The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln Ionization Detectors Henri Becquerel (1852-1908) received.

Slides:

Advertisements

Similar presentations

The Discovery of Radioactivity GROUP 8 Richard Loew Jace Grandinetti Edward Duran Emil Blumburg.

Advertisements

Tyler Thiele.  Cosmic rays are high energy charged particles, in outer space, that travel at nearly the speed of light and strike the Earth from all.

Geiger-Muller detector and Ionization chamber

Radioactivity 1 輻射 Presented by Mr. Y. N. Chan LIU PO SHAN MEMORIAL COLLEGE.

Experimental Particle Physics PHYS6011 Joel Goldstein, RAL 1.Introduction & Accelerators 2.Particle Interactions and Detectors (1/2) 3.Collider Experiments.

Radiation Detectors / Particle Detectors

LIGHTNING PHENOMENON 1. The height of the cloud base above the surrounding ground level may vary from 160 to 9,500 m. The charged centres which are responsible.

 The nucleus of the atom is composed of protons and neutrons  Some nuclei are stable, some are unstable  Larger nucleus = more unstable  Smaller nucleus.

Radioactivity Radiation: –stream of particles/waves Radioactive Materials: –material that emit penetrating/dangerous radiation –radiation comes from nucleus.

History of Particle Detectors

Tracking detectors/1 F.Riggi.

Shantanu Menon Thomas Irons Michael Jacoutot. Cosmic Rays  High energy particles (mainly protons) from outer space.  Have up to 10 million times more.

6. Atomic and Nuclear Physics

1900 Charles T. R. Wilson’s ionization chamber Electroscopes eventually discharge even when all known causes are removed, i.e., even when electroscopes.

To be charged : means the particle is capable of emitting and absorbing photons What’s the ground state or zero-point energy of a system? e  e  harmonic.

Dd q2q2  b. What about the ENERGY LOST in the collision? the recoiling target carries energy some of the projectile’s energy was surrendered if the.

Scanning Electron Microscope Jamie Goings. Theory Conventional microscopes use light and glass lenses SEM uses electrons and magnetic lenses to create.

Proportional Counters

Detectors. Measuring Ions  A beam of charged particles will ionize gas. Particle energy E Chamber area A  An applied field will cause ions and electrons.

Main detector types Multi Pixel Photon Counter (MPPC) and Charge Coupled Devices (CCDs) How does it work? 1. Photon hits a pixel producing electron hole.

Ionizing Radiation radioactivity measurements

Topic 7: Atomic and nuclear physics 7.2 Radioactive Decay 3 hours.

Discovering Particles

Targets of our work group Simple lessons with BC photographs History of BC Overview of 50-minutes lesson FAQs.

Who is this?. Marie Curie Born 1867 Poland 1893 degree in physics, 1894 degree in mathematics Denied a place in Krakow University because she was.

Why are low energy neutrons more dangerous than high energy neutrons?  Generally radiation causes damage to cells because it ionizes atoms. This can break.

Chapter 30: Nuclear Physics and Radioactivity. Radioactivity Radioactivity is the discentigration of an unstable nuclei. when the nuclei decays the nucleus.

Mv 0 mv f  (mv) =  recoil momentum of target ( )  mv 0 mv f large impact parameter b and/or large projectile speed v 0 v f  v o For small scattering.

Visual methods.  the cloud chamber, also known as the Wilson chamber, is a particle detector used for detecting ionizing radiation.  In its most basic.

Tools for Nuclear & Particle Physics Experimental Background.

Melanie Carter and Jamie Hegarty. CLOUD CHAMBER OUTLINE Introduction: Cloud Chamber Principles All About Ionizing Radiation –Types of Radiation, why it’s.

Victor Hess took a gold leaf electroscope on his balloon flight to detect radiation. When an electroscope is charged, its “leaves” repel. A radioactive.

Radioactivity I §Content: §Radioactive substance §Three types of radiation §Properties of radiation §To investigate the radiation by apparatus §To summarize.

DISCOVERY OF RADIOACTIVITY

Intro to Nuclear Chemistry

Background Radiation Patterns Eli Braun and Evan Stewart Pd.1.

The tentative schedule of lectures for the semester with links to posted electronic versions of my notes.

Calorimeters  A calorimeter is a detector that measures “energy” of the particles that pass through. Ideally it stops all particles of interest.  Usually.

Seeing the Subatomic Stephen Miller Saturday Morning Physics October 11, 2003.

Unit C RADIOACTIVITY: NATURAL AND ARTIFICIALRADIOACTIVITY: NATURAL AND ARTIFICIAL (HANK 9:57 )

Cosmic Rays Cosmic Rays at Sea-Level - Extensive Air Showers and the detection of cosmic rays.

Ch. 25 Nuclear Changes Begins on p. 35 of your PACKET.

Galactic Cosmic Rays (GCRS) Galactic cosmic rays (GCRs) come from outside the solar system but generally from within our Milky Way galaxy. GCRs are atomic.

Photography in detectors. This cloud-chamber photograph, showing the track of a positively charged particle of electronic mass slowed down by passing.

II. DETECTORS AND HOW THEY WORK

C.T.R. Wilson. Charles Wilson is 2nd from right in the front row. Can you find Paul Langevin and O.W. Richardson?

What’s Hot in High Energy Particle Physics Study of the fundamental constituents & interactions of matter. What is the universe made of and by what rules.

Cloud Chamber Intro Aha Moments……. Wilson, Charles Thomas

PHYSICS 225, 2 ND YEAR LAB NUCLEAR RADIATION DETECTORS G.F. West Thurs, Jan. 19.

1 Experimental particle physics introduction. 2 What holds the world together?

The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln A History of Cosmic Rays “If we knew what we were doing,

THE HISTORY OF AN ATOM. What is an Atom? Atom is a portion of an element that takes part in chemical reactions. Atom is a portion of an element that takes.

