The Use of Molecular Beam Electric Resonance Technique for High Precision Hyperfine Measurements Charles McEachern, Ben McDonald and Professor James Cederberg.

Slides:

Advertisements

Similar presentations

Applications of the Motion of Charged Particles in a Magnetic Field AP Physics C Montwood High School R. Casao.

Advertisements

 NMR arises from the fact that certain atomic nuclei have a property called “ spin ”  “Spin” is caused by circulating nuclear charge and can be thought.

FC-MS from Teledyne Isco CombiFlash ® a Name You Can Rely On.

Sub-picosecond Megavolt Electron Diffraction International Symposium on Molecular Spectroscopy June 21, 2006 Fedor Rudakov Department of Chemistry, Brown.

PIXE: Data Analysis What the data can (and cannot) tell us. Larry Lamm PIXE Seminar Winter 2008.

Mass Spectroscopy Mass Spectrometry ä Most useful tool for molecular structure determination if you can get it into gas phase ä Molecular weight of.

Quantum Computing with Trapped Ion Hyperfine Qubits.

Analysis of instrumental effects in HIBP equilibrium potential profile measurements on the MST-RFP Xiaolin Zhang Plasma Dynamics Lab, Rensselaer Polytechnic.

Low Temperature Photon Echo Measurements of Organic Dyes in Thin Polymer Films Richard Metzler ‘06, Eliza Blair ‘07, and Carl Grossman, Department of Physics.

CoolMolecules: Teaching Molecular Structure with the Cambridge Structural Database Robert M. Hanson, Melanie Casavant, and Michael McGuan St. Olaf College,

Microwave Spectroscopy I

Mass Spectrometry.

Physics of fusion power Lecture 10 : Running a discharge / diagnostics.

Accelerator Physics  Basic Formalism  Linear Accelerators  Circular Accelerators  Magnets  Beam Optics  Our Accelerator Greg LeBlanc Lead Accelerator.

Accelerators We’ve seen a number of examples of technology transfer in particle detector development from HEP (basic science) to industry (medical, …)

Magnetic Fields Magnetic fields emerge from the North pole of a magnet and go into the South pole. The direction of the field lines show the direction.

X-ray Diffraction Outline Crystals and Bragg Diffraction

Electron Paramagnetic Resonance at Hunter College

ELECTRON SPIN RESONANCE SPECTROCOPY

Electron Spin Resonance Spectroscopy

 PART Requirements for Spectroscopic Techniques for Polymers 1. High resolution 2. High sensitivity (>1%) 3. High selectivity between molecular.

Electrons Thermionic Emission

Magnetic Resonance Contributions to Other Sciences Norman F. Ramsey Harvard University Principles of Magnetic Resonance First experiments Extensions to.

Recirculation Concept - Cyclotron Radio frequency alternating voltage Hollow metal drift tubes time t =0 time t =½ RF period D-shaped.

Kovat’s retention Index

1 Magnetism.. 2 Magnetic Fields  Magnetic fields are historically described in terms of their effect on electric charges. A moving electric charge, such.

Mass Spectroscopy 1 Mass Spectroscopy (Mass Spec) Applying Atomic Structure Knowledge to Chemical Analysis.

Sarah Newton University of Oregon Applied Physics.

Future electron EDM measurements using YbF

NanoPHYS’12 – December 17-19, 2012 K. Nakano, S. Miyasaka, K. Nagai and S. Obata (Department of Physics, Tokyo Institute of Technology) Drift Chambers.

The Apparatus…. Ionic target studies…. Neutral target studies…. Queens University Belfast University College London.

Chemistry Topic: Atomic theory Subtopic : Mass Spectrometer.

1 EPIC SIMULATIONS V.S. Morozov, Y.S. Derbenev Thomas Jefferson National Accelerator Facility A. Afanasev Hampton University R.P. Johnson Muons, Inc. Operated.

Mass spectrometry (Test) Mass spectrometry (MS) is an analytical technique that measures masses of particles and for determining the elemental composition.

Our goal is to understand the properties of delocalized vacancies in solid 4 He. Using a triplet of orthogonal diffusion measurements we plan to locate.

Molecular Mass. Mass of Atom Measured in atomic mass unit (amu) 1 amu = 1.66 x g Defined by assigning the mass of 12 amu to the carbon-12 isotope.

PARALLEL PLATES. From previous work, the electric field strength can be found from the electric force on a test charge.

Fiducial Cuts for the CLAS E5 Data Set K. Greenholt (G.P. Gilfoyle) Department of Physics University of Richmond, Virginia Goal: To generate electron fiducial.

Mass Spectrometer: A Practical Use for Moving Charges in a Magnetic Field Physicists designed the mass spectrometer to assist the chemistry folks in determining.

Practical Microwave Beam Concepts

The Use of Molecular Beam Spectroscopy to Measure Hyperfine Interactions Sara Fortman, John Nichol, Jimmy Randolph and James Cederberg St. Olaf College.

