Radiopharmaceutical Production

Slides:

Advertisements

Similar presentations

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

Advertisements

QUANTA TO QUARKS DOT POINT 4.4 Identity ways by which physicists continue to develop their understanding of matter, using accelerators as a probe to investigate.

Radiopharmaceutical Production

Radiation Detectors / Particle Detectors

Particle Accelerator. Particle accelerators It is a device that provides – forces on charge particles – by some combinations of electric & magnetic fields,

NCEA Physics Thermionic emission.

Particle Accelerators

ENTRY TASK Get your notebooks Pencil Highlighter.

427 PHC.  Atomic emission spectroscopy (AES) is based upon emission of electromagnetic radiation by atoms.

2/xx/07184 Lecture 221 PHY 184 Week 6 Spring 2007 Lecture 22 Title: The Lorentz Force = q v x B.

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

Accelerators. Electron Beam  An electron beam can be accelerated by an electric field. Monitors Mass spectrometers  Any charged particle can be accelerated.

Our sun is a star located in our Solar System. It is a huge, spinning ball of hot gas, mostly hydrogen and helium, that lights up the Earth and provides.

Radiopharmaceutical Production

Chapter 28 Magnetic Fields Key contents Magnetic fields and the Lorentz force The Hall effect Magnetic force on current The magnetic dipole moment.

Lecture 11  Production of Positron Emitters, Continued  The Positron Tomograph.

Atomic Emission Spectroscopy

FFAG Fixed Field Alternating Gradient synchrotrons, FFAGs, combine some of the main advantages of both cyclotrons and synchrotrons:  Fixed magnetic field.

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

Tools for Nuclear & Particle Physics Experimental Background.

An Introduction To Particle Accelerators A-Level Physics.

Lecture 16 Magnetic Fields& Force

Outline Cyclotrons and Synchrotrons Cyclotrons and Synchrotrons History History Compare to Linear Accelerators Compare to Linear Accelerators Schematic.

Overview of Cyclotron Facilities

The ISIS strong focusing synchrotron also at the Rutherford Appleton Laboratory. Note that ISIS occupies the same hall as NIMROD used to and re- uses some.

Thomas Jefferson National Accelerator Facility Operated by the Southeastern Universities Research Association for the U. S. Department of Energy USPAS.

LBNL 88'' cyclotron operations Status of the 88-Inch Cyclotron High-Voltage upgrade project December 14, 2009 Ken Yoshiki Franzen.

Schmitz F., Van Naemen J., Monclus M., Van Gansbeke B., Kadiata M., Ekelmans D., Moray M., Penninckx R., Goldman S. PET/Biomedical Cyclotron Unit, ULB-Hospital.

FFAG F ixed F ield A lternating G radient Synchrotrons A new type of particle accelerator - with a wide variety of applications Cancer Therapy and UK Activities.

Lecture 10  Relationship Between Wavelength, Frequency, Energy, and Velocity of Light  Production of Positron Emitters  Image of the Week.

Chapter 8 Charges in Magnetic Fields. Introduction In the previous chapter it was observed that a current carrying wire observed a force when in a magnetic.

Book Reference : Pages To understand that the path of a charged particle in a magnetic field is circular 2.To equate the force due to the magnetic.

2c) Energy and Potential Difference in Circuits Part 1 Current and Charge.

The cyclotron The cyclotron was first designed to avoid the need for a long linear accelerator to obtain high energy particles. It consists of two semicircular.

Georgia Performance Standard S8P5. Students will recognize characteristics of gravity, electricity, and magnetism as major kinds of forces acting in nature.

Principles of Electromechanics Electricity  Motion Electricity  Motion: Motor Motion  Electricity: Generator  Magnetic Field & Faraday’s Law.

Radiopharmaceutical Production

Synchrotron Radiation Presented ByCourse Incharge Muhammad Azhar Ishfaque Ahmed Prof. Dr. Saqib Anjum.

Radiopharmaceutical Production Cyclotron radionuclide production STOP.

8.5 – Applications of Electric and Magnetic Fields

The Electromagnetic Spectrum

Particle in uniform B-field

Radiopharmaceutical Production

International Teacher Programme /8/ /8/2017

Electron Beam Welding Welding Technology/4.3 Electron Beam Welding.

Nuclear Fusion and energy utilities

Summary of session 5: Innovative Ideas and New R&D

Electromagnetic Waves. Energy Carried by Electromagnetic Waves.

@ 2016 Global Market Insight, Inc. USA. All Rights Reservedwww.fractovia.org Oil-Free Air Compressor Market PDF Report; Product Analysis, Size, Industry.

Force on an Electric Charge Moving in a Magnetic Field

The Mysterious Magnetic Field

The Effect Of A Magnetic Field On Charged Particles

C.Octavio Domínguez, Humberto Maury Cuna

Electrical Energy and Current

PARTICLE ACCELERATOR.

Chapter 28 Magnetic Fields

Charging by Magnetism Since you can create a magnetic field by running electricity through a wire, can you create electricity using a magnetic field?

B.Sc.II, Paper VIII ( IIISemester)

Machine Sources of Radiation

By Daveed Ransome and a little bit of work done by Charles Cramer

Radiopharmaceutical Production

CYCLOTRON PREPARED BY Dr. P. K. Sharma.

Radiopharmaceutical Production

Constant Current Power Supplies for LEDs

CfE Higher Unit 2 – Particles and Waves

Presentation transcript:

Radiopharmaceutical Production Cyclotron Operations STOP

Cyclotron Operations The cyclotron is typically the core of the radiopharmaceutical production facility. If the cyclotron is not functioning, all other operations stop. Although the cyclotron was invented more than 70 years ago, the basic components are the same now as they were then. The technology has improved to the point where these are very reliable machines and can be run with a basic understanding of the underlying principles Contents History of the Cyclotron Basic Operation of the Cyclotron Commercial Cyclotrons ►See a video by IBA about the cyclotron STOP

Cyclotron History The cyclotron was developed in the 1930’s in Berkeley, California by E.O. Lawerence. His idea was to use a magnetic field to constrain a charged particle to a circular path and use the same acceleration voltage over and over again to add more energy. The number of cyclotrons in the world is growing at a very rapid pace. In 2000 there were about 350 world-wide and in 2008, it was estimated that the number had grown to nearly 600. The expansion of clinical PET using FDG played and important role in that growth. If you wish to learn more about the history, here is a presentation on the history of the cyclotron. More Cyclotron History

Cyclotron Operations The cyclotron creates an ion in the center and then uses a radio-frequency electric field to accelerate the particle. Once the particle has gained enough energy, it can be extracted from the accelerating field and directed towards a target material in order to carry out a nuclear reaction. There are several advantages of cyclotrons over other types of accelerators. These are: Cyclotrons have a single electrical driver, which saves both money and power, since more expense may be allocated to increasing efficiency. Cyclotrons produce a continuous stream of particles at the target, so the average power is relatively high. The compactness of the device reduces other costs, such as its foundations, radiation shielding, and the enclosing building A slightly more detailed description of Cyclotron operations is available here. More Cyclotron Basics

Commercial Cyclotron Modern cyclotrons come in many sizes and energy ranges and are commercially available from several manufacturers. They range from rather small cyclotrons designed specifically to produce fluorine-18 to large cyclotrons capable of producing a wide range of radionuclides. A list of some of the more common commercially produced cyclotrons is available here. More Cyclotron Comparison

Return to Main Menu