3D-Printed mm-Wave Lenses for DNP Target System

Slides:

Advertisements

Similar presentations

John D. Williams, Wanjun Wang Dept. of Mechanical Engineering Louisiana State University 2508 CEBA Baton Rouge, LA Producing Ultra High Aspect Ratio.

Advertisements

Chapter2: Light and EM Spectrum 18.1 The Electromagnetic Spectrum 18.2 Interference, Diffraction, and Polarization 18.3 Special Relativity Professor Mohammad.

Fiber-Optic Communications

8.1 PRODUCTION AND CHARACTERISTICS OF X-RAYS

Rapid prototyping is a computer program that constructs three-dimensional models of work derived from a Computer Aided Design (CAD) drawing. With the use.

Lecture 4 Photolithography.

NMR Background Curve Fitting Caitlyn Meditz, on behalf of the Nuclear and Particle Physics Group. Advisor K. Slifer, E. Long Overview Dynamic Nuclear Polarization.

Solid Polarized Target Opportunities at JLab Possibilities for Future Experiments.

Laser Beam Machining Done By: Murad.

The HERMES Dual-Radiator Ring Imaging Cerenkov Detector N.Akopov et al., Nucl. Instrum. Meth. A479 (2002) 511 Shibata Lab 11R50047 Jennifer Newsham YSEP.

B. Spatial coherancy & source size Spetial coherancy is related to the size of the source. Source size governs spatial coherancy and maller source sizes.

Designing for 3D Printers PART 1: KNOW YOUR PRINTER.

Ekaterina Dikarov (Suhovoy ) Development of high sensitivity, high resolution ESR and its applications for studying solar cells.

An attempt toward dynamic nuclear polarization for liquid 3 He 1. Motivation of the study 2 ． Polarizing 3 He in dense form 3. DNP for liquid He3 3 ． Doping.

Y. Kisselev PST05 conference Nov 05 1 PST05 Conference Microwave cavity for large COMPASS polarized target By: Y. Kisselev, J. Ball, G. Baum, N.

A NON LINEAR TRANSPORT LINE FOR THE OPTIMIZATION OF F18 PRODUCTION BY THE TOP LINAC INJECTOR C. Ronsivalle, L. Picardi, C. Cianfarani, G. Messina, G.L.

Hard X and Gamma-ray Polarization: the ultimate dimension (ESA Cosmic Vision ) or the Compton Scattering polarimetery challenges Ezio Caroli,

Polarized Proton Solid Target for RI beam experiments M. Hatano University of Tokyo H. Sakai University of Tokyo T. Uesaka CNS, University of Tokyo S.

Elena Long Joint Hall A/C Collaboration Meeting Jefferson Lab June 6 th, /06/2014Joint Hall A/C Collaboration MeetingElena Long.

Divergent Illumination Optical Testing Device M. Fried 1, Z. Horváth 2, G. Juhász 1, O. Polgár 1, T. Mosoni 1, P. Petrik 1 1 Research Institute for Technical.

Parameter to be measured Proposed Diagnostic System Critical Components Relevant Radiation fields Potential radiation effects Li temperatureIR camera Lens20-50.

BNL E951 BEAM WINDOW EXPERIENCE Nicholas Simos, PhD, PE Neutrino Working Group Brookhaven National Laboratory.

Analysis of the Ammonia Target Polarization Kangkang L. Kovacs, Physics Department, University of Virginia, Charlottesville, VA

Unit 12: Part 1 Physical Optics: The Wave Nature of Light.

Sponsor: Carrier Corporation Advisor: Dr. H. El-Mounayri May 3, 2007 Design Team: Mike Abel Braden Duffin Simon Marin Joe McGuire.

Electromagnetic Waves

Quantification of Chromatic Aberration In the Laser-Heated Diamond Anvil Cell Emily England, Wes Clary, Daniel Reaman, Wendy Panero School of Earth Sciences,

CONSTRUCTION AND TEST OF A TRANSVERSE SUPERCONDUCTING HOLDING MAGNET 15th CB Meeting Mainz March 8th, 2010 Henry G. Ortega Spina.

