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Update from the LARIS lab Marica Sjödin Auto-ionizing state 1 2 3 Isolde workshop, November 2008.

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Presentation on theme: "Update from the LARIS lab Marica Sjödin Auto-ionizing state 1 2 3 Isolde workshop, November 2008."— Presentation transcript:

1 Update from the LARIS lab Marica Sjödin Auto-ionizing state 1 2 3 Isolde workshop, November 2008

2 Primary objectives:  Investigate new ionization schemes (free from ISOLDE scheduling)  Improve upon current schemes that rely on non-resonant ionization - search for auto-ionizing states  Prepare for RILIS transition Solid State Laser system - different wavelength range (532 nm and 355 nm pumped dye lasers) Secondary objectives:  Investigate RILIS selectivity improvements - HFS measurements (isomer selectivity) - Hot cavity optimization / material testing Tertiary objectives:  Questions related to fundamental atomic spectroscopy, e.g. accurate determination of atomic ionization potentials. The LARIS Laboratory - Introduction Funding: Knut and Alice Wallenberg Foundation CERN/KTH collaboration

3 2-step: (1 resonance) (2 resonance) 3-step: 2 resonance) (3 resonance)

4 LARIS is an offline development lab for RILIS ISOLDE Separate laser system Separate atomic scource (only stable isotopes) The LARIS Laboratory Measure relative efficiecies of ionization schemes Systematic study of auto-ionising states New ionisation schemes for currently unavailable elements Replace schemes that require CVL pumping @ 511 nm - Immediate tasks oror...

5 The LARIS Laboratory - overview Nd:YAG 3 Dye laser Nd:YAG 2 OPO 2 Nd:YAG 1 Wavelength Meter 2  generators With tracking system OPO 1 Auto-ionizing state IP 3 2 1 Atomic beam Oven / Laser ablation source TOF MS Detector Lecroy Waverunner oscilloscope Integrated ion signal Pulse, Delay generator PD

6 Continuum PowerLite 7010 + OPO Mirage + Continuum UVT Tuning range: 720 - 920 nm (fund.), 360 - 460 nm (2  ) 532 nm, 10 Hz 400 mJ The LARIS Laboratory - Lasers 80 mJ @750nm 10 mJ @ 425nm

7 Spectra Physics Quanta-Ray PRO 230-10 + MOPO HF + FDO-970 Tuning range: 450 - 690 nm (signal), 735 - 1680 nm (idler), 220 – 440 (2  ) 355 nm, 10 Hz 400mJ MOPO-HF The LARIS Laboratory - Lasers 70 mJ @500nm7.5 mJ @250nm

8 MOPO-HF The LARIS Laboratory - Lasers ”Easily” tuneable over a very wide -region (with some gaps) Handy when probing for autoionising states Spectra Physics Quanta-Ray PRO 230-10 + MOPO HF + FDO-970 Tuning range: 450 - 690 nm (signal), 735 - 1680 nm (idler), 220 – 345, 365 - 440 (2  ) Complicated (and expensive!) to set up Need good tables

9 The LARIS Laboratory - Lasers Quantel YAG Pump laser 20 Hz Pulse energy: 350 mJ (1064 nm) 160 mJ (532 nm) 60 mJ (355 nm) Pulse duration @1064 nm: 4.4 ns Quantel Brilliant (“Banana laser”) Nd:YAG with 2  and 3  units Lumonics HD-500 Dye laser Dye tuning ranges: 390 - 850 nm (fund.), >200 nm(2  )

10 The LARIS Laboratory Two complementary units: Laser ablation source With Time Of Flight MS Thermal atomic beam unit TOF MS will be added

11 The LARIS Laboratory - Time of flight mass spectrometer Ablation chamber To acquire higher resolution laser spectra for specific isotopes Measure isotope shifts for stable isotopes Measure HFS for different atomic transitions in various ionization schemes (Feasibility study for isomer separation ) Ablation chamber and gas transport of atoms into interaction region: Ulf Sassenberg - Summer 2007 TOF tube

