Amand Faessler

What is he best known for?

The fields of study he is best known for:

• Quantum mechanics
• Electron
• Particle physics

His primary areas of study are Particle physics, Nuclear physics, Nucleon, Double beta decay and Neutrino. His Meson, Quark, Quark model, Baryon and Isospin study are his primary interests in Particle physics. His Nuclear physics study which covers Atomic physics that intersects with Cross section, Mean field theory and Isotope.

In Nucleon, Amand Faessler works on issues like Quantum electrodynamics, which are connected to Pion, Renormalization and Quantum mechanics. His Double beta decay study also includes

• Random phase approximation, which have a strong connection to Quasiparticle, Pairing and Pseudovector,
• Neutron which intersects with area such as Proton. As part of the same scientific family, Amand Faessler usually focuses on Neutrino, concentrating on Ground state and intersecting with Excited state.

His most cited work include:

• Constraints on the high-density nuclear equation of state from the phenomenology of compact stars and heavy-ion collisions (302 citations)
• Suppression of the two-neutrino double β decay (246 citations)
• Double beta decay (240 citations)

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

Amand Faessler mainly focuses on Particle physics, Nuclear physics, Atomic physics, Nucleon and Quark. His is doing research in Meson, Quark model, Neutrino, Baryon and Pion, both of which are found in Particle physics. His Nuclear physics research includes themes of Heavy ion and Cross section.

His research investigates the link between Atomic physics and topics such as Neutron that cross with problems in Proton and Pairing. Amand Faessler works mostly in the field of Nucleon, limiting it down to topics relating to Quantum electrodynamics and, in certain cases, Quantum mechanics and Hamiltonian. His work in Double beta decay addresses subjects such as Random phase approximation, which are connected to disciplines such as Matrix.

He most often published in these fields:

• Particle physics (40.57%)
• Nuclear physics (36.79%)
• Atomic physics (26.97%)

What were the highlights of his more recent work (between 2007-2021)?

• Particle physics (40.57%)
• Nuclear physics (36.79%)
• Double beta decay (13.13%)

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

Amand Faessler mainly investigates Particle physics, Nuclear physics, Double beta decay, Neutrino and Nucleon. As part of his studies on Nuclear physics, he frequently links adjacent subjects like Production. His Double beta decay study combines topics from a wide range of disciplines, such as Atomic physics, Random phase approximation, Isospin, Beta decay and Beta.

The Random phase approximation study which covers Quasiparticle that intersects with Pairing. His Neutrino research is multidisciplinary, incorporating perspectives in Electron and Electron capture. His Nucleon study integrates concerns from other disciplines, such as Pion, Proton and Mathematical physics.

Between 2007 and 2021, his most popular works were:

• Anatomy of the 0νββ nuclear matrix elements (224 citations)
• Quasi-elastic electroproduction of charged ho -mesons on nucleons (213 citations)
• Beta Decay and the Cosmic Neutrino Background (212 citations)

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

• Quantum mechanics
• Electron
• Particle physics

Amand Faessler mostly deals with Particle physics, Nuclear physics, Hadron, Neutrino and Meson. As part of his studies on Nuclear physics, Amand Faessler often connects relevant subjects like Production. His Hadron research is multidisciplinary, relying on both Molecule, Lambda, Quantum number and Bound state.

His research investigates the connection between Neutrino and topics such as Electron capture that intersect with issues in Atomic physics, Atom and Energy. His Meson research integrates issues from Crystallography and Resonance. His research in Double beta decay intersects with topics in Neutron, Radioactive decay, Isotope and Random phase approximation.

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