Proposal for continuation of UK participation in the International Muon Ionization Cooling Experiment: Requested Additional Proposal for Studentship

Lead Research Organisation: University of Strathclyde
Department Name: Physics

Abstract

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.

Planned Impact

MICE is a large, capital construction project. A significant part of the investment in the project has been used to source products and materials in British industry. For example, of the £4.50M non-staff spend in Phase I of the project, approximately £4.09M was used to source materials and equipment in the UK.

The UK is responsible for the procurement of the focus-coil modules that focus the muon beam at the centre of the liquid-hydrogen absorbers. Each focus-coil module contains two coils capable of producing a field of 5 T on axis. The coils will be kept cold using closed-cycle refrigerators (cryocoolers), a novel technique requiring considerable development. TESLA Engineering based in Surrey won the contract to provide the focus coils. Engineers and physicists from Technology Department at RAL and the University of Oxford are working with TESLA to ensure that the design and its implementation will yield a magnet fit for purpose in MICE. The expertise gained by TESLA will be applicable in the construction of magnets for other applications. In addition, the UK is responsible for the provision of liquid hydrogen to each of the three absorber-modules. The hydrogen delivery system uses state-of-the-art hydride-bed technology and liquefaction is performed with cryocoolers. The development of the systems for MICE will be carried out in collaboration with industry to the benefit of the hydrogen economy.

The MICE programme is varied, encompassing the development of numerical methods and simulation techniques, the development of accelerator hardware (from conventional transfer lines to the development of novel superconducting magnets), the construction of a novel, pion-production target, the development of hydrogen-handling systems, the provision of RF power, and the construction of state of the art diagnostics. Further, the implementation of the large and complicated project has allowed members of the collaboration to develop project management and integration enginring skills.

MICE is an integral part of the Proton Accelerators for Science and Innovation initiative, putting the UK firmly at the heart of the community that seeks to develop the technology required to produce high intensity muon beams suitable for use in the Neutrino Factory and Muon Collider. MICE has created a UK community capable of delivering large and complex projects in an international environment.

Substantial contributions to the experiment in equipment, personnel, and intellectual input are being made by the international collaboration. To date, the international collaboration has provided the muon decay solenoid, beam-line instrumentation (scintillators and scintillating-fibre based beam-position monitors), three time-of-flight hodoscopes, two Cherenkov detectors, a lead-scintillator pre-shower detector, a prototype of the Electron Muon Ranger, the tracker readout and cryogenic systems, three high-power RF amplifiers, and the data-acquisition system. Over the period of the award, the international collaboration will complete the time-of-flight and calorimeter systems and provide the spectrometer solenoids, the liquid-hydrogen absorbers, and the RF-cavity/coupling-coil modules. The total value of these contributions, through hard to estimate, is in excess of £25M.

By making a success of the MICE project, the UK has gained substantial influence in the international Neutrino Factory community. The leverage opportunity for the future will be to forge appropriate partnerships with those laboratories or collaborations wishing to develop the Neutrino Factory and Muon Collider as options for the field. This is being taken forward through the EC FP7 Preparatory Phase Project TIARA in which funds have been secured to turn the infrastructure that supports the MICE experiment into the Ionization Cooling Test Facility (the ICTF).

Publications

10 25 50
 
Description This project is a research studentship and has focused on the development of diagnostics and simulations for the cooling channel required for a Muon particle accelerator (this is a candidate instrument for future fundamental particle physics experiments). The project has involved the student working in a large international collaboration. The RF input sources have been developed in the UK at Daresbury laboratory and the student participated in the demonstration of the required RF power level. The cavity has been developed by Berkeley laboratory (US) and the student visited FNAL where the cavity was on test to demonstrate the required performance and understand how it will interface to the diagnostic hardware. The diagnostic being developed in the course of this project is to determine the transit phase of the Muons through the RF accelerator structure and a scheme based on 'undersampling' has been shown to be feasible and has been successfully tested on data from the test undertaken at FNAL.
Exploitation Route Developments in HPRF systems and Accelerator Science have wide applications. Accelerators are important in security and healthcare as well as fundamental physics, whilst HPRF systems are vital to applications including Radar, communications and energy. Muon cooling systems make unusual demands on its HPRF system and the techniques developed to meet this can have impacts on these other wider application areas.
Sectors Aerospace, Defence and Marine,Digital/Communication/Information Technologies (including Software),Education,Electronics,Energy,Healthcare,Security and Diplomacy

