Andrew Seltzman. Georgia Institute of Technology, Dept. of Physics

Slides:

Advertisements

Similar presentations

Electronics Cooling MPE 635

Advertisements

Multiphase Thermoelectric Converter Efficiently Harvesting Electricity from Waste Heat for Decreasing Size of Space Radiators Moacir L. Ferreira Jr. January.

W. Udo Schröder, 2004 Instrumentation 1. W. Udo Schröder, 2004 Instrumentation 2 Probes for Nuclear Processes To “see” an object, the wavelength of the.

X-radiation. X-rays are part of the electromagnetic spectrum. X-radiation (composed of X-rays) is a form of electromagnetic radiation. X- rays have a.

Ion Injector Design Andrew Seltzman.

Prentice Hall © 2003Chapter 21 Chapter 21 Nuclear Chemistry CHEMISTRY The Central Science 9th Edition.

Nuclear Physics Year 13 Option 2006 Part 2 – Nuclear Fusion.

Runaway Electron Mitigation Collaboration on J-TEXT David Q. Hwang UC Davis Sixth US-PRC Magnetic Fusion Collaboration Workshop Collaborating Institutions:

Fusion Physics - Energy Boon or Nuclear Gloom? David Schilter and Shivani Sharma.

Nuclear Physics: Radiation, Radioactivity & its Applications.

A Pyroelectric Crystal Particle Accelerator

Plasma Dynamics Lab HIBP Abstract Measurements of the radial equilibrium potential profiles have been successfully obtained with a Heavy Ion Beam Probe.

A Pyro-Electric Crystal Particle Accelerator Chelsea L. Harris, Texas Southern University Dr. Rand Watson, Texas A&M University Cyclotron Institute Pyroelectric.

A Desktop Particle Accelerator Employing a Pyroelectric Crystal Jon Kalodimos, Kansas State University Dr. Rand Watson, Texas A&M Cyclotron Institute.

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

Inertial Electrostatic Confinement Fusion Reactor Liquid Cooled Ion Accelerating Grid Design A. Seltzman, Georgia Institute of Technology Abstract: Reactor.

Deuterium Fusion Using Inertial Electrostatic Confinement

IB Physics 12 Nuclear Physics 6 Mr. Jean. The plan: Video clip of the day –Example of fission energies –Example of fusion energies –Recap of nuclear physics.

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

09/13/20111 Status of high intensity polarized electron gun project at MIT-Bates Evgeni Tsentalovich MIT.

Negative Ions in IEC Devices David R. Boris 2009 US-Japan IEC Workshop 12 th October, 2009 This work performed at The University of Wisconsin Fusion Technology.

Active Devices Vacuum tubes. Thomas Edison’s light bulb – Glass envelope – Vacuum – Filament.

Semion System Retarding Field Ion Energy Analyzer “

Active Devices Vacuum tubes. Thomas Edison’s light bulb – Glass envelope – Vacuum – Filament.

EXAM II Monday Oct 19 th (this coming Monday!) HW5 due Friday midnight.

The FAIR* Project *Facility for Antiproton and Ion Research Outline:  FAIR layout  Research programs Peter Senger, GSI USTC Hefei Nov. 21, 2006 and CCNU.

Physics of fusion power Lecture 12: Diagnostics / heating.

Controlled Nuclear Fusion The JET Project

GOLEM operation based on some results from CASTOR

Nuclear energy Summary of period 1. Parts of the atom Mass (A.M.U)Charge Proton1+1 Neutron10 Electron1/1830 Add/subtract a proton: creates a different.

High Energy Observational Astrophysics. 1 Processes that emit X-rays and Gamma rays.

Please remember to sit in assigned seats… before bell rings Outcome: SWBAT Compare and contrast nuclear fusion and fission by reviewing a video and creating.

MAIN COMPONENTS  INTODUCTION  PRINCIPLE  CONSTRUCTIONAL DETAILS  PROCESS  ADVANTAGES  DISADVANTAGES  CONCLUSION.

BUBBLE POWER THE REVOLUTIONARY NEW ENERGY SOURCE

Patient is placed between X-ray tube and silver halide film.

COLLEGE OF ENGINEERING DEPARTMENT OF MECHANICAL ENGINEERING MENB INTRODUCTION TO NUCLEAR ENGINEERING GROUP ASSIGNMENT GROUP MEMBERS: MOHD DZAFIR.

Radiopharmaceutical Production Cyclotron radionuclide production STOP.

