Measurement of emittance in the Muon Ionization Cooling Experiment

Similar documents
Emittance Measurement in the Muon Ionization Cooling Experiment

Measurement of emittance with the MICE scintillating fibre trackers

PoS(EPS-HEP2015)522. The status of MICE Step IV

Ionization Cooling Demonstration

MICE: The Trackers and Magnets

MEASUREMENT OF PHASE SPACE DENSITY EVOLUTION IN MICE

PoS(NuFact2017)099. Measurement of Phase Space Density Evolution in MICE. François Drielsma. MICE Collaboration

Measurements of the Multiple Coulomb Scattering of Muons by MICE

Demonstrating 6D Cooling. Guggenheim Channel Simulations

Recent results from MICE on multiple Coulomb scattering and energy loss

RECENT RESULTS FROM MICE ON MULTIPLE COULOMB SCATTERING AND ENERGY LOSS

High Precision Track Reconstruction and First Emittance Measurements in the MICE Step IV Cooling Channel

The Reconstruction Software for the Muon Ionization Cooling Experiment Trackers

WEDGE ABSORBER DESIGN FOR THE MUON IONISATION COOLING EXPERIMENT

Results from HARP. Malcolm Ellis On behalf of the HARP collaboration DPF Meeting Riverside, August 2004

State Machine Operation of the MICE Cooling Channel

The HARP Experiment. G. Vidal-Sitjes (INFN-Ferrara) on behalf of the HARP Collaboration

Recent results from MICE on multiple Coulomb scattering and energy loss

Luminosity measurement and K-short production with first LHCb data. Sophie Redford University of Oxford for the LHCb collaboration

Full-Acceptance Detector Integration at MEIC

Measurement of the pion contamination in the MICE beam

Polyethylene Wedge Absorber in MICE

Non-collision Background Monitoring Using the Semi-Conductor Tracker of ATLAS at LHC

Tracking at the LHC. Pippa Wells, CERN

Linear Collider Collaboration Tech Notes. Design Studies of Positron Collection for the NLC

Accelerator Physics Final Exam pts.

arxiv:hep-ex/ v1 19 Jun 2004

MICE-NOTE-DET-388. Geant4 Simulation of the EMR Detector Response Study

Lawrence Berkeley National Laboratory Lawrence Berkeley National Laboratory

High Pressure, High Gradient RF Cavities for Muon Beam Cooling

Measurement of the associated production of direct photons and jets with the Atlas experiment at LHC. Michele Cascella

CERN Accelerator School. Intermediate Accelerator Physics Course Chios, Greece, September Low Emittance Rings

Polarized muon decay asymmetry measurement: status and challenges

Particle Identification Algorithms for the Medium Energy ( GeV) MINERνA Test Beam Experiment

6 Bunch Compressor and Transfer to Main Linac

Track reconstruction for the Mu3e experiment Alexandr Kozlinskiy (Mainz, KPH) for the Mu3e collaboration DPG Würzburg (.03.22, T85.

NA62: Ultra-Rare Kaon Decays

Muon reconstruction performance in ATLAS at Run-2

Early physics with the LHCb detector

The Reconstruction Software for the MICE Scintillating Fibre Trackers

arxiv:hep-ex/ v1 15 Oct 2004

EP228 Particle Physics

HARP (Hadron Production) Experiment at CERN

Tracking properties of the ATLAS Transition Radiation Tracker (TRT)

arxiv: v4 [physics.acc-ph] 12 Jun 2018

Future prospects for the measurement of direct photons at the LHC

V0 cross-section measurement at LHCb. RIVET analysis module for Z boson decay to di-electron

Tools of Particle Physics I Accelerators

The Compact Muon Solenoid Experiment. Conference Report. Mailing address: CMS CERN, CH-1211 GENEVA 23, Switzerland. Commissioning of the CMS Detector

Susanna Costanza. (Università degli Studi di Pavia & INFN Pavia) on behalf of the ALICE Collaboration

The Compact Muon Solenoid Experiment. Conference Report. Mailing address: CMS CERN, CH-1211 GENEVA 23, Switzerland. First Physics at CMS