URL http://www.mice.iit.edu
 
Description The results were used in the preparation of the International Muon Ionisation Cooling Experiment (MICE) at the Rutherford Appleton Laboratory. This experiment will show that it is possible to form a controlled and well defined beam of Muons for a future accelerator. The technology to develop such systems, in terms of specialised instrumentation, magnets, cryogenic systems and RF systems can be expected to have a beneficial impact on the UK economy in the future. RF systems impact on communication, sensing, energy sectors and the development of these capabilities can also be expect to have social outcomes, including through potential impact on accelerators in healthcare and security. A key aspect of this project is the education of the student engaged who is developing skills required by the significant UK industrial community engaged in electronics, free electron technology and accelerator science.
First Year Of Impact 2016
Sector Education
Impact Types Societal,Economic

 
Description RF Accelerator Material in L5 Instructional Class
Geographic Reach Multiple continents/international 
Policy Influence Type Influenced training of practitioners or researchers
Impact Students will have been informed of aspects of RF accelerator technology on completion of studies, informed by the research on the MICE project. This specifically relates to PGT courses. RF technology is regularly indicated as being a significant skills shortage in a international context (both for accelerator science and in a wider scope).
 
Description MICE Ionization-Cooling Demonstration
Amount £373,578 (GBP)
Funding ID ST/P001114/1 
Organisation Science and Technologies Facilities Council (STFC) 
Sector Academic/University
Country United Kingdom
Start 01/2017 
End 06/2020
 
Title MICE Raw Data 
Description Raw data obtained by the International Muon Ionisation Cooling Experiment (MICE) experiment 
Type Of Material Database/Collection of data 
Year Produced 2016 
Provided To Others? Yes  
Impact Papers on phase space control of muon beams 
URL https://figshare.com/articles/MICE_Raw_Data/3179644
 
Title MICE Recon Data 
Description Reconstructed data produced by the International Muon Ionisation Experiment 
Type Of Material Database/Collection of data 
Year Produced 2018 
Provided To Others? Yes  
Impact Papers on emittance control of beams of energetic muons by ionisation cooling 
URL https://figshare.com/articles/_/5955850
 
Title MICE Simulation Data 
Description Simulations of ionisation cooling associated with the MICE project 
Type Of Material Database/Collection of data 
Year Produced 2018 
Provided To Others? Yes  
Impact Data supporting papers of muon cooling and emittance control through interaction with low-Z absorbers 
URL https://figshare.com/articles/_/5972329
 
Description MICE 
Organisation Fermilab - Fermi National Accelerator Laboratory
Department FNAL - Other
Country United States 
Sector Private 
PI Contribution International Muon Ionisation Cooling Experiment
Collaborator Contribution The Strathclyde aspects of MICE are focussed on the development of RF systems. In this context there are several major interactions within the MICE collaboration which are focussed on here. There are moreover much wider collaborations for other aspects of the MICE project. FNAL, LBL, DoE, IIT Very large contribution in the buiding and testing of the prototype RF cavities for MICE, Univ Geneva. development of data acquisition system for MICE, INFN Milan, Development of fast particle detectors.
Impact Publication of several papers
Start Year 2012
 
