9th IWoRiD: Erlangen,July 2007, John Vallerga High resolution UV, Alpha and Neutron Imaging with the Timepix CMOS readout J. Vallerga, J. McPhate, A. Tremsin.

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Presentation transcript:

9th IWoRiD: Erlangen,July 2007, John Vallerga High resolution UV, Alpha and Neutron Imaging with the Timepix CMOS readout J. Vallerga, J. McPhate, A. Tremsin and O. Siegmund Space Sciences Laboratory University of California, Berkeley

9th IWoRiD: Erlangen,July 2007, John Vallerga Desire for better detector spatial resolution Optics cannot always solve problem –Limits on physical size of detector is often fixed e.g. Space-based imaging (mass, optical focal length) –Projection length where optics don’t work Make pixels smaller rather than detector bigger Ultimate limit is size of interaction region of radiation of interest

9th IWoRiD: Erlangen,July 2007, John Vallerga Imaging, Microchannel Plate Detectors Photocathode converts photon to electron MCP(s) amplify electron by 10 4 to 10 8 Rear field accelerates electrons to anode Patterned anode measures charge centroid MCPneutronelectron alpha

9th IWoRiD: Erlangen,July 2007, John Vallerga Medipix/Timepix ASIC readout 256 x 256 array of 55 µm pixels 100 kHz/pxl Frame rate: 1 kHz Low noise (<100e - ) = low gain operation (10 ke - ) ~1 W watt/chip, abuttable Developed at CERN

9th IWoRiD: Erlangen,July 2007, John Vallerga “Time over Threshold” = ADC Clock Thresh.

9th IWoRiD: Erlangen,July 2007, John Vallerga Timepix version of Medipix Amplitude rather than counts using “time over threshold’ technique If charge clouds are large, can determine centroid to sub- pixel accuracy Tradeoff is count rate as event collisions in frame can destroy centroid information Single UV photon events

9th IWoRiD: Erlangen,July 2007, John Vallerga Centroiding Algorithm For each Frame  Find local event peaks in 3x3 “boxcar” smoothed image For each event  Calculate simple 5x5 “center of gravity”  Threshold on event sum and size  Apply distortion correction  Histogram centroids into high resolution 2D image

9th IWoRiD: Erlangen,July 2007, John Vallerga Original Medipix mode readout 256 x 256 (14 mm) UV image limited by 55  m pixel

9th IWoRiD: Erlangen,July 2007, John Vallerga Zoomed UV image of pattern in Medipix mode Pattern 3-2 (= 9 lp/mm) barely resolved

9th IWoRiD: Erlangen,July 2007, John Vallerga Timepix centroided mode Factor of 8 improved resolution! 256 x 256 converted to 8192x8192 pixels (1.7µm pixels)

9th IWoRiD: Erlangen,July 2007, John Vallerga Current Implementation Installed as a plugin in Pixelman software Designed to be computationally fast for later use in FPGA at kHz frame rates events per frame Muros board at ~20 frames/sec 50k to 200k frames into 1 image (4096x4096, 1.7µm pixels)

9th IWoRiD: Erlangen,July 2007, John Vallerga Zoomed 5-6 pattern resolved = 57 lp/mm Linewidth = 8.8 µm 5-6 The MCP pore spacing of 8µm limits further improvement

9th IWoRiD: Erlangen,July 2007, John Vallerga MCP pores (10 on 12 micron) For better resolution see R. Bellazzini’s poster 11.16

9th IWoRiD: Erlangen,July 2007, John Vallerga Sub-pixel distortion There is a well understood distortion in the calculated centroid vs. the true centroid due to windowed sampling –Function of distribution size and sampling parameters –“Pulls” events towards center of 55 µm pixel –Distortion repeats for every pixel If event sizes are uniform, it can be corrected by a histogram equalization technique and applied as a simple look-up table

9th IWoRiD: Erlangen,July 2007, John Vallerga Modeled distortion for Gaussian

9th IWoRiD: Erlangen,July 2007, John Vallerga Distortion (cont.) Distribution of sub-pixel locations across a single pixel Use a histogram equalization technique to redistribute events uniformly across pixel

9th IWoRiD: Erlangen,July 2007, John Vallerga Distortion corrected Distribution of corrected sub-pixel locations across a single pixel

9th IWoRiD: Erlangen,July 2007, John Vallerga High resolution particle imaging This technique can improve particle imaging as long as the initial interaction length is smaller than a pixel and there is a mechanism to spread the collected charge to many pixels –Neutrons in 10 B or Gd MCPs –Alphas in Si or MCPs –Electrons (< 50 keV?) in MCPs –Soft x-rays in MCPs (< 10 keV?)

9th IWoRiD: Erlangen,July 2007, John Vallerga Neutron MCPs ( 10 B or Gd doped) Absorption of Neutron Secondary(s) reach surface of pore Emission of photoelectron Electron gain above electronic threshold Similar to UV resolution

9th IWoRiD: Erlangen,July 2007, John Vallerga Portable MCP vacuum housing

9th IWoRiD: Erlangen,July 2007, John Vallerga Neutron detected with 10 B doped MCP McClellan nuclear rad. facility Thermal neutrons Very high gamma bkgd. Laser drilled Gd. mask

9th IWoRiD: Erlangen,July 2007, John Vallerga Zoom - Neutron events Holes approx. 60 microns

9th IWoRiD: Erlangen,July 2007, John Vallerga Zoom - UV through same mask

9th IWoRiD: Erlangen,July 2007, John Vallerga Best resolution of neutrons

9th IWoRiD: Erlangen,July 2007, John Vallerga Alpha imaging using Timepix/Si Ni mask Si Diffuse 241 Am

9th IWoRiD: Erlangen,July 2007, John Vallerga Centroiding large events with Silicon/Timepix 241 Am Alphas (5MeV) through 10  m holes on 500  m centers < 18 micron FWHM

9th IWoRiD: Erlangen,July 2007, John Vallerga Future work Integrate centroiding into PRIAM board (ESRF Grenoble) to get kHz framerates - factor of 50! Collision detection algorithm to reject miss- analyzed events Correct for pixel to pixel gain variations in TOT mode (necessary?) Optimize charge cloud size for resolution vs. rate

9th IWoRiD: Erlangen,July 2007, John Vallerga Summary Timepix TOT mode allows us to improve spatial resolution of MCP readout by order of magnitude Very robust to variations of Timepix settings, non- linearities, and non-uniformities Global ct. rate limited by event collision avoidance. –Counts/frame x Frames/sec ~ 200 kHz –Local rate < 10% of frame rate. ~ 100 Hz Excellent for photon-starved astronomical applications (UV to x-ray) Biological Imaging? Neutron imaging? Electron imaging?

9th IWoRiD: Erlangen,July 2007, John Vallerga Acknowledgements This work was funded by an AODP grant managed by NOAO and funded by the NSF The boron sensitive MCPs were loaned to us by Bruce Feller at Nova Scientific (Sturbridge Mass.) We would also like to thank the Medipix2 Collaboration

9th IWoRiD: Erlangen,July 2007, John Vallerga X-ray QE of CsI photocathode