Measurements of the total and inelastic pp cross section with the ATLAS detector at 8 and 13 TeV

A search for heavy and long-lived staus in the LHCb detector at s = 7 and 8 TeV

Latest Results from the OPERA Experiment (and new Charge Reconstruction)

Baby MIND: A magnetised spectrometer for the WAGASCI experiment

Transverse dynamics Selected topics. Erik Adli, University of Oslo, August 2016, v2.21

Absolute D Hadronic Branching Fractions at CLEO-c

arxiv: v1 [physics.ins-det] 1 Sep 2009

MiniBooNE Progress and Little Muon Counter Overview

The Mu2e Transport Solenoid

Low Emittance Machines

HARP a hadron production experiment. Emilio Radicioni, INFN for the HARP collaboration

MuSIC- RCNP at Osaka University

Analysis of muon and electron neutrino charged current interactions in the T2K near detectors

Study of Baryon Form factor and Collins effect at BESIII

General Considerations

Low Emittance Machines

LHCb: From the detector to the first physics results

Physics with Tagged Forward Protons using the STAR Detector at RHIC. The Relativistic Heavy Ion Collider The pp2pp Experiment STAR 2009

Compressor Lattice Design for SPL Beam

Kaon Identification at NA62. Institute of Physics Particle, Astroparticle, and Nuclear Physics groups Conference 2015

Simulation of RF Cavity Dark Current in Presence of Helical Magnetic Field

New Hadroproduction results from the HARP/PS214 experiment at CERN PS

Nuclear and Particle Physics 4b Physics of the Quark Gluon Plasma

The LHCb detector. Eddy Jans (Nikhef) on behalf of the LHCb collaboration

Higgs Factory Magnet Protection and Machine-Detector Interface

Muon Front-End without Cooling

Lecture LHC How to measure cross sections...

2 ATLAS operations and data taking

Muon commissioning and Exclusive B production at CMS with the first LHC data

COMET muon conversion experiment in J-PARC

Neutrinos Induced Pion Production in MINERvA

MC6 - MC7 simulation for Time-of-Flight LAPPD detectors

PoS(HCP2009)042. Status of the ALICE Experiment. Werner Riegler. For the ALICE Collaboration. CERN

Gaseous Hydrogen in Muon Accelerators

Exclusive Central π+π- Production in Proton Antiproton Collisions at the CDF

PoS(ICHEP2016)293. The LArIAT experiment and the charged pion total interaction cross section results on liquid argon. Animesh Chatterjee

Introduction to polarimetry at HERA

Neutrino Detectors for future facilities - III

Simulation Results for CLAS12 From gemc

PoS(TIPP2014)093. Performance study of the TOP counter with the 2 GeV/c positron beam at LEPS. K. Matsuoka, For the Belle II PID group

A Search for Excess Dimuon Production in the Radial Region (1.6 < r < 10) cm at the DØ Experiment

Single Spin Asymmetries on proton at COMPASS

Measurement of the Inclusive Isolated Prompt Photon Cross Section at CDF

Max. Central Momentum 11 GeV/c 9 GeV/c Min. Scattering Angle 5.5 deg 10 deg Momentum Resolution.15% -.2% Solid Angle 2.1 msr 4.

Oliver Stelzer-Chilton University of Oxford High Energy Physics Seminar Michigan State University

COMBINER RING LATTICE

1 Introduction. KOPIO charged-particle vetos. K - RARE Meeting (Frascati) May Purpose of CPV: veto Kl

Recent CMS results on heavy quarks and hadrons. Alice Bean Univ. of Kansas for the CMS Collaboration

Novel Features of Computational EM and Particle-in-Cell Simulations. Shahid Ahmed. Illinois Institute of Technology

Transcription:

Measurement of emittance in the Muon Ionization Cooling Experiment François Drielsma on behalf of the MICE collaboration University of Geneva August 26, 216 François Drielsma (UniGe) Emittance in MICE August 26, 216 1 / 24

