Proposal for continuation of UK participation in the International Muon Ionization Cooling Experiment

关于英国继续参与国际μ介子电离冷却实验的提案

• 批准号: ST/J001953/1
• 负责人: Kevin Ronald
• 金额: $ 39.07万
• 依托单位: University of Strathclyde
• 依托单位国家: 英国
• 项目类别: Research Grant
• 财政年份: 2012
• 资助国家: 英国
• 起止时间: 2012 至 无数据
• 项目状态: 已结题
• 来源: https://gtr.ukri.org/projects?ref=ST%2FJ001953%2F1
• 关键词: Proposal; continuation; UK; participation; International

Neutrinos are three different but related particles; their ability to turn into each other has given physicists their first glimpse of the physics which they know must lay beyond the Standard Model. Investigation of the physics which underlies their properties will: deepen our understanding of how the Universe developed after the Big Bang; how the current asymmetry between matter and anti-matter developed from a situation where they were created in equal amounts in the Big Bang; and help us to understand what happens when a supernova explodes showering the cosmos with the heavy elements necessary for planets and life itself to form. In order to understand their properties, we must build an accelerator capable of creating neutrinos in immense numbers. They must have energy between well-defined limits and the mixture of different types must be very precisely known. Such a facility, known as the Neutrino Factory, would be revolutionary and to build one is a challenging project, both from the point of view of the particle detectors which must be built, and the engineering problems which must be overcome. This programme needs a world-wide collaboration, but it is one in which physicists and engineers from the UK are playing a leading role.Neutrinos are created from a beam of muons and the muons themselves are produced from the decay of pions produced by the collision of protons with a metal target. A machine to make an intense beam of neutrinos needs to take the beam of muons, which is large and diverges rapidly, and reduce its size and divergence. The resulting beam can be accelerated, stored and when it decays produces an intense beam of neutrinos. The muons only live for 2.2 microseconds when at rest, and even when they are accelerated and their lifetime is extended by the effect of relativity, there is little time to manipulate the muons so that they are in a state to be accelerated.MICE is an international collaboration based at the Rutherford Appleton Laboratory in Oxfordshire, which uses a beam of muons created by the ISIS accelerator and aims to show that it is feasible to create such an intense beam. It will do this by creating a beam of muons of much lower intensity and tracking each one individually through one part of the system which has been designed to perform this beam compression at the Neutrino Factory. This process where the random sideways motions of the muons are reduced and we are left with the longitudinal motion is referred to as cooling the beam; the system which performs the cooling is known as the cooling channel.The first stage was to build a system capable of producing a muon beam whose size and divergence could be adjusted before it enters the cooling channel. This was completed last year and measurements have been made to show that the beam has the flexibility and intensity for MICE to perform the required measurements.The second stage is to finish construction of the cooling channel itself and to provide a system to measure very accurately the position and momentum of each muon before and after it has passed through the cooling channel. By looking at many muons produced in many different conditions, it will be possible to determine how much cooling has been produced by the channel. In the channel itself the muons will be slowed by passing through a suitable material, such as liquid hydrogen, liquid helium or lithium hydride. As they slow they lose momentum both longitudinally and transversely to the beam axis. Then they are accelerated with high field radio frequency cavities, replacing only the longitudinal momentum.This experiment which is pushing the boundaries of what is possible with materials, magnets and cooling technologies, represents a collaboration between particle physicists, and accelerator physicists and will demonstrate the UK's ability to host an experiment at the forefront of science and engineering.

中微子是三种不同但相关的粒子；它们相互转化的能力让物理学家第一次看到了物理学，他们知道物理学必须超越标准模型。对它们特性背后的物理学的研究将：加深我们对大爆炸后宇宙如何发展的理解；当前物质和反物质之间的不对称性是如何从大爆炸中等量产生物质和反物质的情况发展而来的；并帮助我们了解当超新星爆炸时会发生什么，向宇宙喷洒行星和生命本身形成所需的重元素。为了了解它们的特性，我们必须建造一个能够产生大量中微子的加速器。它们的能量必须在明确定义的极限之间，并且必须非常精确地了解不同类型的混合物。这样一个被称为中微子工厂的设施将是革命性的，无论是从必须建造的粒子探测器还是从必须克服的工程问题的角度来看，建造一个设施都是一项具有挑战性的项目。该计划需要世界范围内的合作，但英国的物理学家和工程师在其中发挥了主导作用。中微子是由一束μ子产生的，而μ子本身是由碰撞产生的π介子衰变产生的质子与金属靶。制造强中微子束的机器需要吸收大且发散迅速的μ介子束，并减小其尺寸和发散度。产生的光束可以被加速、储存，并且当它衰变时会产生强烈的中微子束。 μ子在静止状态下的寿命只有2.2微秒，即使它们被加速并且由于相对论效应延长了它们的寿命，也几乎没有时间操纵μ子使其处于加速状态。MICE是一种牛津郡卢瑟福阿普尔顿实验室的国际合作，使用 ISIS 加速器产生的 μ 子束，旨在证明产生如此强烈的光束是可行的。它将通过创建一束强度低得多的μ子束并通过系统的一个部分单独跟踪每个μ子束来实现这一点，该系统的设计目的是在中微子工厂执行这种束压缩。 μ 子的随机侧向运动减少而留下纵向运动的过程被称为冷却光束；执行冷却的系统称为冷却通道。第一阶段是建立一个能够产生μ介子束的系统，其尺寸和发散度可以在进入冷却通道之前进行调整。该项目已于去年完成，测量结果表明该梁具有 MICE 执行所需测量所需的灵活性和强度。第二阶段是完成冷却通道本身的构造，并提供一个系统来非常准确地测量冷却通道的温度。每个μ子通过冷却通道前后的位置和动量。通过观察在许多不同条件下产生的许多μ子，将可以确定通道产生了多少冷却。在通道本身中，μ子将通过穿过合适的材料（例如液氢、液氦或氢化锂）而减慢速度。当它们减速时，它们会失去梁轴纵向和横向的动量。然后用高场射频腔对其进行加速，仅取代纵向动量。该实验突破了材料、磁铁和冷却技术的可能性界限，代表了粒子物理学家和加速器物理学家之间的合作，并将展示英国有能力在科学和工程的前沿举办实验。