Alexander Aleksandrov Spallation Neutron Source Oak Ridge, USA

SEMINAR ON BUBBLE POWER THE REVOLUTIONARY NEW ENERGY SOURCE

Degradation and Recovery of Cavity Performance

Visit for more Learning Resources

International Youth Conference on Fusion Energy Conference

Development of X-band 50MW klystron in BVERI

Seok-geun Lee, Young-hwa An, Y.S. Hwang

& Figures Descriptions

FUSION PROPULSION.

DOE Plasma Science Center Control of Plasma Kinetics

X-ray Production Sharif Qatarneh Medical Physics Division

Atomic Energy 3U Physics.

Part No...., Module No....Lesson No

25.3 Fission and Fusion of Atomic Nuclei

In Corial PECVD SYSTEMS

Figure: Title: Radioisotope scanning. Caption:

Applications of Nuclear Physics

The Sun Internal structure of the Sun Nuclear fusion

Outside the nucleus, the beta decay {image} will not occur because the neutron and electron have more total mass than the proton. This process can occur.

alpha beta gamma electron energy electron energy electron positive

Scintillation Counter

Birth out of the interstellar medium Contraction to a normal

Earth Chemistry.

Nuclear Chemistry Chapter 25.

Electrons & Energy Levels

Applications of Nuclear Physics

Generation of X-rays Q&A

Nuclear Fission and Fusion

Radhabai Kale Mahila Mahavidhyalaya, Ppt. name:- x-Ray techniques

The GDT device at the Budker Institute of Nuclear Physics is an experimental facility for studies on the main issues of development of fusion systems based.

Fission and Fusion.

Earth, Sun Chemistry.

Presentation transcript:

Andrew Seltzman. Georgia Institute of Technology, Dept. of Physics Inertial Electrostatic Confinement Fusion Liquid Cooled Ion Accelerating Grid Andrew Seltzman. Georgia Institute of Technology, Dept. of Physics

IEC Fusion Reactor Design Neutron Detector Vacuum Hub ECRF Drive Amplifier Primary Cooling Radiator Vacuum Envelope ECRF Injector Accelerating Grid System Fluorinert Micropump Mark 3 IEC Reactor Core IEC Reactor Core Design

IEC Fusion Overview Ion Trajectory Deuterium Fusion Central grid negatively biased Ions oscillate in electrostatic field Ions collide at focal point and fuse Fusion generated high energy neutrons and protons Ion Trajectory

Problems With Conventional Design Problem to be Solved: Grid heating due to ion bombardment causes thermionic electron emission, thereby increasing reactor power draw and generating unwanted x-ray radiation. Grid Heating A fraction of the accelerated ions collide with the grid heating it. A radiatively cooled grid will operate at high temperatures At high temperatures the grid emits a large thermionic electron current, generating a substantial power draw Emitted electrons are accelerated into the reactor shell where they generate bremsstrahlung x-rays. Thermionic Electron Emission Ion Bombardment Heating

Design Enhancements Solution: A liquid cooled ion accelerating grid remains cool at high operating power, allowing increased plasma density and higher operating efficiency by eliminating thermionic electron emission. Cooled Grid Assembly Low operating temperature to reduce thermionic electron emission current. High voltage bias (-50kV) Three ring grid fabricated from 1/16” OD stainless steel tube Non-conductive Fluorinert coolant High flow rate (1ml/s at 80 PSI) Ceramic cooling system isolation Vacuum compatible alumina ceramic feedthroughs Cooled Grid

Cooled Grid Design Ion Accelerating Grid Grid Design

Grid Cooling System Grid Cooling System Fluorinert Chiller Primary cooling loop radiator removes heat from water Water cooled Fluorinert chiller assembly Thermoelectric chiller assembly allows compact, high performance cooling of grid Fluorinert grid cooling loop Grid Cooling System Fluorinert Chiller

Reactor Operation Deuterium Plasma: 13kV, 5mA, 16mTorr Reactor Operational Deuterium fusion detected via neutron generation Cooled grid remains below 45C at 155W drive power. Grid serves as diagnostic tool to determine fraction of drive power dissipated into grid heating Deuterium Plasma: 13kV, 5mA, 16mTorr

Grid Data: H vs. P

Grid Data: H/P vs. Z

Grid Data: Z vs. P

Future Work ECRF Ion Injector Design ECRF Ion Injector Assembly ECRF Injector System RF drive system operational, Injector system in testing RF ionization of X-mode electron cyclotron resonance at 880MHz Provides low pressure stability Increases plasma density and energy while reducing ion-grid collisions ECRF Ion Injector Design ECRF Ion Injector Assembly

Questions? Results and design documentation posted at: www.rtftechnologies.org