The Muon Ionization Cooling Experiment (MICE) The need for MICE Ionization cooling is the only viable technique to reduce the emittance of a muon beam within their lifetime ( 2.2 µs) Cooled muons are essential to achieve the luminosity required by future muon facilities such as a Neutrino Factory or a Muon Collider MICE physics program Demonstrate the feasibility of ionization cooling Study and validate the cooling equation Energy loss and scattering of muons (material physics) François Drielsma (UniGe) Emittance in MICE August 26, 216 2 / 24

Principle of ionization cooling Muon cooling can be characterised by the rate of change of the normalised emittance (phase space occupied by the beam), approximated by dε N ds ε N β 2 E µ de µ ds + β (.14) 2 2β 3 ; (1) E µ m µ X Energy loss, de µ /ds, reduces both p L and p T Scattering heats the beam as 1/X, must maximize X RF cavities restore p L only The absorber must be placed at a focus for best cooling performance François Drielsma (UniGe) Emittance in MICE August 26, 216 3 / 24

MICE beam line François Drielsma (UniGe) Emittance in MICE August 26, 216 4 / 24

MICE beam line François Drielsma (UniGe) Emittance in MICE August 26, 216 5 / 24

Experimental apparatus at present (Step IV) All the detectors are in and working Three time-of-flight detector stations Two Cherenkov counters and a downstream calorimetry module Two scintillating-fibre trackers Part of the cooling channel (no RF yet) Two Spectrometer Solenoids (SS), each composed of 5 coils An Absorber Focus Coil (AFC) module, made of 2 coils MICE Muon Beam (MMB) Time-of-flight hodoscope 1 (ToF ) Variable thickness high-z diffuser Upstream spectrometer module Absorber/focus-coil module Downstream spectrometer module 7th February 215 Electron Muon Ranger (EMR) MICE Cherenkov counters (CKOV) ToF 1 Liquid-hydrogen absorber Scintillating-fibre trackers Pre-shower (KL) ToF 2 François Drielsma (UniGe) Emittance in MICE August 26, 216 6 / 24

Single-particle experiment MICE is a single-particle experiment, i.e. There is no beam as such going down the beam line, particles go down the beam line one by one (f 2 khz for 1 ms every second) At each DAQ cycle, a single particle track is recorded Particle tracks are bunched at the analysis level to create an ensemble of which to compute the emittance First direct measurement of emittance of muon beams by a scintillating fibre-tracker François Drielsma (UniGe) Emittance in MICE August 26, 216 7 / 24

Definition The emittance represents the volume occupied by the beam in phase-space. In 2D it is a simple ellipse. The 4D normalised RMS transverse emittance is defined as ɛ n = 1 m µ 4 det Σ (2) with m µ the muon mass and Σ the covariance matrix, i.e. σ xx σ xpx σ xy σ xpy Σ = σ pxx σ pxpx σ pxy σ pxpy σ yx σ ypx σ yy σ ypy (3) σ pyx σ pypx σ pyy σ pypy with σ αβ = αβ α β the covariance of α and β. François Drielsma (UniGe) Emittance in MICE August 26, 216 8 / 24

MICE Scintillating-Fibre trackers Two SciFi trackers (US and DS), 5 stations per tracker, 3 planes per station, 214 fibres per plane Measured tracker resolution (cosmics): σx, σy = 467 ± 2 µm Franc ois Drielsma (UniGe) Emittance in MICE August 26, 216 9 / 24

Tracker momentum reconstruction In a uniform solenoid magnetic field, a particle follows a helical path x = ρ cos (qbt/m) y = ρ sin (qbt/m) ρ = p T /qb (4) z = p L t/m Each tracker samples the helix in 5 points (x i, y i ) A circle fit in the (x, y) yields the radius ρ and hence p T The gradient of the arc-length, ds/dz, yields p L Resolutions from MC: σ pl 1.3 MeV/c, σ pt 4 MeV/c y x 2πp L /qb ρ x z François Drielsma (UniGe) Emittance in MICE August 26, 216 1 / 24

Run 7469 In October 215, the upstream spectrometer was powered for the first time at its designed current. Run 7469 was taken that day: 2 MeV/c positive muon input beam 7 minutes of data taking 1976 good muon tracks acquired This run was used to characterise the MICE muon beam and validate the tracker reconstruction. Results follow. François Drielsma (UniGe) Emittance in MICE August 26, 216 11 / 24