12 To TOF tube 5 cm,  6 mm The LARIS Laboratory - Time of flight mass spectrometer Ablation laser Ablation unit New wave POLARIS 3 50mJ @ 532 nm Carrier gas Ar Pulsed nozzle Sample rod Ionisation lasers

13 The LARIS Laboratory - Time of flight mass spectrometer R = ~ 200

14 Wavemeter LM 007 powermeter Photodiode Signal from detector Wavelength measurement to computer If the wavelenght is ”good” then Get parameters from oscillator And from powermeter(s) LABView interface Select parameters to be recorded Set tolerance levels for  Start program The LARIS Laboratory - Data Acquisition system Oscilloscope (Lecroy Waverunner 104Xi) Define parameters P1P1 P2P2  P1P1 P2P2

15 The LARIS Laboratory - First test of RILIS ISOLDE relevant element - Mn Why Mn? A new ionisation scheme was urgently needed When the current Mn scheme was developed at RILIS the yield was found to be better when a weak transition was used in the second step – Suspect an accidental resonance CVL ? Autoionising state 3d 5 4s 2 6 S 5/2 3d 5 4s4p 6 P J 7/2 5/2 3/2 3d 7 4 P 5/2 One colour signal √ Two or three colour signal  285.2 nm 3d 5 4s5s 6 S 5/2 628.3 nm 510.6 nm 732.6 nm Interesting – what is that accidental resonance? What happens when we replace CVL with YAG? Full test of our entire system

16 Ti CVL ? Autoionising state 3d 5 4s 2 6 S 5/2 3d 5 4s4p 6 P J 7/2 5/2 3/2 3d 7 4 P 5/2 2-step: (1 resonance) √ Cu 2-step: (2 resonance) √ One colour signal √ Two or three colour signal  285.2 nm 3d 5 4s5s 6 S 5/2 628.3 nm732.6 nm The LARIS Laboratory We can trust our method for overlapping the beams But... We recently found that we were not using optimal delays between gas pulse, ablation laser and ionisation lasers And we found that our wavemeter can not be trusted in the UV region So we will try again

17 The LARIS Laboratory - Thermal atomic beam unit Plan of the first thermal atomic beam unit in LARIS built by Fabian Österdahl Ceramic oven Watercooled flange Channeltron detector close to the interaction region We are now in the process of making some modifications to begin using it for spectroscopy

18 Laser window Oven port The LARIS Laboratory - Thermal atomic beam unit Channeltron Ceramic oven replaced with Tantalum oven Same flange – Replace insulator and make full use of water cooling 20 cm extension to increase the distance to channeltron

19 The LARIS Laboratory - Testing Reflectivity of Molybdenum mirror at higher temperatures Heated mirror up to 1000 °C No change in reflectivity has been detected

20 Working Lasers Timing system Working Laser ablation TOF MS Laser Ions – Ti, Cu, Mn, Ca 1 and/or 2 coulour signals Data Aquisition: , Oscilloscope can function as 8 Boxcar modules, laser power measurement. FUTURE plans Reassemble oven unit Measurements from thermal ABU to complement laser ablation scource TOF for oven ABU Continue with Mn and other elements... The LARIS Laboratory - SUMMARY

21 FEDOSSEEV, Valentine (CERN) LINDROOS, Mats (CERN) LOSITO, Roberto (CERN) MARSH, Bruce (CERN) BERG, Lars-Erik (Royal Institute of Technology) LAUNILA, Olli (Royal Institute of Technology) PAUCHARD, Thomas (Royal Institute of Technology) RAFIEE, Mohammad (Royal Institute of Technology) SJÖDIN, Marica (Royal Institute of Technology) TRANSTRÖMER, Göran (Royal Institute of Technology) VANNESJÖ, Johanna (Royal Institute of Technology) ÖSTERDAHL, Fabian (Royal Institute of Technology) Funding: Knut and Alice Wallenberg Foundation SASSENBERG, Ulf (Stockholm University) POHJALAINEN, Ilkka (Helsinki University) The LARIS Laboratory - PEOPLE

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