Post on 24-Feb-2016
description
Photodetachment Photodetachment spectroscopy from cooled spectroscopy from cooled
negative ionsnegative ions
James WellsJames Wells
Summer research in the AMO lab*June – August 2005
* Support from Davidson College and the American Chemical Society
PhotodetachmentPhotodetachment
--
- -
-+
- -
- -
+ -
• X- + photon → X + e-
• Equivalent to latter half of an electron-atom collision.
Effects of ions’ random motionEffects of ions’ random motion
Photon frequency is Doppler Photon frequency is Doppler broadenedbroadened Causes uncertainty Causes uncertainty ΔΔE in any energy-E in any energy-
dependent measurementdependent measurement Typical experimental goal: measure Typical experimental goal: measure
probability of detachment as f(Eprobability of detachment as f(Ephotonphoton)) ΔΔE blurs experimental results: fewer E blurs experimental results: fewer
details, less contrast/structure.details, less contrast/structure.
Evaporative coolingEvaporative cooling
Ions trapped in an ion trap: electrostatic Ions trapped in an ion trap: electrostatic potential well.potential well.
Cooling appletCooling applet
Ion trap apparatusIon trap apparatus
Ring dye laserRing dye laser
Laser LabVIEW control codeLaser LabVIEW control code
(Screen shot)
Negative Ion FormationNegative Ion Formation
• Short-range attractive potential (~ 2 eV deep and a few Å wide)
• Electron correlation effects – partly responsible for covalent bonds
- +--
- -
--
- -
-+
Energy Levels (Oxygen)Energy Levels (Oxygen)
Photodetachment with B-FieldsPhotodetachment with B-Fields• departing electron executes cyclotron motion in field
• motion in plane perpendicular to B is quantized to cyclotron levels
• cyclotron states separated by ω = eB/me
• motion along axis of field is continuous, non-quantized
• for typical B = 1.0 Tesla, ω ≈ 30 GHz, period = 36 ps
• quantized Landau levels add structure to detachment cross section
Trap electronicsTrap electronics
Detachment cross section in B Detachment cross section in B fieldfield