Event selection Selection criteria applied to clean up the beam Reject time-of-flights below threshold (e + ) Keep only particles that hit every TOF and tracker stations Remove particles that scraped the apparatus (magnet bore, diffuser) Time of flight (ns) 34 32 3 28 26 MICE Preliminary ISIS Cycle 215/2 24 1 12 14 16 18 2 22 24 26 28 3 P at Tracker (MeV/c) 12 Figure: time of flight 1 8 6 4 2 between the first and second TOF stations as a function of the reconstructed total momentum tracker A single curve signifies a single particle species: muons. François Drielsma (UniGe) Emittance in MICE August 26, 216 12 / 24

Position at the tracker reference plane The reference plane corresponds to the tracker station closest to the absorber The position distribution is the result of as many helical fits as particles The fiducial surface of each tracker plane is 3 mm in diameter y (mm) 15 MICE Preliminary ISIS Cycle 215/2 1 5 5 1 15 15 1 5 5 1 15 x (mm) 4 35 3 25 2 15 1 5 Visual representation of one of the covariance matrix elements, σ 2 xy François Drielsma (UniGe) Emittance in MICE August 26, 216 13 / 24

2D beam ellipses Another two plots of the elements σ 2 xp x and σ 2 yp y of the covariance matrix Similar distribution in the two 2D subspaces In an uncoupled phase space, these would represent the horizontal and vertical 2D emittance of the beam, respectively Px (MeV/c) 1 MICE Preliminary 8 6 4 2 2 4 6 8 ISIS Cycle 215/2 25 2 15 1 5 Py (MeV/c) 1 MICE Preliminary 8 6 4 2 2 4 6 8 ISIS Cycle 215/2 22 2 18 16 14 12 1 8 6 4 2 1 15 1 5 5 1 15 x (mm) 1 15 1 5 5 1 15 y (mm) François Drielsma (UniGe) Emittance in MICE August 26, 216 14 / 24

Beam dispersion The second bending magnet (D2) has a large acceptance Large momentum spread and dispersion in the beam Mean position of the beam proportional to momentum/bending radius Need to bin the sample in p z to remove chromatic effects Pz (MeV/c) 3 MICE Preliminary 28 26 24 22 2 ISIS Cycle 215/2 4 35 3 25 2 Radius of beam centre (mm) 65 MICE Preliminary ISIS Cycle 215/2 6 55 5 45 18 15 4 16 14 12 1 15 1 5 5 1 15 x (mm) 1 5 35 3 25 19 2 21 22 23 24 25 <Pz> (MeV/c) François Drielsma (UniGe) Emittance in MICE August 26, 216 15 / 24

Comparaison with Monte Carlo End-to-end Monte Carlo Pion production, target Transport with G4BL Custom MICE Analysis User Software MC Good agreement Accurately reproduces the tracker beam profiles (xp x, yp y ) Tool for systematic analysis Provides understanding of the beam dispersion Px (MeV/c) Py (MeV/c) 1 MICE Preliminary ISIS Cycle 215/2 8 6 4 2 2 4 6 8 1 15 1 5 5 1 15 x (mm) 1 MICE Preliminary ISIS Cycle 215/2 8 6 4 2 2 4 6 8 1 15 1 5 5 1 15 y (mm) 25 2 15 1 5 22 2 18 16 14 12 1 8 6 4 2 Px (MeV/c) Py (MeV/c) 1 MICE Preliminary Simulation 8 6 4 2 2 4 6 8 1 15 1 5 5 1 15 x (mm) 1 MICE Preliminary Simulation 8 6 4 2 2 4 6 8 1 15 1 5 5 1 15 y (mm) 3 25 2 15 1 5 25 2 15 1 5 François Drielsma (UniGe) Emittance in MICE August 26, 216 16 / 24

