His primary areas of study are Carbon nanotube, Nanotechnology, Graphene, Raman spectroscopy and Analytical chemistry. His Carbon nanotube research is under the purview of Composite material. His Nanotechnology research integrates issues from Optoelectronics, Heterojunction and Energy conversion efficiency.
As a part of the same scientific study, Alexandru R. Biris usually deals with the Graphene, concentrating on Inorganic chemistry and frequently concerns with Electrode, Nanoparticle, Uric acid, Linear sweep voltammetry and High-resolution transmission electron microscopy. In his study, Crystallite, Graphite, Scanning electron microscope, Exfoliation joint and Cobalt is strongly linked to X-ray photoelectron spectroscopy, which falls under the umbrella field of Raman spectroscopy. His work in Analytical chemistry addresses subjects such as Absorption, which are connected to disciplines such as Solubility, Enthalpy, Desorption and Atmospheric temperature range.
His scientific interests lie mostly in Carbon nanotube, Nanotechnology, Catalysis, Graphene and Analytical chemistry. As part of his studies on Carbon nanotube, Alexandru R. Biris often connects relevant areas like Raman spectroscopy. Alexandru R. Biris combines subjects such as Optoelectronics, Heterojunction and Energy conversion efficiency with his study of Nanotechnology.
Alexandru R. Biris has included themes like Inorganic chemistry, Acetylene, Hydrocarbon, Carbon and Composite material in his Catalysis study. His studies deal with areas such as Nanoparticle, Nanocomposite, Nanomaterials and Electrode as well as Graphene. As a member of one scientific family, Alexandru R. Biris mostly works in the field of Analytical chemistry, focusing on Dielectric spectroscopy and, on occasion, Linear sweep voltammetry.
Alexandru R. Biris mainly focuses on Graphene, Raman spectroscopy, Nanotechnology, Nanoparticle and Inorganic chemistry. His Graphene research includes elements of Electrochemistry, Nanocomposite, Nanomaterials and Oxide. His Raman spectroscopy study improves the overall literature in Analytical chemistry.
His research links Thermogravimetric analysis with Nanotechnology. His study in Nanoparticle is interdisciplinary in nature, drawing from both Electron paramagnetic resonance, Raman scattering and Composite material. His research investigates the link between Inorganic chemistry and topics such as Hydrogen peroxide that cross with problems in Photochemistry and Nucleobase.
Alexandru R. Biris focuses on Graphene, Raman spectroscopy, Inorganic chemistry, Graphene oxide paper and Oxide. Graphene is the subject of his research, which falls under Nanotechnology. His Nanotechnology study integrates concerns from other disciplines, such as Cell activation, Thermogravimetric analysis and Osteocyte, Osteoblast.
Alexandru R. Biris works mostly in the field of Nanoparticle, limiting it down to topics relating to Quartz crystal microbalance and, in certain cases, Transmission electron microscopy, as a part of the same area of interest. He interconnects Nanocomposite, Catalysis, Hydrogen peroxide and Cytotoxicity in the investigation of issues within Nanomaterials. The Analytical chemistry study combines topics in areas such as Graphite, Scanning electron microscope and Exfoliation joint.
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Light-Harvesting Using High Density p-type Single Wall Carbon Nanotube/n-type Silicon Heterojunctions
Zhongrui Li;Vasyl P. Kunets;Viney Saini;Yang Xu.
ACS Nano (2009)
Carbon Nanotubes: Synthesis, Properties, and Applications
Enkeleda Dervishi;Zhongrui Li;Yang Xu;Viney Saini.
Particulate Science and Technology (2009)
Large-scale graphene production by RF-cCVD method.
Enkeleda Dervishi;Zhongrui Li;Fumiya Watanabe;Abhijit Biswas.
Chemical Communications (2009)
Comparative Study on Different Carbon Nanotube Materials in Terms of Transparent Conductive Coatings
Zhongrui Li;Horn R. Kandel;Enkeleda Dervishi;Viney Saini.
Electrical, Optical, and Morphological Properties of P3HT-MWNT Nanocomposites Prepared by in Situ Polymerization
Viney Saini;Zhongrui Li;Shawn Bourdo;Enkeleda Dervishi.
Journal of Physical Chemistry C (2008)
Does the wall number of carbon nanotubes matter as conductive transparent material
Zhongrui Li;Hom R. Kandel;Enkeleda Dervishi;Viney Saini.
Applied Physics Letters (2007)
Cobalt nanoparticles coated with graphitic shells as localized radio frequency absorbers for cancer therapy
Yang Xu;Meena Mahmood;Zhongrui Li;Enkeleda Dervishi.
Cytotoxicity and biological effects of functional nanomaterials delivered to various cell lines
Meena Mahmood;Daniel A. Casciano;Teodora Mocan;Cornel Iancu.
Journal of Applied Toxicology (2010)
The influence of uric and ascorbic acid on the electrochemical detection of dopamine using graphene-modified electrodes
Stela Pruneanu;Alexandru R. Biris;Florina Pogacean;Crina Socaci.
Electrochimica Acta (2015)
Synergistic enhancement of cancer therapy using a combination of carbon nanotubes and anti-tumor drug.
Meena Mahmood;Alokita Karmakar;Ashley Fejleh;Teodora Mocan.
Nanomedicine: Nanotechnology, Biology and Medicine (2009)
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