-- RamonaValenzuelaPerez - 2013-04-13
Our instrument, or diagnostic, will allow us to study plasma instabilities. Our research will contribute to worldwide efforts in better understanding plasmas to control instabilities which can deteriorate fusion plasma performance. Plasma performance is a concern because stable plasmas are necessary to create commercially viable fusion energy.
Spherical tokamaks are machines that can create and confine a plasma to sustain the nuclear fusion reactions we want to study with our instrument. However because these machines are too large and expensive to build with a small group of people, working with plasmas to study fusion can be a highly collaborative effort. Though we design, develop, and bench test our instruments at FIU, we will be collecting our data offsite at a spherical tokamak in England.
We are currently designing a four channel prototype instrument (an array of four detectors) to determine the time dependent charged fusion product profile of a spherical tokamak. In general, we want to know where and when charged particles from fusion reactions are created inside of a fusion plasma. We will look for protons and tritons (isotopes of hydrogen) which are products from fusion reactions between deuterium (another hydrogen isotope).
Principal Investigator (PI): 
ABOVE LEFT: Werner next to the Mega Amp Spherical Tokamak (MAST) RIGHT: Ramona next to MAST
ABOVE LEFT: Pierre, our collaborator Bob Kaita (PPPL), Carlos RIGHT: Carlos, Omar, Pierre, our collaborator Doug Darrow (PPPL)
ABOVE: Daniel Andruczyk (PPPL), our collaborator Lane Roquemore (PPPL), Pierre, Omar, and Carlos
Research Facilities: 
LEFT: Ultra High Vacuum system for bench testing RIGHT: Stainless steel housing unit for detectors (for diagnostic to be installed in MAST)
3-D reconstruction of dust particle trajectories in the NSTX 
LEFT AND RIGHT: Images of 3D cad drawings for detector housing/ probe head with the ability to change detector orientations
FIU Experimental Plasma Physics Group (FEPP)
Current Project
Our instrument, or diagnostic, will allow us to study plasma instabilities. Our research will contribute to worldwide efforts in better understanding plasmas to control instabilities which can deteriorate fusion plasma performance. Plasma performance is a concern because stable plasmas are necessary to create commercially viable fusion energy.
Spherical tokamaks are machines that can create and confine a plasma to sustain the nuclear fusion reactions we want to study with our instrument. However because these machines are too large and expensive to build with a small group of people, working with plasmas to study fusion can be a highly collaborative effort. Though we design, develop, and bench test our instruments at FIU, we will be collecting our data offsite at a spherical tokamak in England.
We are currently designing a four channel prototype instrument (an array of four detectors) to determine the time dependent charged fusion product profile of a spherical tokamak. In general, we want to know where and when charged particles from fusion reactions are created inside of a fusion plasma. We will look for protons and tritons (isotopes of hydrogen) which are products from fusion reactions between deuterium (another hydrogen isotope).
- Please visit our TWiki page for our Charged Fusion Products Diagnostic, also called the Proton Detector:
- More information:
FIU Group Members
Principal Investigator (PI): - Werner Boeglin
- Ramona V Perez
- Adrianna Angulo
- Carlos Lopez
- Omar Leon
- Pierre Avila
- Rahul Patel
- Princeton Plasma Physics Laboratory (PPPL) located in Princeton, New Jersey
- Culham Science Centre, Culham Centre for Fusion Energy (CCFE) located in Culham, Oxfordshire, England
ABOVE LEFT: Werner next to the Mega Amp Spherical Tokamak (MAST) RIGHT: Ramona next to MAST
ABOVE LEFT: Pierre, our collaborator Bob Kaita (PPPL), Carlos RIGHT: Carlos, Omar, Pierre, our collaborator Doug Darrow (PPPL)
ABOVE: Daniel Andruczyk (PPPL), our collaborator Lane Roquemore (PPPL), Pierre, Omar, and Carlos
Research Opportunities
Research Facilities: - FIU Physics Laboratory CP185
- National Spherical Torus Experiment (NSTX) at the PPPL http://nstx.pppl.gov/overview.html
- National Spherical Torus Experiment Upgrade (NSTX-U) at the PPPL (upgrade not yet completed)
- Mega Amp Spherical Tokamak (MAST) at the CCFE http://www.ccfe.ac.uk/MAST.aspx
- Independent Study credits
- Undergraduate Research Experience
- Read about what our undergraduate researchers are doing
- M.S. and Ph.D opportunities (speak with Dr. Werner Boeglin http://physics.fiu.edu/faculty/)
- Read about what our graduate student is doing
- What kind of research experience can you gain working in FEPP?
LEFT: Ultra High Vacuum system for bench testing RIGHT: Stainless steel housing unit for detectors (for diagnostic to be installed in MAST)
Past Projects
3-D reconstruction of dust particle trajectories in the NSTX - http://www.astro.sunysb.edu/rpatel/files/Rahul%20Patel%20McNair%20Poster.pdf
- http://www.astro.sunysb.edu/rpatel/files/sdarticle.pdf
- http://phy.fiu.edu/twiki/pub/Main/DesignReview/Design_Review_Apr_2011.pdf
- http://phy.fiu.edu/twiki/pub/Main/DesignReview/Design_Details_Apr_2011_1.pdf
- http://phy.fiu.edu/twiki/bin/view/TWiki/NSTX_Diagnositc
LEFT AND RIGHT: Images of 3D cad drawings for detector housing/ probe head with the ability to change detector orientations
- FEPP7.jpg:
Topic revision: r11 - 2013-08-25 - lc_2eramona
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