7 edition of Physics Potential and Development of Muon Colliders and Neutrino Factories found in the catalog.
November 17, 2000
by American Institute of Physics
Written in English
|The Physical Object|
|Number of Pages||303|
Lepton flavour violation and neutrino physics: beyond the Standard Model, Ana M. Teixeira, arXiv, 28th Rencontres de Blois - Particle Physics and Cosmology, Blois, 29 May - 3 June [Teixeirayrk]. No such neutrino factories or muon colliders exist. Much theoretical research has gone into considering such possibilities. At present the technological know-how does not exist. While many research papers looked into the physics potential and feasibility of such neutrino factories, currently there is no plan to build any.
the Strategy Group and their physics potential and technological feasibility were carefully analyzed. An overview of these projects is given, followed by a summary of the main points of stages of development—from very detailed design reports to short written inputs to the Strategy Group. Muon colliders and γγ colliders offer further. 40 years of neutrino physics: Prog. in Part. and Nucl. Phys. 32 () 1: Special issue devoted to neutrino physics – Proceedings of the International School “Neutrinos in Cosmology, in Astro, Particle, Nuclear Physics”, Erice: review progpn history: Jan H.T. Janka, E. .
Recent results from MiniBooNE and new calculations regarding the anti-neutrino flux from reactors provide exciting new motivation to study neutrino oscillations physics at L/E 1. Using a targeting system similar to the one used for MiniBooNE and a muon storage/decay ring with central E of GeV gives the capability to measure electron. The Future Circular Collider (FCC) is a proposed post-LHC particle accelerator with an energy significantly above that of previous circular colliders (SPS, Tevatron, LHC). After injection at TeV, each beam would have a total energy of MJ. With a centre-of-mass collision energy of TeV (vs 14 TeV at LHC) the total energy value increases to GJ. These total energy .
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An Ever-Expanding Quest of Life and Knowledge
The Neutrino Factory and Muon Collider Collaboration The Case for a Muon Collider † More aﬀordable than an e+e¡ collider at the TeV (LHC) scale. † More aﬀordable than either a hadron or an e+e¡ collider for (eﬀective) energies beyond the LHC.
† Precision initial state superior even to e+e¡. Muon polarization 25%,)CandetermineEbeam to10¡5 viag¡2spinprecession. deliver muon-based facilities, ranging from neutrino factories to muon colliders, that could span research needs at both the intensity and energy frontiers.
The Low EMittance Muon Accelerator (LEMMA) concept. This development prepares the way for a new type of neutrino source (Neutrino Factory) and a new type of very high energy lepton-antilepton collider (Muon Collider).Author: Steve Geer.
The need for intense muon beams for muon colliders and for neutrino factories based on muon storage rings leads to a concept of 1–4 MW proton beams incident on a moving target that is inside a.
Neutrino Factories and Muon Colliders. INTRODUCTION. The muon, which can be thought of as a heavy electron, lives just long enough (τ. 0 =2µs) to enable it to be accelerated to high energy before it decays into an electron, a muon-type neutrino and an electron-type antineutrino.
Over the last decade there has been. Muon colliders and neutrino factories are attractive options for future facilities aimed at achieving the highest lepton-antilepton collision energies and precision measurements of Higgs boson and.
muon-type neutrino and anti-neutrino beams produced from charged pion electron-type neutrinos and anti-neutrinos would enable extremely sensitive measurements of ”e. ”„, ”e. ”¿,and ”e. ”¿ transitions with very low background rates.
Neutrino Factories require very intense beams of muons with energies of a few tens of GeV. Neutrino Factories: Physics Potential. Produced mu mesons can be used in studying different aspects of neutrino and muon physics, and may be considered as an important step towards Author: Steve Geer.
more Muon Colliders, which could operate at center-of-mass energies from the Higgs resonance at GeV up to the multi-TeV scale. An ensemble of facilities built in stages is made possible by the strong synergies between Neutrino Factories and Muon Colliders, both of which require aCited by: 9. At each step, one opens up new physics vistas, leading eventually to a Neutrino Factory and a Muon Collider.
One of the ﬁrst steps toward a Neutrino Factory is a proton driver that can be used to provide intense beams of conventional neutrinos in addition to providing the intense source of low energy muons from pion decay that must be cooled.
The potential for neutrino physics at muon colliders and dedicated high current muon storage rings Current design scenarios for muon colliders [2,1] and neutrino factories [10,4] envision of order positive and negative muons per.
Conceptual design studies are underway for muon colliders and other high-current muon storage rings that have the potential to become the first true “neutrino factories”. Muon decays in long straight sections of the storage rings would produce precisely characterized beams of electron and muon type neutrinos of unprecedented intensity.
This article reviews the. Over the past decade, there has been significant progress in developing the concepts and technologies needed to produce, capture, and accelerate (10) muons per year. These developments have paved the way for a new type of neutrino source (neutrino factory) and a new type of very high energy lepton-antilepton collider (muon collider).
This article reviews. Physics at a Neutrino Factory FERMILAB-FN pp. e-Print Archive: hep- ex/ and I The Potential for Neutrino Physics at Muon Colliders and Dedicated High Current Muon Storage Rings Sep Synergetic to the collider is the neutrino factory concept that is based on racetrack type muon-decay ring production of the neutrinos.
Below we briefly review the concepts and feasibility of the muon accelerator facilities for particle physics research, discuss the status of the corresponding accelerator R&D, and outline directions of the. The physics potential of muon colliders is reviewed, both as Higgs Factories and compact high energy lepton colliders.
The status and timescale of our research and development effort is reviewed as well as the latest designs in cooling channels including the promise of ring coolers in achieving longitudinal and transverse cooling simultaneously.
An overview is given of muon collider technology and of the current status of the muon collider research program. The exciting potential of muon colliders for both neutrino physics and collider physics studies is then described and illustrated using self-consistent collider parameter sets at TeV to TeV center-of-mass energies.
the collider physics. Except at the very highest energy muon colliders, the main thrust of the neutrino physics program would be to improve on the measurements from pre-ceding neutrino experiments at lower energy muon colliders, particularly in the ﬁelds of B physics, quark mixing and CP violation.
Muon colliders at the 10 TeV energy. A STAGED MUON ACCELERATOR FACILITY FOR NEUTRINO AND COLLIDER PHYSICS* Jean-Pierre Delahaye, SLAC, Menlo Park, California evidence for BSM physics with the potential to probe up to extremely high energies.
Neutrino Factories with an possible by the strong synergies between Neutrino Factories and Muon Colliders, both of which require a. The physics potential of an intense source of low-energy muons is studied.
Such a source is a necessary stage towards building the neutrino factories and muon colliders which are being considered at present. The CERN Neutrino Factory could deliver muon beams with intensities 3–4 orders of magnitude.
arXiv:physics/v1 [-ph] 19 Jan MICE-CONF-GEN MICE: The International Muon Ionization Cooling Experiment Daniel M. Kaplan Illinois Institute of Technology, Chicago, IllinoisUSA (for the MICE Collaboration) Abstract.
Ionization cooling of a muon beam is a key technique for a Neutrino Factory or Muon Collider.The Muon Accelerator Program (MAP) was created in to unify the DOE supported R&D in the U.S.
aimed at developing the concepts and technologies required for Muon Colliders and Neutrino Factories. These muon based facilities have the potential to discover and explore new exciting fundamental physics, but will require the development of.Subject: Muon colliders and Neutrino factories: which is triggered either by increasing the strength of the defect potential This has led the Physics Education Research and Development Group at the University of Minnesota to undertake a long-term, multi-stage research program to understand physics instructors' conceptions about the.