ISIS Cycle 215/2 ISIS Cycle 215/2 ISIS Cycle 215/2 ISIS Cycle 215/2 ISIS Cycle 215/2 ISIS Cycle 215/2 Poincaré sections of the covariance matrix in data x p x y p y σ 2 xx Px (MeV/c) 1 MICE Preliminary 8 6 4 2 2 4 6 8 y (mm) 25 1 2 5 15 1 5 5 1 15 MICE Preliminary 4 35 3 25 2 15 1 5 Py (MeV/c) 1 MICE Preliminary 8 6 4 2 2 4 6 8 25 2 15 1 5 x 1 15 1 5 5 1 15 x (mm) 15 15 1 5 5 1 15 x (mm) 1 15 1 5 5 1 15 x (mm) Px (MeV/c) 1 MICE Preliminary 8 6 22 2 18 Py (MeV/c) 1 MICE Preliminary 8 6 22 2 18 4 16 4 16 σ 2 p xp x 2 2 14 12 1 8 2 2 14 12 1 8 px 4 6 4 6 6 4 6 4 8 2 8 2 1 15 1 5 5 1 15 y (mm) 1 15 1 5 5 1 15 Px (MeV/c) Figure: Visual representation of the off-diagonal elements of the covariance matrix used to compute the emittance σ 2 yy Py (MeV/c) 1 MICE Preliminary 8 6 4 2 2 4 22 2 18 16 14 12 1 8 6 y 6 4 8 2 1 15 1 5 5 1 15 y (mm) François Drielsma (UniGe) Emittance in MICE August 26, 216 17 / 24

First direct measurement of emittance with MICE trackers Transverse normalised emittance (mm) 4.2 MICE Preliminary ISIS Cycle 215/2 4.1 4 3.9 3.8 3.7 3.6 19 2 21 22 23 24 25 <Pz> (MeV/c) François Drielsma (UniGe) Emittance in MICE August 26, 216 18 / 24

Latest MICE field-on data taking In July 216, great progress was made with the cooling channel operation Both spectrometers ECE coil triples were powered at 14 A, which corresponds to 2 T in each tracker The focus coil was powered at 5 A together with the spectrometers A 3 mm-14 MeV/c input beam was used, empty absorber module First look at muons that made it through the entire MICE channel First focus coil transfer matrix measurements François Drielsma (UniGe) Emittance in MICE August 26, 216 19 / 24

Beam profiles up and downstream the focus coil In two hours of data taking (run 8155 on July 27th 216) Upwards of 8 muon and pion tracks were recorded going through the entire MICE step IV magnet channel Both trackers were successful in the reconstruction of helical tracks at half the nominal spectrometer field TKD TKU François Drielsma (UniGe) Emittance in MICE August 26, 216 2 / 24

Cooling in MICE Step IV The MICE collaboration intends to measure emittance change for 3 1 mm tunable emittance (tuned with the diffuser) 14, 2 and 24 MeV/c mean momentum Lithium hydride absorber (LiH) and liquid hydrogen (LH2) Two types of lattices: solenoid and flip mode A first cooling measurement is soon to be made in MICE Step IV Whole cooling channel will be powered in September, empty absorber The lithium hydride absorber will go in before the end of 216 The liquid hydrogen absorber will go in this winter François Drielsma (UniGe) Emittance in MICE August 26, 216 21 / 24

Simulated emittance change 2 MeV/c sol. 2 MeV/c flip François Drielsma (UniGe) Emittance in MICE August 26, 216 22 / 24

Alternative: Kernel Density Estimation method A Kernel Density Estimator (KDE) is a nonparametric PDF defined as f( r) = 1 h d N N ( ) r ri K h i=1 (5) with h an arbitrary bandwidth, K the kernel, a normalised dimension d Normal distribution. This allows to compute contours and see changes in the phase space density François Drielsma (UniGe) Emittance in MICE August 26, 216 23 / 24

Conclusions The first direct measurement of emittance with the MICE trackers The trackers and PID detectors are fully operational The emittance was measured and chromatic effects were understood A technique paper is in preparation First emittance change measurement to come in the near future MICE will observe transverse muon beam emittance reduction The first set of LiH data will be taken in 216 More to come! Transverse normalised emittance (mm) 4.2 MICE Preliminary ISIS Cycle 215/2 4.1 4 3.9 3.8 3.7 3.6 19 2 21 22 23 24 25 <Pz> (MeV/c) François Drielsma (UniGe) Emittance in MICE August 26, 216 24 / 24

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback