J. M. Roney: H-index & Awards - Academic Profile

Research.com Recognitions

Awards & Achievements

2016 - Fellow of American Physical Society (APS) Citation For contributions to lepton flavor violation measurements, detailed studies of the tau lepton, precision measurements of the electroweak interaction, and leadership of the BABAR experiment at SLAC National Accelerator Laboratory

Overview

What is he best known for?

The fields of study he is best known for:

Particle physics
Quantum mechanics
Nuclear physics

Particle physics, Electron–positron annihilation, Nuclear physics, Branching fraction and Particle decay are his primary areas of study. Particle physics connects with themes related to Lepton in his study. His Electron–positron annihilation research includes themes of Crystallography, Invariant mass, Annihilation and Particle identification.

His research in Nuclear physics intersects with topics in Quantum chromodynamics, Asymmetry and Photon. His Branching fraction research incorporates elements of X, Photon energy, Isospin, Analytical chemistry and Semileptonic decay. J. M. Roney interconnects Center, Pair production, Pion and Resonance in the investigation of issues within Particle decay.

His most cited work include:

Indication of Electron Neutrino Appearance from an Accelerator-produced Off-axis Muon Neutrino Beam (1090 citations)
The BABAR detector (738 citations)
Evidence for an excess of B̄→D( *)τ -ν ̄τ decays (550 citations)

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

J. M. Roney mainly focuses on Particle physics, Nuclear physics, Electron–positron annihilation, Branching fraction and B meson. His study ties his expertise on Lepton together with the subject of Particle physics. His Nuclear physics study incorporates themes from Photon, Resonance and Asymmetry.

As a part of the same scientific family, he mostly works in the field of Electron–positron annihilation, focusing on Dalitz plot and, on occasion, Amplitude. While the research belongs to areas of Branching fraction, J. M. Roney spends his time largely on the problem of Particle decay, intersecting his research to questions surrounding Atomic physics. His work deals with themes such as Quantum chromodynamics and Quark, which intersect with Hadron.

He most often published in these fields:

Particle physics (69.66%)
Nuclear physics (52.75%)
Electron–positron annihilation (46.36%)

What were the highlights of his more recent work (between 2011-2021)?

Particle physics (69.66%)
Nuclear physics (52.75%)
Electron–positron annihilation (46.36%)

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

His primary areas of study are Particle physics, Nuclear physics, Electron–positron annihilation, Branching fraction and Meson. His works in CP violation, B meson, Hadron, Collider and Asymmetry are all subjects of inquiry into Particle physics. His Nuclear physics research is multidisciplinary, incorporating elements of Resonance and Photon.

He studied Electron–positron annihilation and Standard Model that intersect with Boson and Higgs boson. His Branching fraction research includes elements of Charmed baryons, Mass spectrum, Form factor, Invariant mass and Cabibbo–Kobayashi–Maskawa matrix. His studies deal with areas such as Pion and Quantum chromodynamics as well as Meson.

Between 2011 and 2021, his most popular works were:

Evidence for an excess of B̄→D( *)τ -ν ̄τ decays (550 citations)
Measurement of an excess of B̄→D(*) τ-ν̄τ decays and implications for charged Higgs bosons (513 citations)
Electroweak measurements in electron positron collisions at W-boson-pair energies at LEP (395 citations)

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

Particle physics
Quantum mechanics
Electron

J. M. Roney mostly deals with Nuclear physics, Particle physics, Electron–positron annihilation, Branching fraction and CP violation. He has researched Nuclear physics in several fields, including Detector and Photon. His Particle physics study is mostly concerned with BaBar experiment, B meson, Asymmetry, Standard Model and Hadron.

His Hadron research includes themes of Cabibbo–Kobayashi–Maskawa matrix and Invariant mass. The concepts of his Electron–positron annihilation study are interwoven with issues in Resonance, Radiation, Resonance and Lepton. Much of his study explores Branching fraction relationship to Mass spectrum.

This overview was generated by a machine learning system which analysed the scientist’s body of work. If you have any feedback, you can contact us here.

Best Publications

The BABAR detector

B. Aubert;A. Bazan;A. Boucham;D. Boutigny.
Nuclear Instruments & Methods in Physics Research Section A-accelerators Spectrometers Detectors and Associated Equipment (2002)

3317 Citations

Indication of Electron Neutrino Appearance from an Accelerator-produced Off-axis Muon Neutrino Beam

K. Abe;N. Abgrall;Y. Ajima;H. Aihara.
Physical Review Letters (2011)

1987 Citations

Observation of CP violation in the B(0) meson system.

Bernard Aubert;D. Boutigny;J.M. Gaillard;A. Hicheur.
Physical Review Letters (2001)

1343 Citations

The BABAR detector: Upgrades, operation and performance

B. Aubert;R. Barate;D. Boutigny;F. Couderc.
Nuclear Instruments & Methods in Physics Research Section A-accelerators Spectrometers Detectors and Associated Equipment (2013)

1157 Citations

Observation of a broad structure in the pi(+)pi(-)J/psi mass spectrum around 4.26 GeV/c(2)

B. Aubert;R. Barate;D. Boutigny;F. Couderc.
Physical Review Letters (2005)

1145 Citations

Measurement of an excess of B̄→D(*) τ-ν̄τ decays and implications for charged Higgs bosons

J. P. Lees;V. Poireau;V. Tisserand;E. Grauges.
Physical Review D (2013)

876 Citations

The OPAL detector at LEP

K Ahmet;A L Fletcher;A Sato;D E Klem.
Physics Letters B (1990)

862 Citations

Search for neutral MSSM Higgs bosons at LEP

S. Schael;R. Barate;R. Bruneliére;I. de Bonis.
European Physical Journal C (2006)