Microwave Devices.

Sound Chapter 15. What is sound? It is a ______________wave The disturbance that causes it is a __________ The vibrations are transferred through _______________.

Momentum Corrections for E5 Data Set R. Burrell, G.P. Gilfoyle University of Richmond, Physics Department CEBAF The Continuous Electron Beam Accelerating.

Lecture 33 Rotational spectroscopy: energies. Rotational spectroscopy In this lecture, we will consider the rotational energy levels. In the next lecture,

Mass Spectrometry Relative atomic masses and the mass of individual isotopes can be determined using a mass spectrometer. The principle behind mass spectrometry.

Chapter 26 Electromagnetism. Mass of Electron Determined by J.J. Thomson Determined by the deflection of the electron in a cathode ray tube.

An Experimental Approach to the Prediction of Complete Millimeter and Submillimeter Spectra at Astrophysical Temperatures Ivan Medvedev and Frank C. De.

Electrons Thermionic Emission

Lecture 4 Longitudinal Dynamics I Professor Emmanuel Tsesmelis Directorate Office, CERN Department of Physics, University of Oxford ACAS School for Accelerator.

How do we know? Spectroscopy: Experimental Evidence.

Fiducial Cuts for the CLAS E5 Data Set K. Greenholt (G.P. Gilfoyle) Department of Physics University of Richmond, Virginia INTRODUCTION The purpose of.

Unit 3: Identifying elements and molecules Unit Objectives: Explain how mass spectrometry is used to identify different substances. Deduce the identify.

Mass Spectroscopy “You can’t make an omelette without breaking eggs” The Joker.

RESONANCE FREQUENCY SHIFT EFFECTS DUE TO CAVITY LENGTH AND WINDOW VARIATION By Gabriela Arriaga 1.

What are the only two forces your body has ever experienced??? GRAVITY ELECTRIC.

Scanning Electron Microscope Eee-Jay Rodriguez. The Structure of the Microscope Inside Outside.

Components of Mass Spectrometer

Continuous Flow Isotope Ratio Mass Spectrometry

Mass Spectroscopy. Mass Spectroscopy Mass Spectrometry Most useful tool for molecular structure determination if you can get it into gas phase Molecular.

5-level Rabi-flopping Rabi-flopping of a 5-level Zeeman split atom:

Introduction Spectroscopy is an analytical technique which helps determine structure. It destroys little or no sample. The amount of light absorbed by.

New Measurements of the Hyperfine Interactions and Dipole Moment of KI

Mass Spectrometry.

Lecture 22 Introduction to Mass Spectrometry Lecture Problem 7 Due

SPECTROPHOTOMETRY Applied Chemistry.

Electron Attachment TOF

Isotope Ratio Mass Spectrometers (IRMS)

Presentation transcript:

The Use of Molecular Beam Electric Resonance Technique for High Precision Hyperfine Measurements Charles McEachern, Ben McDonald and Professor James Cederberg Physics Department, St Olaf College, Northfield MN

The MolBeam Project Our work observes pure hyperfine transitions in order to describe very precisely various electric and magnetic interactions in our molecules.

The Apparatus “Old” is such an ugly word. We prefer to think of it as “aged to perfection.”

The Source Our source is a metal tube with a small hole in it. We use our effusive oven to vaporize our sample and send it out into the spectrometer.

The Lenses We use electrostatic quadrupole lenses as state selectors. They focus the states we want into a path straight through the transition region.

How do the Lenses Work? The lenses create an energy gradient that can be compared to a parabolic well.

Selecting States To get a strong signal the lenses must select the appropriate velocity for a given state.

Transition Region In this region there is an oscillating RF electric field and a DC field on large parallel plates. The combination of these two can induce a second order transition between hyperfine states.

Length of Transition Region The long (about 2 meters) transition region increases the  t of the transition, so the energy uncertainty is reduced.

More Lenses These lenses are set identically to those just before the transition region. They focus unchanged molecules to the detector. DetectorTransition RegionSource

The Detector Our detector is a tantalum filament. It has a high affinity for electrons, so it ionizes the molecules that hit it. We measure the current caused by these ionizations.

The Brains Previous student researchers have written all of our software.

Simulating Runs We can simulate the effects of various RF and DC voltages to pinpoint what we want our run to look like.

Effects of the RF and DC Voltage The RF and DC fields change the shape of the data.

Data Analysis Our collection software feeds us a scatter plot. We use Linefit to match a Rabi lineshape to our data very precisely.

Getting Results Once we have fit many transitions, we can plug the numbers into a program called specfit. This program gives us values for our constants. Ben will share what our numbers mean in the next talk.

Acknowledgements I would like to thank Professor Cederberg, the St. Olaf College Physics Department, the Whittier endowment, and the Howard Hughes Medical Institute for their resources, funding, and the opportunity to participate in this research.