A strontium detective story James Millen Strontium detective – Group meeting 19/10/09 Ions‽

Slides:

Advertisements

Similar presentations

Photoexcitation and Ionization of Cold Helium Atoms R. Jung 1,2 S. Gerlach 1,2 G. von Oppen 1 U. Eichmann 1,2 1 Technical University of Berlin 2 Max-Born-Institute.

Advertisements

Optical clocks, present and future fundamental physics tests

First Year Seminar: Strontium Project

Rydberg & plasma physics using

Matt Jones Precision Tests of Fundamental Physics using Strontium Clocks.

P. Cheinet, B. Pelle, R. Faoro, A. Zuliani and P. Pillet Laboratoire Aimé Cotton, Orsay (France) Cold Rydberg atoms in Laboratoire Aimé Cotton 04/12/2013.

Making cold molecules from cold atoms

Probing the Rydberg spectrum of strontium – group meeting Probing the Rydberg spectrum of strontium James Millen.

Graham Lochead 07/09/09 Pulsed laser spectroscopy in strontium.

Rydberg physics with cold strontium James Millen Durham University – Atomic & Molecular Physics group.

Graham Lochead YAO 2009 Towards a strontium pyramid MOT Graham Lochead Durham University

MQDT analysis James Millen. Introduction MQDT analysis – Group meeting 13/09/10 In our experiment we measure the population of Rydberg states using autoionization.

A Magneto-Optical Trap for Strontium James Millen A Magneto-Optical Trap for Strontium – Group meeting 29/09/08.

Danielle Boddy Durham University – Atomic & Molecular Physics group Red MOT is on its way to save the day!

Rydberg excitation laser locking for spatial distribution measurement Graham Lochead 24/01/11.

The story unfolds… James Millen The story unfolds… – Group meeting 12/04/10.

Dipole-dipole interactions in Rydberg states. Outline Strontium experiment overview Routes to blockade Dipole-dipole effects.

Studying our cold Rydberg gas James Millen. Level scheme (5s 2 ) 1 S 0 461nm 32MHz (5s5p) 1 P 1 (5sns) 1 S 0 (5snd) 1 D 2 Continuum ~413nm Studying our.

Rydberg & plasma physics using ultra-cold strontium James Millen Supervisor: Dr. M.P.A. Jones Rydberg & plasma physics using ultra-cold strontium.

Studying a strontium MOT – group meeting Studying a strontium MOT James Millen.

Autoionization of strontium Rydberg states

Excited state spatial distributions Graham Lochead 20/06/11.

Trapped Radioactive Isotopes:  icro-laboratories for fundamental Physics EDM in ground state (I=1/2) H = -(d E + μ B) · I/I m I = 1/2 m I = -1/2 2ω12ω1.

H. J. Metcalf, P. Straten, Laser Cooling and Trapping.

Excitation of Ultracold Molecules to “Trilobite-like” Long-range Molecular Rydberg States M. A. Bellos, R. Carollo, J. Banerjee, E. E. Eyler, P. L. Gould,

Precise Measurement of Vibrational Transition Frequency of Optically Trapped molecules NICT Masatoshi Kajita TMU G. Gopakumar, M. Abe, M. Hada We propose.

Spin-polarization using ns~fs laser pulses Takashi Nakajima Institute of Advanced Energy Kyoto University

Evidence of Radiational Transitions in the Triplet Manifold of Large Molecules Haifeng Xu, Philip Johnson Stony Brook University Trevor Sears Brookhaven.

Kinetic Investigation of Collision Induced Excitation Transfer in Kr*(4p 5 5p 1 ) + Kr and Kr*(4p 5 5p 1 ) + He Mixtures Md. Humayun Kabir and Michael.

Solution Due to the Doppler effect arising from the random motions of the gas atoms, the laser radiation from gas-lasers is broadened around a central.

N. Yugami, Utsunomiya University, Japan Generation of Short Electromagnetic Wave via Laser Plasma Interaction Experiments US-Japan Workshop on Heavy Ion.

Accurate density measurement of a cold Rydberg gas via non-collisional two-body process Anne Cournol, Jacques Robert, Pierre Pillet, and Nicolas Vanhaecke.

Using this method, the four wave transition linewidth was measured at several different frequencies of current modulation. The following plot shows the.

