping in the investigation of issues within Analytical chemistry.
His studies deal with areas such as Microstructure, Grain boundary, Electrical resistivity and conductivity, Crystallite and Grain size as well as Dielectric loss.
His Tetragonal crystal system study combines topics from a wide range of disciplines, such as Orthorhombic crystal system, Acceptor and Grain growth.
His Raman spectroscopy research includes themes of Bond length, X-ray crystallography, Bravais lattice, Elastic modulus and Superconductivity.
The study incorporates disciplines such as Pyroelectricity, Ferroelectric ceramics, Activation energy and Permittivity in addition to Ceramic.
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