Recent Developments in Polarized Solid Targets H. Dutz, S. Goertz Physics Institute, University Bonn J. Heckmann, C. Hess, W. Meyer, E. Radke, G. Reicherz.

STATUS OF PREPARATION OF dp-ELASTIC SCATTERING STUDY AT THE EXTRACTED BEAM OF NUCLOTRON. Yu.V.Gurchin LHE JINR September 2009.

Custom Prototyping for Lighting Applications

Microwave Cooking Modeling Heat and moisture transport Andriy Rychahivskyy.

Neutron measurement with nuclear emulsion Mitsu KIMURA 27th Feb 2013.

DNP for polarizing liquid 3 He DNP for polarizing liquid 3 He Akira Tanaka Department of Physics For Yamagata University PT group.

DNP for polarizing liquid 3 He DNP for polarizing liquid 3 He Hideaki Uematsu Department of Physics Yamagata University.

17th Crystal Ball Meeting

Mr. Jackson  Light is an EM wave (not requiring a medium)  EM waves are produced by radiation which is the transfer of energy in the form of.

DNP for polarizing liquid 3 He DNP for polarizing liquid 3 He Hideaki Uematsu Department of Physics For Yamagata University PT group.

Double spin asymmetry measurement from SANE-HMS data at Jefferson Lab Hoyoung Kang For SANE collaboration Seoul National University DIS /04/23.

Beam Profile Monitor for Spot-Scanning System Yoshimasa YUASA.

NMR Using a Halbach Array Michael Dillman, on behalf of the Nuclear and Particle Physics Group. Advisor K. Slifer, E. Long Motivation : Nuclear Magnetic.

Light and Optics  The Electromagnetic Spectrum  Interference, Diffraction, and Polarization Wave Properties of Light.

Where is the change in refractive index of the glass, and is the change in temperature due to heating. The relative phase change due to asymetric heating.

All-Dielectric Metamaterials: A Platform for Strong Light-Matter Interactions Jianfa Zhang* （College of Optoelectronic Science and Engineering, National.

Spin Tracking at the ILC Positron Source with PPS-Sim POSIPOL’11 V.Kovalenko POSIPOL’11 V. Kovalenko 1, G. Moortgat-Pick 1, S. Riemann 2, A. Ushakov 1.

CLAS12 Longitudinally Polarized Target R&D Update CLAS Collaboration, October 20, 2015 Chris Keith.

Date of download: 9/19/2016 Copyright © 2016 SPIE. All rights reserved. Schematics of the 3-D printed probe for tissue collagen differentiation. (a) The.

Diagnostic Radiology II X-ray Tubes. Anode angle Anode angle defined as the angle of the target surface with respect to the central ray in the x-ray field.

Designing for Rapid Prototyping

By ASST. Prof. DR. ASEEL BASIM

3D printed Luneburg lens antenna for millimeter wave system Min Liang and Hao Xin Electrical and Computer Engineering Department, University of Arizona,

Solid Freeform Fabrication Symposium 2012

Light-Matter Interaction

Diagnosing kappa distribution in the solar corona with the polarized microwave gyroresonance radiation Alexey A. Kuznetsov1, Gregory D. Fleishman2 1Institute.

Investigation of Flow in a Model of Human Respiratory Tract

The Frascati Neutron Generator

Wakefield Accelerator

Polarized solid Targets for AFTER

Factors Effecting the Production

Origin of The Electromagnetic (EM) Waves

Ω Ω Understanding Thermometry at Low Temperature Abstract Background

Computer Numerical Control

Why Do CPO Lead to Slow Light When the Laser

Chapter 17, Section 1 and 2: Nature of Electromagnetic Waves

Irradiation of Polarized Target Materials

Solidification of Ammonia for Polarized Targets

Computed Tomography (C.T)

Volume 91, Issue 4, Pages (August 2006)

Presentation transcript:

3D-Printed mm-Wave Lenses for DNP Target System Kellie McGuire Advisor: Prof. Elena Long University of New Hampshire Physics Background The University of New Hampshire’s Long Lab1 is at the forefront of 3D-printing technology, developing new techniques and materials for nuclear physics experiments. Included in this work is a method of 3D-printing with the fluoroplastics FEP and PCTFE (Kel-F®). This technology is being used to manufacture mm-wave lenses for a dynamic nuclear polarization (DNP) target system. In DNP, a target material doped with free radicals is placed in a strong magnetic field and exposed to mm-wave radiation, inducing electron-to-nucleon spin transfer. 3D-printed lenses will be used to evenly distribute the mm-wave radiation and thus drive up the degree of nucleon spin polarization. This work is part of the UNH Nuclear Physics Group’s tensor-polarized target project.2 To date, deuteron polarization of 15-20% has been achieved,3 and it is a central goal of the group to increase this to > 30%. 3D-Printing with Fluoroplastics FEP and PCTFE are challenging materials to use in 3D-printing: Higher processing temperature (380 °C and 360 °C, respectively) than conventional materials, such as PLA (230 °C) and ABS (280 °C). Low viscosity and self-lubricating; materials will not adhere directly to the print bed. Must print at a much slower speed than conventional materials. FEP filament is soft; trouble feeding through printer nozzle. Small temperature window in which PCTFE can be processed. Work must be performed in a fume hood to minimize exposure to HF and HCl. PCTFE printing on a Prusa i3 MK2.5 printer. The beam is imaged through the PCTFE components using a custom 3D-printed absorption screen. The absorption screen features thermally isolated “pixels” to minimize heat spread. The intensity of the beam is observed in the color gradient of a liquid crystal sheet. Printer filament is made in-house, using a custom device, the “Filatizer.” The material tends to develop a brown tint when exposed to heat, so it is necessary to find the right balance between temperature, speed, and processing volume to minimize exposure to heat. Extruded at 246 °C (nozzle temp.) through stainless steel 3D-printed PCTFE prism and DNP target cup. Designing mm-Wave Lenses A direct application of fluoroplastic printing is the development of PCTFE lenses to be implemented into a DNP target system. The polarizing radiation comes in the form of a 140 GHz Gaussian beam incident on the PCTFE target cups. The lenses will be designed to evenly distribute the beam to uniformly saturate the target and drive up the degree of polarization. Absorption screen showing an unobstructed mm-wave beam. Absorption screen with mm-wave beam through PCTFE target cup. Future Work While highly transparent to mm-wave radiation at short optical path lengths, PCTFE experiences considerable power loss at thicknesses > 1 mm. A critical next step will be to characterize the mm-wave power loss through PCTFE. This data will be used to determine the optimal lens thickness. Once the lenses have been optimized, they will be implemented into the DNP target cups that hold the target during polarization. Filament production system, featuring custom-built “Filatizer,” used to produce FEP (top) and PCTFE (bottom) filament. Motivation Why PCTFE? Suitable for use in dynamic nuclear polarization (DNP). PCTFE is ideal because: It retains its plasticity at 1K, the temperature at which DNP is performed. It is transparent to the microwave radiation used in DNP. It contains no free protons that could introduce noise in the NMR signal used to measure polarization. Why 3D printing? 3D printing offers several benefits over machining: Rapid prototyping. Allows for complex geometries that are difficult or impossible to machine. Less expensive; 3D printing can be done with very little waste. Illustration of mm-wave beam through DNsP target cup. Acknowledgments This research was funded through grants from the U.S. Department of Energy and the University of New Hampshire’s Hamel Center for Undergraduate Research. Unobstructed mm-wave beam features a Gaussian irradiance pattern with central “hot spot.” Illustration of an idealized mm-wave beam, showing uniform irradiance and no power loss. References www.unhlonglab.com https://nuclear.unh.edu/ 3. W. Meyer, et al., Nucl. Instr. Meth. A 244, 574 (1986). The lenses can be printed with a layer thickness of < 0.1 mm, suitable for use with 140 GHz (2 mm) radiation. Measurements using a 3D-printed PCTFE prism at 140 GHz yield an index of refraction consistent with that of solid PCTFE at 1 MHz. Iterations of 3D-printed PCTFE target cup. 2019 CUWiP at UMass Amherst