项目成果

First particle-by-particle measurement of emittance in the Muon Ionization Cooling Experiment

Mu 子电离冷却实验中首次逐个粒子测量发射度

• DOI: 10.1140/epjc/s10052-019-6674-y
• 发表时间: 2019
• 期刊: The European Physical Journal C
• 作者: Adams D

Pion contamination in the MICE muon beam

• DOI: 10.1088/1748-0221/11/03/p03001
• 发表时间: 2015-11
• 期刊: Journal of Instrumentation
• 影响因子: 1.3
• 作者: D. Adams;A. Alekou;M. Apollonio;R. Asfandiyarov;G. Barber;P. Barclay;A. Bari;R. Bayes;V. Bayliss;R. Bertoni;V. Blackmore;A. Blondel;S. Blot;M. Bogomilov;M. Bonesini;C. Booth;D. Bowring;S. Boyd;T. W. Brashaw;U. Bravar;A. Bross;M. Capponi;T. Carlisle;G. Cecchet;C. Charnley;F. Chignoli;D. Cline;J. Cobb;G. Colling;N. Collomb;L. Coney;P. Cooke;M. Courthold;L. Cremaldi;A. Demello;A. Dick;A. Dobbs;P. Dornan;M. Drews;F. Drielsma;F. Filthaut;T. Fitzpatrick;P. Franchini;V. Francis;L. Fry;A. Gallagher;R. Gamet;R. Gardener;S. Gourlay;Alec Grant;J. R. Greis;S. Griffiths;P. Hanlet;O. M. Hansen;G. Hanson;T. L. Hart;T. Hartnett;T. Hayler;C. Heidt;M. Hills;P. Hodgson;C. Hunt;A. Iaciofano;S. Ishimoto;G. Kafka;D. Kaplan;Y. Karadzhov;Y. K. Kim;Y. Kuno;P. Kyberd;J. Lagrange;J. Langlands;W. Lau;M. Leonova;Derun Li;A. Lintern;M. Littlefield;K. Long;T. Luo;C. Macwaters;B. Martlew;J. Martyniak;R. Mazza;S. Middleton;A. Moretti;A. Moss;A. Muir;I. Mullacrane;J. Nebrensky;D. Neuffer;A. Nichols;R. Nicholson;J. Nugent;A. Oates;Y. Onel;D. Orestano;E. Overton;P. Owens;V. Palladino;J. Pasternak;F. Pastore;C. Pidcott;M. Popovic;R. Preece;S. Prestemon;D. Rajaram;S. Ramberger;M. Rayner;S. Ricciardi;T. Roberts;M. Robinson;C. Rogers;K. Ronald;P. Rubinov;P. Rucinski;H. Sakamato;D. Sanders;E. Santos;T. Savidge;P. Smith;P. Snopok;F. Soler;D. Speirs;T. Stanley;G. Stokes;D. Summers;J. Tarrant;I. Taylor;L. Tortora;Y. Torun;R. Tsenov;C. D. Tunnell;M. Uchida;G. Vankova-Kirilova;S. Virostek;M. Vretenar;P. Warburton;S. Watson;C. White;C. Whyte;A. Wilson;M. Winter;X. Yang;A. Young;M. Zisman

The Progress on the MICE RF System

MICE射频系统研究进展

• 发表时间: 2015
• 作者: Dick A

Emittance Measurement in the Muon Ionization Cooling Experiment

μ子电离冷却实验中的发射测量

• DOI: 10.22323/1.282.0868
• 发表时间: 2017
• 作者: Blackmore V

Lattice design and expected performance of the Muon Ionization Cooling Experiment demonstration of ionization cooling

μ子电离冷却的晶格设计和预期性能 电离冷却实验演示

• DOI: 10.1103/physrevaccelbeams.20.063501
• 发表时间: 2017
• 期刊: Physical Review Accelerators and Beams
• 影响因子: 1.7
• 作者: Bogomilov M