The Time-resolved atomic, Molecular and Optical Science (TMO) instrument

TMO - Time-resolved AMO

The Time-resolved atomic, Molecular and Optical Science (TMO) instrument (NEH 1.1), one of the three new LCLS-II instruments with a energy range from 0.25 to 2 keV, will support a wide range of science including gas phase photochemistry, attosecond electron dynamics, and the study of nanoscale systems. TMO will support an array of experimental techniques and features two X-ray focus positions. The NEH beamline 1.1  science end station, will be configured to take full advantage of both the high per pulse energy from the copper accelerator (120 Hz) as well as high average intensity and high repetition rate (1 MHz) from the superconducting accelerator.  

Endstation Descriptions

The initial TMO focus spot or interaction point, IP1, is optimized for performing high energy, high resolution, time-but also angular-resolved photoelectron spectroscopic measurements. This interaction point features an array of standardizied, modular endstations. Depending on the photon energy, IP1 X-ray photon fluence can reach the high 1019 photons/cm2 range with superconducting Linac, and high 1020 photons/cm2 range with copper accelerator at 120 Hz.

The second TMO focus spot (IP2) features the new Dynamic REAction Microscope (DREAM) endstation which is a reaction microscope (or COLTRIMS type) spectrometer as a standard configuration. A second set of focusing mirrors defocus the IP1 spot to produce sub-mircon x-ray focal spots. The reaction microscope techniques is well suited for accumulating data on the event-by-event basis at the rep rates in excess of 100 kHz fully utilizing the LCLS-II capabilities. Photon fluence in IP2 will reach beyond 1021 photons/cm2 with superconducting Linac X-rays, while with copper accelerator it will be over 1022 photons/cm2 at 120 Hz.

Pump-probe timing resolution of X-ray with optical laser pulses can be expected to exceed 10 fs for both endstations.

Specifications

Parameter 

Value 

Undulator Source

SXU

Photon Energy Range  

250-2000 eV

Focused Beam Diameter (FWHM)

< 1.5 μm (IP1) & < 300 nm (IP2)

X-ray Bandwidth 

3 × 10−3 

1 × 10−4 (seeded) 

Beamline Transmission 

~ 80% (IP1) & ~ 60% (IP2)

Repetition Rate

up to 929 kHz

X-ray Power Limit

200 W

Optical Laser

200 nm to 17 μm with varying power, repetition rate, and pulse duration 

Primary X-ray Techniques

  • Electron/Ion coincidence measurements in a reaction microscope (or COLTRIMS) type spectrometer

  • High-Energy Electron Spectroscopy 

  • X-ray Pump / X-ray Probe, Optical pump / X-ray Probe

Advisory Panel

  • Christoph Bostedt - PSI, ETH Zurich
  • Reinhard Dörner - Frankfurt
  • Gilles Doumy – Argonne
  • Oliver Gessner - LBNL - CSD
  • Markus Guehr - U. Potsdam
  • Daniel Rolles - KSU
  • Thorsten Weber - LBNL - CSD
  • Nora Berrah - U. Conn
  • Adrian Cavalieri - MPSD, CFEL, U. Hamburg
  • Jon Marangos - ICL
  • Artem Rudenko - KSU
  • Richard Squibb - GU

TMO INSTRUMENT TEAM

James Cryan

TMO Instrument Lead Scientist   
(650) 926-3290   
jcryan@slac.stanford.edu

Justin James

Beamline Engineer   
(650) 926-3842   
jhjames@slac.stanford.edu

Ming-Fu Lin

TMO Scientist   
(650) 926-2586   
mfucb@slac.stanford.edu

Razib Obaid

TMO Scientist   
robaid@slac.stanford.edu

Thomas Wolf

TMO Scientist   
(650) 926-2533   
thomas.wolf@slac.stanford.edu

Taran Driver

TMO Scientist   
tdd14@slac.stanford.edu

Xiang Li

TMO Scientist   
xiangli@slac.stanford.edu

Mike Glownia

Laser Scientist   
jglownia@slac.stanford.edu

Ruaridh Forbes

Laser Scientist   
ruforbes@slac.stanford.edu

Mat Britton

Laser Scientist   
matb@slac.stanford.edu

Jeff Aldrich

Area Manager 
jaldrich@SLAC.Stanford.EDU