Roland Böhmer

What is he best known for?

The fields of study he is best known for:

• Quantum mechanics
• Organic chemistry
• Hydrogen

His main research concerns Condensed matter physics, Supercooling, Dielectric, Relaxation and Glass transition. His research integrates issues of Spectroscopy and Nanoscopic scale in his study of Condensed matter physics. His Supercooling research entails a greater understanding of Thermodynamics.

His Dielectric research is multidisciplinary, relying on both Crystallography, Inorganic compound, Electric field and Quantum tunnelling. His studies in Relaxation integrate themes in fields like Chemical physics and Analytical chemistry. In Glass transition, Roland Böhmer works on issues like Length scale, which are connected to Dynamical heterogeneity and Molecular motion.

His most cited work include:

• Correlations of the nonexponentiality and state dependence of mechanical relaxations with bond connectivity in Ge-As-Se supercooled liquids. (399 citations)
• Nonresonant Spectral Hole Burning in the Slow Dielectric Response of Supercooled Liquids (249 citations)
• Dynamics of supercooled liquids and glassy solids (220 citations)

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

His primary areas of investigation include Dielectric, Condensed matter physics, Relaxation, Dielectric spectroscopy and Analytical chemistry. He has included themes like Chemical physics, Relaxation, Nuclear magnetic resonance and Thermodynamics in his Dielectric study. His Condensed matter physics study which covers Dipole that intersects with Solid solution.

His research on Relaxation often connects related areas such as Supercooling. The various areas that Roland Böhmer examines in his Supercooling study include Deuterium and Glass transition. He usually deals with Analytical chemistry and limits it to topics linked to Spectral line and Molecular physics.

He most often published in these fields:

• Dielectric (32.49%)
• Condensed matter physics (26.35%)
• Relaxation (22.74%)

What were the highlights of his more recent work (between 2014-2021)?

• Chemical physics (18.41%)
• Dielectric (32.49%)
• Dielectric spectroscopy (22.38%)

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

The scientist’s investigation covers issues in Chemical physics, Dielectric, Dielectric spectroscopy, Spectral line and Glass transition. His research in Chemical physics intersects with topics in Supramolecular chemistry, Rheology, Relaxation, Ionic bonding and Debye. His Dielectric research includes elements of Relaxation and Hydrogen bond.

His study in Spectral line is interdisciplinary in nature, drawing from both Molecular physics and Analytical chemistry. The Glass transition study combines topics in areas such as Viscous liquid, Supercooling, Work, Thermodynamics and Amorphous ice. His Supercooling research focuses on subjects like Nuclear magnetic resonance, which are linked to Dielectric loss, Molecule and Hydrate.

Between 2014 and 2021, his most popular works were:

• Colloquium : Water’s controversial glass transitions (89 citations)
• The glass transition in high-density amorphous ice. (36 citations)
• Positive and Negative Mixed Glass Former Effects in Sodium Borosilicate and Borophosphate Glasses Studied by 23Na NMR (22 citations)

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

• Quantum mechanics
• Organic chemistry
• Hydrogen

Analytical chemistry, Dielectric spectroscopy, Glass transition, Hydrogen and Clathrate hydrate are his primary areas of study. His biological study spans a wide range of topics, including Tensor, Inorganic chemistry, Molecular physics, Spins and Oxygen. The study incorporates disciplines such as Relaxation and Amorphous ice in addition to Glass transition.

He interconnects Doping, Ice XII and Phase diagram in the investigation of issues within Hydrogen. His study looks at the relationship between Debye and topics such as Dielectric, which overlap with Supercooling. His work investigates the relationship between Hydrogen bond and topics such as Dielectric loss that intersect with problems in Spectroscopy.

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