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M. Hance

ORCID: 0000-0001-8392-0934
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About
Contact & Profiles
A5105755939
Research Areas
  • Particle physics theoretical and experimental studies
  • High-Energy Particle Collisions Research
  • Particle Detector Development and Performance
  • Quantum Chromodynamics and Particle Interactions
  • Dark Matter and Cosmic Phenomena
  • Neutrino Physics Research
  • Cosmology and Gravitation Theories
  • Computational Physics and Python Applications
  • Distributed and Parallel Computing Systems
  • Radiation Detection and Scintillator Technologies
  • Medical Imaging Techniques and Applications
  • Astrophysics and Cosmic Phenomena
  • Black Holes and Theoretical Physics
  • Atomic and Subatomic Physics Research
  • Digital Radiography and Breast Imaging
  • Advanced Data Storage Technologies
  • Autoimmune and Inflammatory Disorders Research
  • Kawasaki Disease and Coronary Complications
  • Superconducting Materials and Applications
  • Muon and positron interactions and applications
  • SARS-CoV-2 detection and testing
  • Algorithms and Data Compression
  • Particle Accelerators and Free-Electron Lasers
  • Adolescent and Pediatric Healthcare
  • Advanced Semiconductor Detectors and Materials

University of California, Santa Cruz
 2016-2025

Northern Illinois University
 2023-2024

Institute for High Energy Physics
 2023-2024

Atlas Scientific (United States)
 2024

Institute of Science and Technology
 2023-2024

A. Alikhanyan National Laboratory
 2024

The University of Adelaide
 2017-2023

University of Toronto
 2023

Ludwig-Maximilians-Universität München
 2020

Philadelphia University
 2020

 Chapter 3: Beyond the Standard Model Phenomena
OPENALEX - Publications 
T. Golling M. Hance P. Harris M. Mangano Matthew McCullough and 95 more Filip Moortgat Pedro Schwaller Riccardo Torre Prateek Agrawal Daniele S. M. Alves Stefan Antusch A. Arbey B. Auerbach G. Bambhaniya M. Battaglia Martin Bauer P. S. Bhupal Dev A. Boveia Joseph Bramante O. L. Buchmueller Malte Buschmann Joydeep Chakrabortty M. Chala S. Chekanov C. -Y. Chen Heung‐Chin Cheng Marco Cirelli M. Citron Timothy Cohen Nathaniel Craig David Curtin Raffaele Tito D’Agnolo C. Doglioni Jeff A. Dror Tristan Du Pree Daniel Dylewsky J. Ellis Sebastian A. R. Ellis Rouven Essig JiJi Fan Marco Farina Jonathan L. Feng Patrick J. Fox Jamison Galloway Gian F. Giudice J. Gluza Stefania Gori Sunny Guha K. A. Hahn Tao Han C. Helsens A. Henriques Sho Iwamoto Tomasz Jeliński Seung‐Jo Jung Felix Kahlhoefer Valentin V. Khoze D. Kim Joachim Kopp A. Kotwal M. Gabriela Kramer Jonas M. Lindert Jia Liu Hou Keong Lou J. Love Matthew Low P. Machado F. Mahmoudi J. Marrouche A. Martin Kirtimaan A. Mohan R. N. Mohapatra Germano Nardini Keith A. Olive Bryan Ostdiek Giuliano Panico Tilman Plehn J. Proudfoot Zhihong Qian Matthew Reece Thomas G. Rizzo C. Roskas Joshua T. Ruderman Richard Ruíz Filippo Sala Ennio Salvioni Prashant Saraswat Torben Schell Kai Schmidt-Hoberg Javi Serra Yonatan Shadmi Jessie Shelton Carlos Solans Michael Spannowsky Tripurari Srivastava Daniel Stolarski Robert Szafron Marco Taoso S. Tarem Arun M. Thalapillil

10.23731/cyrm-2017-003.441 article EN other-oa OSTI OAI (U.S. Department of Energy Office of Scientific and Technical Information) 2017-06-22
 Improved Measurement of the Positive-Muon Lifetime and Determination of the Fermi Constant
OPENALEX - Publications 
D. B. Chitwood T. Banks Michael Barnes S. Battu Robert M. Carey and 37 more Santosh Kumar Cheekatmalla Steven Clayton J. Crnkovic K. M. Crowe P. T. Debevec S. Dhamija W. Earle А. Р. Гафаров K. L. Giovanetti T. P. Gorringe F. Gray M. Hance D. W. Hertzog M. Hare P. Kammel B. Kiburg J. Kunkle B. Lauss I. Logashenko Kevin Lynch R. McNabb J. Miller F. Mulhauser C. J. G. Onderwater C. S. Oezben Qiu‐He Peng C. C. Polly Shubhalaxmi Rath B. L. Roberts V. Tishchenko G.D. Wait J. Wasserman D.M. Webber P. Winter Piotr Zolnierczuk null null C. Özben

The mean life of the positive muon has been measured to a precision 11 ppm using low-energy, pulsed beam stopped in ferromagnetic target, which was surrounded by scintillator detector array. result, tau(micro)=2.197 013(24) micros, is excellent agreement with previous world average. new average 019(21) micros determines Fermi constant G(F)=1.166 371(6)x10(-5) GeV-2 (5 ppm). Additionally, measurement positive-muon lifetime needed determine nucleon pseudoscalar coupling g(P).

10.1103/physrevlett.99.032001 article EN Physical Review Letters 2007-07-16
 Characterizing novel Indium Phosphide pad detectors with focused X-ray beams and laboratory tests
OPENALEX - Publications 
E. R. Almazan A. A. Affolder Ian Dyckes V. Fadeyev M. Hance and 10 more M. B. Jadhav Sungjoon Kim Thomas Mccoy J. Metcalfe J. Nielsen J. Ott A. Poley T. Shin D. Sperlich Anirudha V. Sumant

Abstract Future tracking systems in High Energy Physics experiments will require large instrumented areas with low radiation length. Crystalline silicon sensors have been used for decades, but are difficult to manufacture and costly produce areas. We exploring alternative sensor materials that amenable fast fabrication techniques thin film devices. Indium Phosphide pad were fabricated at Argonne National Lab using commercially available InP:Fe 2-inch mono-crystal substrates. Current-voltage...

10.1088/1748-0221/19/11/p11016 article EN Journal of Instrumentation 2024-11-01
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