Difference between revisions of "NEUP DE-FOA-0000613"
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#We propose to establish the infrastructure needed for a modern instrumentation and controls laboratory that will attract and instruct students in the methods used for nuclear physics applications. The laboratory will have a classroom component used to teach students in a focused approach and an application component where the students will apply the techniques in the problem solving environment of a research facility. | #We propose to establish the infrastructure needed for a modern instrumentation and controls laboratory that will attract and instruct students in the methods used for nuclear physics applications. The laboratory will have a classroom component used to teach students in a focused approach and an application component where the students will apply the techniques in the problem solving environment of a research facility. | ||
#We propose to establish the infrastructure needed for a modern instrumentation and controls laboratory that will attract and instruct students in the methods used for nuclear physics applications. The laboratory will be used for hands on training of personnel with skill sets appropriate for serving the nuclear power fleet, national labs, or technology based industries for the next generation. The focus will be on real time monitors using modern digital equipment and will not focus on control systems which remain analog systems for security reasons. | #We propose to establish the infrastructure needed for a modern instrumentation and controls laboratory that will attract and instruct students in the methods used for nuclear physics applications. The laboratory will be used for hands on training of personnel with skill sets appropriate for serving the nuclear power fleet, national labs, or technology based industries for the next generation. The focus will be on real time monitors using modern digital equipment and will not focus on control systems which remain analog systems for security reasons. | ||
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| + | =Budget= | ||
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| + | $50k Target (Valeria quote) | ||
| + | $30k Enclosure (Valeria quotes) | ||
| + | $20k Monitors (Yujong) | ||
| + | |||
| + | $150k (GE neutron detectors + readout electrons) | ||
| + | |||
| + | $50k Workstation | ||
=Classroom experiments= | =Classroom experiments= | ||
Revision as of 18:16, 21 December 2011
Possible approaches
- We propose to complement a high intensity neutron source with a modern controls and instrumentation infrastructure to be used as both a user facility and a practical instruction apparatus for students in nuclear physics fields
- We propose to establish the infrastructure needed for a modern instrumentation and controls laboratory that will attract and instruct students in the methods used for nuclear physics applications. The laboratory will have a classroom component used to teach students in a focused approach and an application component where the students will apply the techniques in the problem solving environment of a research facility.
- We propose to establish the infrastructure needed for a modern instrumentation and controls laboratory that will attract and instruct students in the methods used for nuclear physics applications. The laboratory will be used for hands on training of personnel with skill sets appropriate for serving the nuclear power fleet, national labs, or technology based industries for the next generation. The focus will be on real time monitors using modern digital equipment and will not focus on control systems which remain analog systems for security reasons.
Budget
$50k Target (Valeria quote) $30k Enclosure (Valeria quotes) $20k Monitors (Yujong)
$150k (GE neutron detectors + readout electrons)
$50k Workstation
Classroom experiments
Scintillator based neutron detection
Identification of nuclei using gamma spectroscopy
HpGE
Neutron detection using ionization chambers
He-3 tubes, fission chambers
Solid state neutron detectors
Gadolinium