1 / 19

AMO Instrument Planning

AMO Instrument Planning. Scientific Goals Experimental capabilities End-station layout Outstanding issues Schedule & status . AMO Scientific Goals.

caugusta
Télécharger la présentation

AMO Instrument Planning

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. AMO Instrument Planning Scientific Goals Experimental capabilities End-station layout Outstanding issues Schedule & status

  2. AMO Scientific Goals • Capitalize on unique properties of the LCLS pulses to study interaction with simplest forms of matter – atoms, molecules & clusters, matter unencumbered with low-energy long-range collective phenomena • 826-2000 eV on soft x-ray branch – inner shell phenomena • Brightest x-ray source – multi-photon processes, high field studies • Short pulse ~200fs – time-resolved studies, time-evolving states

  3. AMO Experimental Capabilities • High Field Physics end-station to study photo-ionization of atoms, molecules, clusters: • Optics to focus beam to ~1mm2– power density • Pulsed gas jet – easier to manipulate sample with pulsed laser if necessary • Electron spectrometers (qty 5) – measure electron KE, dipole and non-dipole asymmetries • Ion spectrometers (qty 3) – charge states, momenta • X-ray fluorescence spectrometers (qty2) – distinct de-excitation channels,charging problems At least initially LCLS will have • Chaotic pulses • Poor synchronization …so also need shot-by-shot diagnostics

  4. AMO Pulse Diagnostics • AMO targets usually transparent – can measure pulse following experiment • What do we want to know ? • Photon energy, bandwidth – 0.2% from LCLS? • Pulse energy – 100% variation • Beam position & focal properties – to tune the refocus optics • Temporal relation to laser pump/probe – timing jitter, pulse duration

  5. AMO end-station – refocus optics • Need adaptive optics to change spot size (control power), move focus ~1m between end-station and diagnostics • Ideally two sets of optics – for ~1μm focus and <100nm focus

  6. AMO end-station – Field Strengths • LCLS Pulse: • 1.1×1013 ph @ 825 eV • 5 B4C mirrors with ~92% reflectivity = 7.2×1012 ph in 137fs (rms) pulse • Intensity will depend on focus size in end-station

  7. AMO experiments – High Field Multiphoton ionization Tunneling ionization Above-threshold-ionization (ATI) Keldysh parameter:

  8. AMO end-station – Sample source • Pulsed supersonic skimmed jet to match LCLS pulse • to reduce background signal need chamber pressure in low 10-10Torr range • Easier to produce large clusters (>104 atoms) from a pulsed source • Pulsed laser to desorb material from solid target and entrain in rare gas beam for cooling • Retain option of using CW jet, particularly for initial experiments

  9. AMO end-station – Ion Spectrometers • Very first experiment – charge state distribution from atomic sample • Integrating TOF spectrometer initially • Velocity map imaging – no m/q resolution but obtain momentum images • ColTRIMS type detection with time and position sensitive detector – difficult if there is too much signal (4-10 events per shot)

  10. AMO end-station – Electron Spectrometers • angle-resolved PES examines initial interaction - photoionization • time-of-flight energy dispersion ideally suited to LCLS • Multi-photon processes will be apparent in kinetic energy and angular distribution – many unknown processes

  11. AMO end-station – Fluorescence Spectrometers • X-ray emission from highly excited/ionized sample interrogates different electronic states/de-excitation channels • In dense samples, intense LCLS pulse will create numerous electrons/ion • resulting charge density will smear out charged particle momenta – reducing electron and ion spectroscopies’ utility

  12. AMO end-station – Laser systems • synchronized laser Ti:Sapphire laser & harmonics • For state preparation, temporal diagnostics, instrument commissioning, etc.

  13. AMO Planning – need for diagnostics • Large pulse-to-pulse variations • Power – bolometer • Peak power – magnetic bottle electron spectrometer • Pulse length/arrival time – cross-correlation in magnetic bottle • Smaller variations, but diagnostics useful for • Photon energy/bandwidth – magnetic bottle • Beam position & focal properties – imaging screens or quadrant BPMs

  14. AMO Diagnostics – magnetic bottle • High (2π) collection efficiency using asymmetric magnetic field to guide electrons into TOF –requires extensive modeling for high energy electrons • i.e. cross correlation of 12ps frequency doubled Nd:YLF laser pulse with 35.5eV FLASH pulse in photoionization of He M. Meyer et al, PRA, 74, 011401(R) 2006.

  15. AMO Planning – high field physics

  16. AMO Planning – imaging experiment • Desire within AMO community to use intense LCLS pulse to “image” size-selected clusters and time-evolving states • Considered diffraction of ionic (size-selected) clusters – i.e. what does a C6 cluster look like? • , or Mie scattering of larger clusters, both equilibrium states and temporally evolving states driven by external laser • Neither seems particularly well suited, but trying to describe a workable experiment

  17. AMO Planning – hutch layout • Room for three experiments in the first two hutches • Space to install monochromator for future needs

  18. AMO Planning – schedule highlights • Design process – through Oct 07 • Begin acquisitions – June 07 • Components arrive – March 08 • Install end-station – May 08 • First light – August 08 • Initial experiments – August 08 • Full capability end-station completed– January 09

  19. AMO Planning - Status • Experimental requirements defined – completing Physics Requirement Document • System Concept Review imminent • Experimental apparatus ready for beneficial occupancy • Experimental capabilities ready for first light • Completed experimental apparatus in January 2009

More Related