Coherent excitation of Rydberg atoms on an atom chip

Obtaining Ion and Electron Beams From a source of Laser-Cooled Atoms Alexa Parker, Gosforth Academy  Project Supervisor: Dr Kevin Weatherill Department.

D. L. McAuslan, D. Korystov, and J. J. Longdell Jack Dodd Centre for Photonics and Ultra-Cold Atoms, University of Otago, Dunedin, New Zealand. Coherent.

Progress towards laser cooling strontium atoms on the intercombination transition Danielle Boddy Durham University – Atomic & Molecular Physics group.

Progress Towards Formation and Spectroscopy of Ultracold Ground-state Rb 2 Molecules in an Optical Trap H.K. Pechkis, M. Bellos, J. RayMajumder, R. Carollo,

Elastic collisions. Spin exchange. Magnetization is conserved. Inelastic collisions. Magnetization is free. Magnetic properties of a dipolar BEC loaded.

Stefan Truppe MM-Wave Spectroscopy and Determination of the Radiative branching ratios of 11 BH for Laser Cooling Experiments.

Trap loss of spin-polarized 4 He* & He* Feshbach resonances Joe Borbely ( ) Rob van Rooij, Steven Knoop, Wim Vassen.

Considerations on Rydberg transport for antihydrogen formation Daniel Comparat Laboratoire Aimé Cotton Orsay FRANCE.

Quantum interference phenomenon Quantum interference phenomenon in the cold atomic cascade system $$ : National Science Council and National Space Program.

W I S S E N T E C H N I K L E I D E N S C H A F T  Januar 13 Name und OE, Eingabe über > Kopf- und Fußzeile.

Experiments with Stark-decelerated and trapped polar molecules Steven Hoekstra Molecular Physics Department ( Gerard Meijer) Fritz-Haber-Institutder Max-Planck-Gesellschaft.

Resonant dipole-dipole energy transfer from 300 K to 300μK, from gas phase collisions to the frozen Rydberg gas K. A. Safinya D. S. Thomson R. C. Stoneman.

Excited state spatial distributions in a cold strontium gas Graham Lochead.

Optically detected magnetic resonance of silicon vacancies in SiC Kyle Miller, John Colton, Samuel Carter (Naval Research Lab) Brigham Young University.

-Plasma can be produced when a laser ionizes gas molecules in a medium -Normally, ordinary gases are transparent to electromagnetic radiation. Why then.

Dynamics of Low Density Rydberg Gases Experimental Apparatus E. Brekke, J. O. Day, T. G. Walker University of Wisconsin – Madison Support from NSF and.

Spatial distributions in a cold strontium Rydberg gas Graham Lochead.

Rydberg States of Two Valence Electron Atoms W. E Cooke K.A. Safinya W. Sandner F. Gounand P. Pillet N. H. Tran R. Kachru R. R. Jones.

Spatial distributions in a cold strontium Rydberg gas Graham Lochead.

Millimeter Wave Spectroscopy of Cold 85 Rb Atoms JIANING HAN, YASIR JAMIL, PAUL TANNER, DON NORUM, T. F. GALLAGHER University of Virginia Supported by:

Intramolecular Energy Redistribution in C 60 M. Boyle, Max Born Institute.

Rydberg Series of C 60 Osnabrück, Germany March 2002 Eleanor Campbell, Göteborg University & Chalmers, Sweden R.D. Levine, Fritz Haber Center, Hebrew University.

Direct Observation of Rydberg–Rydberg Transitions in Calcium Atoms K. Kuyanov-Prozument, A.P. Colombo, Y. Zhou, G.B. Park, V.S. Petrović, and R.W. Field.

|| Quantum Systems for Information Technology FS2016 Quantum feedback control Moritz Businger & Max Melchner

Microwave Spectroscopy of the Autoionizing 5d 3/2 n l States of Barium Edward Shuman Tom Gallagher.

Multi-step and Multi-photon Excitation Studies of Group-IIB Elements

Microwave Transitions Between Pair States Composed of Two Rb Rydberg Atoms Jeonghun Lee Advisor: Tom F. Gallagher Department of Physics, University of.

Summary Blackbody radiation Einstein Coefficients

Many-Body Effects in a Frozen Rydberg Gas Feng zhigang

Test of Variation in m p /m e using 40 CaH + Molecular Ions in a String Crystal NICT Masatoshi Kajita TMU Minori Abe We propose to test the variation in.