Detection of Radiation Contents: Geiger tubes Photo-Multiplier tubes Cloud Chambers Solid State devices.

Wilson cloud chamber.

Nuclear Chemistry Unit 4. History Wilhelm Conrad Roentgen ( ) Wilhelm Conrad Roentgen ( ) Awarded a Nobel Prize in Physics in 1901 Awarded.

Radioactivity and Nuclear Decay Test on Friday March 1.

Measurement devices Cloud chamber Geiger counter Bubble chamber Nuclear emulsion 2.

KS4 Radioactivity. AlphaBetaGamma Penetrating power Range of radiation leastmediummost shortestmediumlongest.

Geiger-Mueller Counters Darwin L. Boyd Kent State University School of Technology.

Radioactivity Discovery of radioactivity Discovery of radioactivity (1896) : Henri Becquerel Next Slide Exposure of film by X-ray Discovery of radioactive.

CLOUD CHAMBER There are more particles around us at all times. We just needed to learn how to look. Particles Detectors Cloud Chamber: 1911, C.T.R. Wilson.

Alpha, Beta, gamma.

Chapter 9 – Radioactivity and Nuclear Reactions

A –Level Physics: Nuclear Physics Particle Detectors

25.3 – Detecting Radioactivity

NUCLEAR RADIATION DETECTORS

NOTE: The spatial distribution depends on the particular frequencies involved  x 2  1 k k =  x  Two waves of slightly different wavelength and.

The Cloud Chamber Bengu Bozlar*

Presentation transcript:

The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln Ionization Detectors Henri Becquerel ( ) received the 1903 Nobel Prize in Physics for the discovery of natural radioactivity. Wrapped photographic plate showed clear silhouettes, when developed, of the uranium salt samples stored atop it While studying photographic images of various fluorescent and phosphorescent materials, Becquerel finds potassium-uranyl sulfate spontaneously emits radiation capable of penetrating thick opaque black paper aluminum plates copper plates Exhibited by all known compounds of uranium (phosphorescent or not) & metallic uranium itself.

The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln Ionization Detectors 1930s plates coated with thick photographic emulsions (gelatins carrying silver bromide crystals) carried up mountains or in balloons clearly trace cosmic ray tracks through their depth when developed light produces spots of submicroscopic silver grains a fast charged particle can leave a trail of Ag grains 1/1000 mm (1/25000 in) diameter grains small singly charged particles - thin discontinuous wiggles only single grains thick heavy, multiply-charged particles - thick, straight tracks November 1935 Eastman Kodak plates carried aboard Explorer II’s record altitude (72,395 ft) manned flight into the stratosphere 1937 Marietta Blau and Herta Wambacher report “stars” of tracks resulting from cosmic ray collisions with nuclei within the emulsion

The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln Ionization Detectors 1937 Marietta Blau and Herta Wambacher report “stars” of tracks resulting from cosmic ray collisions with nuclei within the emulsion

The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln Ionization Detectors 1894 After weeks in the Ben Nevis Observatory, British Isles, Charles T. R. Wilson begins study of cloud formation a test chamber forces trapped moist air to expand supersaturated with water vapor condenses into a fine mist upon the dust particles in the air each cycle carried dust that settled to the bottom purer air required larger, more sudden expansion observed small wispy trails of droplets forming without dust to condense on!

The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln Ionization Detectors Cloud chamber photographs by George Rochester and J.G. Wilson of Manchester University showed the large number of particles contained within cosmic ray showers.

The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln Ionization Detectors

The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln Ionization Detectors

The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln Ionization Detectors 1952 Donald A. Glaser invents the bubble chamber boiling begins at nucleation centers (impurities) in a liquid along ion trails left by the passage of charged particles in a superheated liquid tiny bubbles form for about 10 msec before being obscured by a rapid, agitated “rolling” boil hydrogen, deuterium, propane(C 3 H 6 ) or Freon(CF 3 Br) is stored as a liquid at its boiling point by external pressure (5-20 atm) super-heated by sudden expansion created by piston or diaphragm bright flash illumination and stereo cameras record 3D images through the depth of the chamber (~6  m resolution possible) a strong (2-3.5 tesla) magnetic field can identify the sign of a particle’s charge and its momentum (by the radius of its path) 1960 Glaser awarded the Nobel Prize for Physics

The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln Ionization Detectors Spark Chambers High Voltage across two metal plates, separated by a small (~cm) gap can break down. d

The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln Ionization Detectors If an ionizing particle passes through the gap producing ion pairs, spark discharges will follow it’s track. In the absence of HV across the gap, the ion pairs usually recombine after a few msec, but this means you can apply the HV after the ion pairs have formed, and still produce sparks revealing any charged particle’s path! Spark chambers (& the cameras that record what they display) can be triggered by external electronics that “recognize” the event topology of interest.

The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln Ionization Detectors HV pulse Logic Unit A B C Incoming particle Outgoing particles

The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln Ionization Detectors Georges Charpak develops the multiwire proportional chamber 1992 Charpak receives the Nobel Prize in Physics for his invention

The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln Ionization Detectors

The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln Ionization Detectors

The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln Ionization Detectors

The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln Ionization Detectors

The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln Ionization Detectors

The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln Ionization Detectors 20  m dia 2 mm spacing argon-isobutane spatial resolutions < 1mm possible

The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln Ionization Detectors

The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln Ionization Detectors The Detector in various stages of assembly

The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln Ionization Detectors

The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln Ionization Detectors

The Cosmic Ray Observatory Project High Energy Physics Group The University of Nebraska-Lincoln Ionization Detectors