Low energy positive muons beam Bangjiao Ye Science of Science University of Science and technology of China
Low energy positive muons beam
Cryogenic moderator Laser lonization method
Cryogenic moderator Laser Ionization method
Slow muon beam Slow muons muons which are (re-)accelerated from the muons which are almost at a rest. Beam energy is tunable,and its spread is very small. The range in the material is tunable down to sub um. Emittance is very small. Small sample can be used. polarized muons ideal as a microscopic magnetic probe to solid state physics(uSR technique) ● Depolarization of the muon spin due to local magnetic fields can be monitored through decay positrons which are emitted preferentially along the spin direction
Slow muon beam l Slow muons : muons which are (re-)accelerated from the muons which are almost at a rest. l Beam energy is tunable, and its spread is very small. a The range in the material is tunable down to sub mm. – Emittance is very small. aSmall sample can be used. lpolarized muons ideal as a microscopic magnetic probe to solid state physics (mSR technique) l Depolarization of the muon spin due to local magnetic fields can be monitored through decay positrons which are emitted preferentially along the spin direction
Study of Surface Interfaces ▣thin films ▣nanomaterials multi-layered compounds ▣small size samples ▣Atomic Physics. Surface Chemistry-Catalysis
Study of Surface & Interfaces pthin films pnanomaterials pmulti-layered compounds psmall size samples pAtomic Physics. pSurface Chemistry-Catalysis
mm 1 Cu Bulk 102 m 101 Thin films 02 nm 1 ◆ 1 7 o L 1 10 102 103 104 Energy keV
Thin films Bulk
Muon cooling methods 1keV range Methods capable of muon cooling below keV within the lifetime of 2.2us: Relatively efficient,problems with muonium 1keV Frictional cooling in gasses formation,loss LE muons in extraction from gas cell Uses layer of solid rare gas as a moderator for controlled slowing down emission process. Ideal are perfect insulators with wide band-gap 10eV Cold moderator method (epithermal muons) energy (11-22 eV) Good quality beam with small emittance BUT: Laser ionization of Only pulsed operation<30 Hz rep <leV muonium complex laser required (ultraslow muons)
Muon cooling methods < 1keV range Methods capable of muon cooling below keV within the lifetime of 2.2 ms: 1 keV Frictional cooling in gasses m + m - Relatively efficient , problems with muonium formation, loss LE muons in extraction from gas cell 10 eV Cold moderator method (epithermal muons) m + Uses layer of solid rare gas as a moderator for controlled slowing down emission process. Ideal are perfect insulators with wide band-gap energy (11-22 eV) <1 eV Laser ionization of muonium (ultraslow muons) m + Good quality beam with small emittance BUT: Only pulsed operation < 30 Hz rep & complex laser required
Two methods to generate slow muon beam Cryogenic moderator method Use a layer of solid rare gas as a moderator. Initial energy is 10-100eV,and its spread is around 10eV. Time structure is determined by initial beam. slow muon muon beam solid rare-gas film
Two methods to generate slow muon beam • Cryogenic moderator method – Use a layer of solid rare gas as a moderator. – Initial energy is 10-100eV, and its spread is around 10eV. – Time structure is determined by initial beam
● Laser resonant ionization method Obtain slow muons by ionizing thermal muoniums emitted from a hot tungsten film. 一 Initial energy is around 0.2eV,and its spread is less than 1eV. Time structure is determined by laser timing. Gives better time resolution for pulsed beam. Possible use for Mu anti-Mu conversion experiment as a sensitive detection method of anti-Mu and background suppression. muonium slow muon muon beam tungsten film laser light
• Laser resonant ionization method – Obtain slow muons by ionizing thermal muoniums emitted from a hot tungsten film. – Initial energy is around 0.2eV, and its spread is less than 1eV. – Time structure is determined by laser timing. g Gives better time resolution for pulsed beam. g Possible use for Mu anti-Mu conversion experiment as a sensitive detection method of anti-Mu and background suppression
Cryogenic moderator PSI slow muon beam line ISIS EC slow muon beam line oCryogenic moderator method Applied cryogenic moderator method to Efficiency close to 10-4 a pulsed muon source. Initial beam energy spread is ● Yielded about 1 u/sec (*2) about 10eV ●Pulsed source ● Yielded about 700 u/sec (1) ● DC source Time-of-flight showed time resolution was about 90nsec(FWHM),according to A timing counter needs to be ISIS beam pulse width. inserted in the transport line for uSR study Better energy resolution than PSI thanks to absence of a trigger counter. Successful operation since 1993 ●Currently defunct
Cryogenic moderator PSI slow muon beam line l Cryogenic moderator method n Efficiency close to 10-4 n Initial beam energy spread is about 10eV l Yielded about 700 m/sec (*1) l DC source n A timing counter needs to be inserted in the transport line for mSR study l Successful operation since 1993 ISIS EC slow muon beam line l Applied cryogenic moderator method to a pulsed muon source. l Yielded about 1 m/sec (*2) l Pulsed source n Time-of-flight showed time resolution was about 90nsec (FWHM), according to ISIS beam pulse width. n Better energy resolution than PSI thanks to absence of a trigger counter. l Currently defunct
PSI slow muon beam line Surface u beam E~4 Mev MCP1 ■D Mirror Spin Einzel lens Einzel lens (LN:cooled) Moderator Trigger Detector (C-foil) ☒ ☒ Einzel lens Low Energy u beam (LN:cooled) 0-30 kev Gate Valye Conical Helmholtz Coils lens Sample or MCP Sample Cryostat
PSI slow muon beam line