Description MICE 
Organisation Illinois Institute of Technology
Country United States 
Sector Academic/University 
PI Contribution International Muon Ionisation Cooling Experiment
Collaborator Contribution The Strathclyde aspects of MICE are focussed on the development of RF systems. In this context there are several major interactions within the MICE collaboration which are focussed on here. There are moreover much wider collaborations for other aspects of the MICE project. FNAL, LBL, DoE, IIT Very large contribution in the buiding and testing of the prototype RF cavities for MICE, Univ Geneva. development of data acquisition system for MICE, INFN Milan, Development of fast particle detectors.
Impact Publication of several papers
Start Year 2012
 
Description MICE 
Organisation Lawrence Berkeley National Laboratory
Country United States 
Sector Public 
PI Contribution International Muon Ionisation Cooling Experiment
Collaborator Contribution The Strathclyde aspects of MICE are focussed on the development of RF systems. In this context there are several major interactions within the MICE collaboration which are focussed on here. There are moreover much wider collaborations for other aspects of the MICE project. FNAL, LBL, DoE, IIT Very large contribution in the buiding and testing of the prototype RF cavities for MICE, Univ Geneva. development of data acquisition system for MICE, INFN Milan, Development of fast particle detectors.
Impact Publication of several papers
Start Year 2012
 
Description MICE 
Organisation National Institute for Nuclear Physics
Country Italy 
Sector Academic/University 
PI Contribution International Muon Ionisation Cooling Experiment
Collaborator Contribution The Strathclyde aspects of MICE are focussed on the development of RF systems. In this context there are several major interactions within the MICE collaboration which are focussed on here. There are moreover much wider collaborations for other aspects of the MICE project. FNAL, LBL, DoE, IIT Very large contribution in the buiding and testing of the prototype RF cavities for MICE, Univ Geneva. development of data acquisition system for MICE, INFN Milan, Development of fast particle detectors.
Impact Publication of several papers
Start Year 2012
 
Description MICE 
Organisation U.S. Department of Energy
Country United States 
Sector Public 
PI Contribution International Muon Ionisation Cooling Experiment
Collaborator Contribution The Strathclyde aspects of MICE are focussed on the development of RF systems. In this context there are several major interactions within the MICE collaboration which are focussed on here. There are moreover much wider collaborations for other aspects of the MICE project. FNAL, LBL, DoE, IIT Very large contribution in the buiding and testing of the prototype RF cavities for MICE, Univ Geneva. development of data acquisition system for MICE, INFN Milan, Development of fast particle detectors.
Impact Publication of several papers
Start Year 2012
 
Description MICE 
Organisation University of Geneva
Department Physics Section
Country Switzerland 
Sector Academic/University 
PI Contribution International Muon Ionisation Cooling Experiment
Collaborator Contribution The Strathclyde aspects of MICE are focussed on the development of RF systems. In this context there are several major interactions within the MICE collaboration which are focussed on here. There are moreover much wider collaborations for other aspects of the MICE project. FNAL, LBL, DoE, IIT Very large contribution in the buiding and testing of the prototype RF cavities for MICE, Univ Geneva. development of data acquisition system for MICE, INFN Milan, Development of fast particle detectors.
Impact Publication of several papers
Start Year 2012
 
Description MICE-UK 
Organisation Brunel University London
Country United Kingdom 
Sector Academic/University 
PI Contribution Ronald, Strathclyde is the manager for the RF project on the collaboration. Strathclyde work with Imperial, Sheffield, Daresbury and RAL on the RF systems for the project. Strathclyde participated in the tests of the amplifier chain and the demonstration that they can be integrated in the MICE hall, and have participated in the tests of the cavities at Fermilab. Strathclyde are developing the detector to determine the RF phase during the particle transit of the cavities. The project also encompasses (through the international MICE collaboration) 10 US participating institutions, University of Geneva, four Italian Institutions, CERN, and Sofia with other institutions in Japan, China and the Netherlands.
Collaborator Contribution In terms of the RF project, Sheffield have interacted particularly with Strathclyde on the detectors for determining the RF phase experienced by the Muons crossing the accelerator gaps. Daresbury have led the development of the RF amplifiers, and are leading the LLRF system. Fermilab are testing the RF cavities developed by the Lawrence Berkeley lab. Close links with the Universities of MIlan and Geneva are important as the RF phase detection system must interface to the fast particle detectors and data capture systems developed by these laboratories.
Impact Two papers have been published to date
Start Year 2012
 
Description MICE-UK 
Organisation Daresbury Laboratory
Country United Kingdom 
Sector Private 
PI Contribution Ronald, Strathclyde is the manager for the RF project on the collaboration. Strathclyde work with Imperial, Sheffield, Daresbury and RAL on the RF systems for the project. Strathclyde participated in the tests of the amplifier chain and the demonstration that they can be integrated in the MICE hall, and have participated in the tests of the cavities at Fermilab. Strathclyde are developing the detector to determine the RF phase during the particle transit of the cavities. The project also encompasses (through the international MICE collaboration) 10 US participating institutions, University of Geneva, four Italian Institutions, CERN, and Sofia with other institutions in Japan, China and the Netherlands.
Collaborator Contribution In terms of the RF project, Sheffield have interacted particularly with Strathclyde on the detectors for determining the RF phase experienced by the Muons crossing the accelerator gaps. Daresbury have led the development of the RF amplifiers, and are leading the LLRF system. Fermilab are testing the RF cavities developed by the Lawrence Berkeley lab. Close links with the Universities of MIlan and Geneva are important as the RF phase detection system must interface to the fast particle detectors and data capture systems developed by these laboratories.
Impact Two papers have been published to date
Start Year 2012
 
Description MICE-UK 
Organisation Imperial College London
Country United Kingdom 
Sector Academic/University 
PI Contribution Ronald, Strathclyde is the manager for the RF project on the collaboration. Strathclyde work with Imperial, Sheffield, Daresbury and RAL on the RF systems for the project. Strathclyde participated in the tests of the amplifier chain and the demonstration that they can be integrated in the MICE hall, and have participated in the tests of the cavities at Fermilab. Strathclyde are developing the detector to determine the RF phase during the particle transit of the cavities. The project also encompasses (through the international MICE collaboration) 10 US participating institutions, University of Geneva, four Italian Institutions, CERN, and Sofia with other institutions in Japan, China and the Netherlands.
Collaborator Contribution In terms of the RF project, Sheffield have interacted particularly with Strathclyde on the detectors for determining the RF phase experienced by the Muons crossing the accelerator gaps. Daresbury have led the development of the RF amplifiers, and are leading the LLRF system. Fermilab are testing the RF cavities developed by the Lawrence Berkeley lab. Close links with the Universities of MIlan and Geneva are important as the RF phase detection system must interface to the fast particle detectors and data capture systems developed by these laboratories.
Impact Two papers have been published to date
Start Year 2012
 
Description MICE-UK 
Organisation Rutherford Appleton Laboratory
Country United Kingdom 
Sector Public 
PI Contribution Ronald, Strathclyde is the manager for the RF project on the collaboration. Strathclyde work with Imperial, Sheffield, Daresbury and RAL on the RF systems for the project. Strathclyde participated in the tests of the amplifier chain and the demonstration that they can be integrated in the MICE hall, and have participated in the tests of the cavities at Fermilab. Strathclyde are developing the detector to determine the RF phase during the particle transit of the cavities. The project also encompasses (through the international MICE collaboration) 10 US participating institutions, University of Geneva, four Italian Institutions, CERN, and Sofia with other institutions in Japan, China and the Netherlands.
Collaborator Contribution In terms of the RF project, Sheffield have interacted particularly with Strathclyde on the detectors for determining the RF phase experienced by the Muons crossing the accelerator gaps. Daresbury have led the development of the RF amplifiers, and are leading the LLRF system. Fermilab are testing the RF cavities developed by the Lawrence Berkeley lab. Close links with the Universities of MIlan and Geneva are important as the RF phase detection system must interface to the fast particle detectors and data capture systems developed by these laboratories.
Impact Two papers have been published to date
Start Year 2012
 
Description MICE-UK 
Organisation University of Glasgow
Country United Kingdom 
Sector Academic/University 
PI Contribution Ronald, Strathclyde is the manager for the RF project on the collaboration. Strathclyde work with Imperial, Sheffield, Daresbury and RAL on the RF systems for the project. Strathclyde participated in the tests of the amplifier chain and the demonstration that they can be integrated in the MICE hall, and have participated in the tests of the cavities at Fermilab. Strathclyde are developing the detector to determine the RF phase during the particle transit of the cavities. The project also encompasses (through the international MICE collaboration) 10 US participating institutions, University of Geneva, four Italian Institutions, CERN, and Sofia with other institutions in Japan, China and the Netherlands.
Collaborator Contribution In terms of the RF project, Sheffield have interacted particularly with Strathclyde on the detectors for determining the RF phase experienced by the Muons crossing the accelerator gaps. Daresbury have led the development of the RF amplifiers, and are leading the LLRF system. Fermilab are testing the RF cavities developed by the Lawrence Berkeley lab. Close links with the Universities of MIlan and Geneva are important as the RF phase detection system must interface to the fast particle detectors and data capture systems developed by these laboratories.
Impact Two papers have been published to date
Start Year 2012
 
Description MICE-UK 
Organisation University of Liverpool
Country United Kingdom 
Sector Academic/University 
PI Contribution Ronald, Strathclyde is the manager for the RF project on the collaboration. Strathclyde work with Imperial, Sheffield, Daresbury and RAL on the RF systems for the project. Strathclyde participated in the tests of the amplifier chain and the demonstration that they can be integrated in the MICE hall, and have participated in the tests of the cavities at Fermilab. Strathclyde are developing the detector to determine the RF phase during the particle transit of the cavities. The project also encompasses (through the international MICE collaboration) 10 US participating institutions, University of Geneva, four Italian Institutions, CERN, and Sofia with other institutions in Japan, China and the Netherlands.
Collaborator Contribution In terms of the RF project, Sheffield have interacted particularly with Strathclyde on the detectors for determining the RF phase experienced by the Muons crossing the accelerator gaps. Daresbury have led the development of the RF amplifiers, and are leading the LLRF system. Fermilab are testing the RF cavities developed by the Lawrence Berkeley lab. Close links with the Universities of MIlan and Geneva are important as the RF phase detection system must interface to the fast particle detectors and data capture systems developed by these laboratories.
Impact Two papers have been published to date
Start Year 2012
 
Description MICE-UK 
Organisation University of Oxford
Department Department of Physics
Country United Kingdom 
Sector Academic/University 
PI Contribution Ronald, Strathclyde is the manager for the RF project on the collaboration. Strathclyde work with Imperial, Sheffield, Daresbury and RAL on the RF systems for the project. Strathclyde participated in the tests of the amplifier chain and the demonstration that they can be integrated in the MICE hall, and have participated in the tests of the cavities at Fermilab. Strathclyde are developing the detector to determine the RF phase during the particle transit of the cavities. The project also encompasses (through the international MICE collaboration) 10 US participating institutions, University of Geneva, four Italian Institutions, CERN, and Sofia with other institutions in Japan, China and the Netherlands.
Collaborator Contribution In terms of the RF project, Sheffield have interacted particularly with Strathclyde on the detectors for determining the RF phase experienced by the Muons crossing the accelerator gaps. Daresbury have led the development of the RF amplifiers, and are leading the LLRF system. Fermilab are testing the RF cavities developed by the Lawrence Berkeley lab. Close links with the Universities of MIlan and Geneva are important as the RF phase detection system must interface to the fast particle detectors and data capture systems developed by these laboratories.
Impact Two papers have been published to date
Start Year 2012
 
Description MICE-UK 
Organisation University of Sheffield
Country United Kingdom 
Sector Academic/University 
PI Contribution Ronald, Strathclyde is the manager for the RF project on the collaboration. Strathclyde work with Imperial, Sheffield, Daresbury and RAL on the RF systems for the project. Strathclyde participated in the tests of the amplifier chain and the demonstration that they can be integrated in the MICE hall, and have participated in the tests of the cavities at Fermilab. Strathclyde are developing the detector to determine the RF phase during the particle transit of the cavities. The project also encompasses (through the international MICE collaboration) 10 US participating institutions, University of Geneva, four Italian Institutions, CERN, and Sofia with other institutions in Japan, China and the Netherlands.
Collaborator Contribution In terms of the RF project, Sheffield have interacted particularly with Strathclyde on the detectors for determining the RF phase experienced by the Muons crossing the accelerator gaps. Daresbury have led the development of the RF amplifiers, and are leading the LLRF system. Fermilab are testing the RF cavities developed by the Lawrence Berkeley lab. Close links with the Universities of MIlan and Geneva are important as the RF phase detection system must interface to the fast particle detectors and data capture systems developed by these laboratories.
Impact Two papers have been published to date
Start Year 2012
 
Description MICE-UK 
Organisation University of Warwick
Country United Kingdom 
Sector Academic/University 
PI Contribution Ronald, Strathclyde is the manager for the RF project on the collaboration. Strathclyde work with Imperial, Sheffield, Daresbury and RAL on the RF systems for the project. Strathclyde participated in the tests of the amplifier chain and the demonstration that they can be integrated in the MICE hall, and have participated in the tests of the cavities at Fermilab. Strathclyde are developing the detector to determine the RF phase during the particle transit of the cavities. The project also encompasses (through the international MICE collaboration) 10 US participating institutions, University of Geneva, four Italian Institutions, CERN, and Sofia with other institutions in Japan, China and the Netherlands.
Collaborator Contribution In terms of the RF project, Sheffield have interacted particularly with Strathclyde on the detectors for determining the RF phase experienced by the Muons crossing the accelerator gaps. Daresbury have led the development of the RF amplifiers, and are leading the LLRF system. Fermilab are testing the RF cavities developed by the Lawrence Berkeley lab. Close links with the Universities of MIlan and Geneva are important as the RF phase detection system must interface to the fast particle detectors and data capture systems developed by these laboratories.
Impact Two papers have been published to date
Start Year 2012
 
Description First Ever Ionization Cooling Demonstration in MICE 
Form Of Engagement Activity A talk or presentation
Part Of Official Scheme? No
Geographic Reach International
Primary Audience Professional Practitioners
Results and Impact Poster paper at Neutrino 2018 - XXVIII International Conference on Neutrino Physics and Astrophysics
Year(s) Of Engagement Activity 2018
URL https://zenodo.org/record/1300586
 
Description MICE Collaboration Meetings 
Form Of Engagement Activity A formal working group, expert panel or dialogue
Part Of Official Scheme? No
Geographic Reach International
Primary Audience Professional Practitioners
Results and Impact Typically participation in international MICE collaboration meetings (three per annum), locations spanning UK, US, Europe. In addition participation in several programme review meetings (typically two per annum) on the management of the research programme, plus engaging in focussed scientific and technical advisory review bodies.
Year(s) Of Engagement Activity 2012,2013,2014,2015,2016
URL http://www.mice.iit.edu
 
Description Recent results from MICE on multiple Coulomb scattering and energy loss 
Form Of Engagement Activity A talk or presentation
Part Of Official Scheme? No
Geographic Reach International
Primary Audience Professional Practitioners
Results and Impact Poster paper at XXVIII International Conference on Neutrino Physics and Astrophysics
Year(s) Of Engagement Activity 2018
URL https://www.mpi-hd.mpg.de/nu2018/speakers