Manipulating Rydberg Atoms with Microwaves

QUANTUM TRANSITIONS WITHIN THE FUNCTIONAL INTEGRATION REAL FUNCTIONAL

Resonant dipole-dipole energy transfer

Excitation control of a cold strontium Rydberg gas

Making cold molecules from cold atoms

State evolution in cold helium Rydberg gas

Presentation transcript:

A strontium detective story James Millen Strontium detective – Group meeting 19/10/09 Ions‽

Strontium detective – Group meeting 19/10/09 The scene Create a MOT Measure MOT population/density Turn off trap Do Rydberg excitation Detect ions Measure MOT again Step Rydberg laser frequency

Strontium detective – Group meeting 19/10/09 Rydberg excitation 460.7nm ΩpΩp ΩcΩc ~420nm  p = 2πx32MHz  c = 2πx0.3MHz for D state [1] 5s 2 1 S 0 5s5p 1 P 1 5s18d 1 D 2 or 5s18s 1 S 0

Integrated ion signal at each coupling laser frequency Fraction of atoms lost during Rydberg excitation Strontium detective – Group meeting 19/10/09 The crime “Ion signal” or “Ion signal height” “Loss fraction” or “Resonant loss fraction”

Strontium detective – Group meeting 19/10/09 Clues Coupling laser power

Strontium detective – Group meeting 19/10/09 Clues Probe laser power (D state only)

Strontium detective – Group meeting 19/10/09 Clues - timing Time evolution of the ion signal Δ t = 0 Δ t = 4μs 4μs probe and coupling pulse 4μs 3.6Vcm -1 E field pulse

Strontium detective – Group meeting 19/10/09 The suspects Electric field ionization [1] For 5s18d state require ~5.4kVcm -1 With our field of ~4Vcm -1 should only be able to field ionize n≈97 and above

Strontium detective – Group meeting 19/10/09 The suspects Blackbody ionization Gallagher (the book!) gives a rough estimate: This yields τ bb = 5μs for n = 18 and T = 900K. More recent work by some Russians [1] yields a lower rate. The lifetime of the 5s18d 1 D 2 state is 640ns [2]

Strontium detective – Group meeting 19/10/09 The suspects Auto-ionization (two electron excitation) [3] 5s 2 5s5p 5s18s s s p s s 5p 1/2 18s s p Δ 5s18s state is closest to the auto-ionizing resonance… over 300GHz away! However, the width of the resonance is 200GHz! So only 1.6 linewidths away

Strontium detective – Group meeting 19/10/09 The suspects Hot atoms Collisions with hot Rydberg atoms could cause ionization [4] The Zeeman slowed atoms have been ruled out Could a small fraction of our hot Sr atoms get excited to the Rydberg state? How do we test this?

Strontium detective – Group meeting 19/10/09 The suspects Collisions Rydberg atoms collide (with resonant dipole- dipole interactions) This leads to ionization, plasma formation, avalanche effect. It has also been observed to be extremely fast (sub μs) [5] [6] Tentative calculations suggest we’re exciting ~40% of our sample to the Rydberg state

Strontium detective – Group meeting 19/10/09 The Culprit? Electric field: Unlikely, unless population is being transferred to higher n states Black body: Looks like it’s too slow, though it can redistribute population… Auto-ionization: need to look in more detail. Is scaling with power as you’d expect? Hot atoms: pass Collisions: not seen a signature of plasma formation yet… needs more work

Strontium detective – Group meeting 19/10/09 References [1] “Ionization of Rydberg atoms by blackbody radiation” N. N. Bezuglov et. al. arXiv: (2009) [2] “Natural radiative lifetimes in the interacting 1,3 D 2 sequences in Sr” S. Svanberg et. al. Phys. Rev. A (1983) [3] ”Sr 5p 1/2 ns 1/2 and 5p 3/2 ns 1/2 J=1 autoionizing states” T. F. Gallagher et. al. Phys. Rev. A (1986) [4] “Spontaneous evolution of Rydberg atoms into an ultracold plasma” P. Pillet et. al. Phys. Rev. Lett (2000) [5] “Ionization due to the interaction between two Rydberg atoms” Robicheaux J. Phys. B: At. Mol. Opt. Phys. 38 S333 (2005) [6] “Autoionization of an ultracold Rydberg gas through resonant dipole coupling” M. Weidemüller et. al. arXiv: (2009)