Ion Motion Through an RFQ

Slides:

Advertisements

Similar presentations

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

Advertisements

RFQ development for high power beams

What is the ISOLDE cooler RFQ CB - ISCOOL H. Frånberg.

ISOLDE WS 2007 Results with ISCOOL a new Radio Frequency Quadrupole Cooler and Buncher at ISOLDE P. Delahaye, H. Frånberg, AB-OP-PSB, ISCOOL, COLLAPS,

Sanja Risticevic Chem 323 Poster Presentation Quadrupole Ion Trap Mass Spectrometry.

Charged Particles in Electric and Magnetic Fields Motion of charged particles Lorentz Force Examples: cyclotron, mass spectrometer.

Simulation of Radio Frequency Quadrupole Mass Analyzer Stephen Jones EPS 109 Final Project 11/27/12.

Causing Rotational Motion In order to make an object start rotating about an axis, a force is required However, not only the amount of force applied but.

On-line tests RFQ cooler ISCOOL A quick summary P. Delahaye, H. Frånberg, I. Podadera ISCOOL, COLLAPS, ISOLDE collaboration.

F.M.H. Cheung School of Physics, University of Sydney, NSW 2006, Australia.

Lapse Rates and Stability of the Atmosphere

March 2011Particle and Nuclear Physics,1 Experimental tools accelerators particle interactions with matter detectors.

Parameter sensitivity tests for the baseline variant Konstantin Lotov, Vladimir Minakov, Alexander Sosedkin Budker Institute of Nuclear Physics SB RAS,

Fundamentals of Rocket Stability It’s (not) rocket science!

Mass Analyzers IV Quadrupole Ion Traps Chem 5181 – Fall 2007 J. Kimmel.

MS Intro. MS requires gas-phase ions, why? MS uses magnetic and electric fields to control the path of a compound based on mass to charge ratio (m/z)

Energy is the capacity to do work or produce a change. Think of the energy of a substance as the total of the kinetic & potential energies of all the particles.

Mass Analyzers: Quadrupole ion trap?

A mass-purification method for REX beams

Comprehension Check 1. If you have a charge of 1.0C, how many electrons have been removed from the object? 2. What voltage is created if a charged particle.

Rotational Motion of an Object Physics Matters: Chapter 7.

Energy Transformations Electricity and Magnetism

WITCH - a first determination of the beta-neutrino angular correlation coefficient in 35 Ar decay S. Van Gorp, M. Breitenfeldt, V. De Leebeeck,T. Porobic,

INTENSITY LIMITATIONS IN THE LHC INJECTORS Discussion on Landau damping Ibon Santiago González Summer Student Session 2007.

Studies on 2.45 GHz microwave ion sources Abhishek Nag IISER, KOLKATA Presented By: G.O. Rodrigues IUAC, New Delhi Supervised By:

Physics Chapter 7 Supplementary Apply rotary motion An object that rotates about an internal axis exhibits rotary motion. Angular displacement (denoted.

DC Sputtering Disadvantage #1 Low secondary electron yield

Single particle trapping and characterization

Electricity and Magnetism

ELECTRONIC DEVICES AND CIRCUITS

3. Force and motion 3.1. Newton’s First Law

Lecture 4 OUTLINE Semiconductor Fundamentals (cont’d)

High Voltage Engineering Insulation: Liquid dieletrics

Effects of Magnetic Fields and Producing Current

15-2 Behavior of Gases 15-3 Graphing Gas Behavior

Ch 8 : Rotational Motion .

Chapter 6 Overview.

Design of the MANX experiment

Fields: Forces and Energy

Gas Behavior Chapter 3 Section 3.

6. Maxwell’s Equations In Time-Varying Fields

Charged Particles in Electric and Magnetic Fields

Section 8.3 Equilibrium Define center of mass.

Lecture 4 OUTLINE Semiconductor Fundamentals (cont’d)

Mass Spectrometry.

Group 14 SmartGLove hardware design

A Solar System is Born.

The Effect Of A Magnetic Field On Charged Particles

A beam of particles, all with the same momentum but with a variety of masses and charges, enters a region of uniform magnetic field, as shown in the picture.

Torque Torque (t) – measure of the ability of a force to rotate an object around an axis (fulcrum). Torque is not a force. It is a rotational analog to.

Centrifugal force It does not exist!.

Chapter 29 Problems Problems 7, 9, 12, 30, 37, 41.

Electricity and Magnetism

Part 2: Rocket Principles

10.6 Fourier Transform Mass Spectrometry

Air Pressure Can you feel it? 1.

LASERS By Swapan Das.

+ and - Stability/ Unstability -Repulsion

Movement of Charges In a Magnetic Field.

Chapter 3 Section 3 The behavior of Gases.

Air Pressure Can you feel it? 1.

A LINEAR RFQ TRAP FOR COOLING AND BUNCHING OF RADIOACTIVE ION BEAMS

Ohm’s Law & Circuits Chapter 7.2 & 7.3.

12.1 Atomic Structure.

Lecture 2 - Transverse motion

Lecture 24 ACCELERATOR PHYSICS HT E. J. N. Wilson

CHROMATOGRAPHY.

Longitudinal Focusing & The Gamma Transition

He Zhang, David Douglas, Yuhong Zhang MEIC R&D Meeting, 09/04/2014

Improvement of a dc-to-pulse conversion efficiency of FRAC

Presentation transcript:

Ion Motion Through an RFQ Varying the q-value Varying the Buffer Gas Pressure The q-value We define the q-value for an ion inside an RFQ device to be: Where: e = the charge on the ion Vpp = the peak-to-peak voltage applied to the RFQ m = the mass of the ion r0 = the radius of the RFQ Ω = the angular frequency of the applied RF-field The q-value governs the stability of the ions paths in the RFQ. In an RFQ the ion motion is stable for q ≤ 0.908. For q-values higher than 0.908 the ion motion is unstable and hence the ions are not trapped.

The Effect of Varying the q-value

Buffer Gas Cooling An ion beam can be cooled via collisions with an inert buffer gas however such collisions cause the beam to diverge. The RFQ provides a force that pushes the ions onto its Z-axis hence an ion beam can be cooled inside an RFQ via collisions with a buffer gas without the beam diverging. By varying the buffer gas pressure one can control the time it takes for cooling to take place.

The Effect of Varying the Buffer Gas Pressure q=0.4_p=1^-2 q=0.4_p=1^-3 q=0.4_p=2.5^-2 q=0.4_p=5^-2 q=0.4_p=5^-3