Alexander Grüneis

What is he best known for?

The fields of study he is best known for:

• Photon
• Semiconductor
• Graphene

His main research concerns Carbon nanotube, Molecular physics, Raman spectroscopy, Nanotechnology and Graphene. His Carbon nanotube research is mostly focused on the topic Optical properties of carbon nanotubes. His Molecular physics study combines topics from a wide range of disciplines, such as Graphite and Scattering.

The concepts of his Raman spectroscopy study are interwoven with issues in Phonon, Condensed matter physics, Molecular electronic transition and Nuclear magnetic resonance. His biological study spans a wide range of topics, including Carbon and Doping. His primary area of study in Graphene is in the field of Graphene nanoribbons.

His most cited work include:

• Nitrogen-Doped Graphene: Efficient Growth, Structure, and Electronic Properties (530 citations)
• Graphene epitaxy by chemical vapor deposition on SiC. (256 citations)
• Graphene epitaxy by chemical vapor deposition on SiC. (256 citations)

What are the main themes of his work throughout his whole career to date?

Graphene, Carbon nanotube, Raman spectroscopy, Condensed matter physics and Photoemission spectroscopy are his primary areas of study. His biological study focuses on Graphene nanoribbons. His Carbon nanotube research is under the purview of Nanotechnology.

His Chemical vapor deposition study, which is part of a larger body of work in Nanotechnology, is frequently linked to Heteroatom, bridging the gap between disciplines. His Raman spectroscopy study deals with Phonon intersecting with Dispersion relation. His study in Photoemission spectroscopy is interdisciplinary in nature, drawing from both Fermi level, Doping, Electronic structure, Dirac fermion and Electronic band structure.

He most often published in these fields:

• Graphene (43.95%)
• Carbon nanotube (39.49%)
• Raman spectroscopy (29.30%)

What were the highlights of his more recent work (between 2016-2021)?

• Graphene (43.95%)
• Graphene nanoribbons (22.29%)
• Raman spectroscopy (29.30%)

In recent papers he was focusing on the following fields of study:

His primary scientific interests are in Graphene, Graphene nanoribbons, Raman spectroscopy, Condensed matter physics and Photoemission spectroscopy. Alexander Grüneis has included themes like Monolayer, Optoelectronics, Electronic structure, Angle-resolved photoemission spectroscopy and Molecular physics in his Graphene study. His Graphene nanoribbons study also includes fields such as

• Epitaxy, Molecular beam epitaxy, Nanotechnology and Laser most often made with reference to Photoluminescence,
• Band gap which intersects with area such as Substrate,
• Plasmon, which have a strong connection to Polarization, Ribbon and Spectral width.

His Raman spectroscopy research focuses on subjects like Phonon, which are linked to Raman scattering and Binding energy. His Condensed matter physics study incorporates themes from Fermi level and Density functional theory. His Photoemission spectroscopy research is multidisciplinary, incorporating perspectives in Bilayer graphene and Electronic band structure.

Between 2016 and 2021, his most popular works were:

• Making Graphene Nanoribbons Photoluminescent (36 citations)
• Massive and massless charge carriers in an epitaxially strained alkali metal quantum well on graphene (26 citations)
• Direct observation of a surface resonance state and surface band inversion control in black phosphorus (24 citations)

In his most recent research, the most cited papers focused on:

• Photon
• Semiconductor
• Organic chemistry

Alexander Grüneis mainly focuses on Graphene, Photoemission spectroscopy, Condensed matter physics, Angle-resolved photoemission spectroscopy and Graphene nanoribbons. His Graphene research is multidisciplinary, incorporating elements of Optoelectronics, Electronic structure and Raman spectroscopy. His research in Photoemission spectroscopy intersects with topics in Molecular physics and Electronic band structure.

His work in Electronic band structure addresses issues such as Scanning tunneling spectroscopy, which are connected to fields such as Density wave theory, Monolayer, Phonon, Partial charge and Free electron model. The Condensed matter physics study combines topics in areas such as Bilayer graphene and Fermi level. He has researched Graphene nanoribbons in several fields, including Effective mass and Band gap.

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