1 FNAL Pixel R&D Status R. Lipton Brief overview due to 3 failed MS Powerpoint versions –3D electronics New technologies for vertical integration of electronics.

Slides:



Advertisements
Similar presentations
Radiation damage in silicon sensors
Advertisements

MonolithIC 3D Inc., Patents Pending MonolithIC 3D ICs RCAT Flow 1 MonolithIC 3D Inc., Patents Pending.
ASIC and Sensor R&D Electronics and sensor technology is central to Particle Physics research Technology is moving very quickly – sensor arrays of unprecedented.
CHARGE COUPLING TRUE CDS PIXEL PROCESSING True CDS CMOS pixel noise data 2.8 e- CMOS photon transfer.
MonolithIC 3D  Inc. Patents Pending 1 The Monolithic 3D-IC A Disruptor to the Semiconductor Industry.
SOIPD Status e prospective for 2012 The SOImager2 is a monolithic pixel sensor produced by OKI in the 0.20 µm Fully Depleted- Silicon On Insulator (FD-SOI)
Snowmass 2005 SOI detector R&D Massimo Caccia, Antonio Bulgheroni Univ. dell’Insubria / INFN Milano (Italy) M. Jastrzab, M. Koziel, W. Kucewicz, H. Niemiec.
Ronald Lipton Hiroshima D Sensors - Vertical Integration of Detectors and Electronics Contents: Introduction to three dimensional integration of.
Progress of SOI Pixel Detectors Sep. 9, Yasuo Arai, KEK 1.
20th RD50 Workshop (Bari)1 G. PellegriniInstituto de Microelectrónica de Barcelona G. Pellegrini, C. Fleta, M. Lozano, D. Quirion, Ivan Vila, F. Muñoz.
Status and outlook of the Medipix3 TSV project
3D chip and sensor Status of the VICTOR chip and associated sensor Bonding and interconnect of chip and sensor Input on sensor design and interconnection.
TRAPPISTE Tracking Particles for Physics Instrumentation in SOI Technology Prof. Eduardo Cortina, Lawrence Soung Yee Institut de recherche en mathématique.
Charge collection studies on heavily diodes from RD50 multiplication run G. Kramberger, V. Cindro, I. Mandić, M. Mikuž Ϯ, M. Milovanović, M. Zavrtanik.
Ronald Lipton, ACES March 4, Application of Vertically Integrated Electronics and Sensors (3D) to Track Triggers Contents Overview of 3D Fermilab.
MonolithIC 3D Inc., Patents Pending MonolithIC 3D ICs RCAT approach 1 MonolithIC 3D Inc., Patents Pending.
3D Vertex Detector Status The requirement for complex functionality in a small pixel led us to investigate vertically integrated (3D) processes. Developed.
Vertexing for SID status N. B. Sinev University of Oregon, Eugene 1 April 23, 2015,A LCW2015, Japan Nick Sinev.
Fabian Hügging – University of Bonn – February WP3: Post processing and 3D Interconnection M. Barbero, L. Gonella, F. Hügging, H. Krüger and.
8/22/01Marina Artuso - Pixel Sensor Meeting - Aug Sensor R&D at Syracuse University Marina Artuso Chaouki Boulahouache Brian Gantz Paul Gelling.
Pierpaolo Valerio.  CLICpix is a hybrid pixel detector to be used as the CLIC vertex detector  Main features: ◦ small pixel pitch (25 μm), ◦ Simultaneous.
Silicon – On - Insulator (SOI). SOI is a very attractive technology for large volume integrated circuit production and is particularly good for low –
ECFA ILC Workshop, November 2005, ViennaLadislav Andricek, MPI für Physik, HLL DEPFET Project Status - in Summary Technology development thinning technology.
Medipix sensors included in MP wafers 2 To achieve good spatial resolution through efficient charge collection: Produced by Micron Semiconductor on n-in-p.
1 Digital Active Pixel Array (DAPA) for Vertex and Tracking Silicon Systems PROJECT G.Bashindzhagyan 1, N.Korotkova 1, R.Roeder 2, Chr.Schmidt 3, N.Sinev.
CMS Phase 2 Tracker R&D R. Lipton 3/27/2014 Module R&D Allocation: Requested ~ $320k, received ~160k – Eliminate VICTR testing (continue with FNAL funds.
SOI pixel detector technology US-Japan collaboration Farah Khalid on behalf of ASIC Development Group SOIPIX collaboration people involved in SOIPIX: G.Deptuch,
Montpellier, November 12, 2003Vaclav Vrba, Institute of Physics, AS CR 1 Vaclav Vrba Institute of Physics, AS CR, Prague CALICE ECal Status Report.
Fully depleted MAPS: Pegasus and MIMOSA 33 Maciej Kachel, Wojciech Duliński PICSEL group, IPHC Strasbourg 1 For low energy X-ray applications.
Phase 2 Tracker R&D Background: Initial work was in the context of the long barrel on local tracklet- based designs. designs of support structures and.
Module Development Plan I believe that we are ready to proceed to a program to demonstrate a PS module based on “2.5 D” interconnections. This is based.
VIP1: a 3D Integrated Circuit for Pixel Applications in High Energy Physics Jim Hoff*, Grzegorz Deptuch, Tom Zimmerman, Ray Yarema - Fermilab *
Foundry Characteristics
MIT Lincoln Laboratory NU Status-1 JAB 11/20/2015 Advanced Photodiode Development 7 April, 2000 James A. Burns ll.mit.edu.
ILC VXD Review, Fermilab, October 23, 2007 Hans-Günther Moser, MPI für Physik DEPFET Devices Hans-Gunther Moser for the DEPFET Collaboration (
Phase 2 Tracker R&D Background: Initial work was in the context of the long barrel on local tracklet- based designs. designs of support structures and.
Thin Silicon R&D for LC applications D. Bortoletto Purdue University Status report Hybrid Pixel Detectors for LC.
Low Resistance Strip Sensors – RD50 Common Project – RD50/ CNM (Barcelona), SCIPP (Santa Cruz), IFIC (Valencia) Contact person: Miguel Ullán.
CERN, November 2005 Claudio Piemonte RD50 workshop Claudio Piemonte a, Maurizio Boscardin a, Alberto Pozza a, Sabina Ronchin a, Nicola Zorzi a, Gian-Franco.
Update on Simulation and Sensor procurement for CLICPix prototypes Mathieu Benoit.
MonolithIC 3D Inc., Patents Pending MonolithIC 3D ICs November MonolithIC 3D Inc., Patents Pending.
Technology Overview or Challenges of Future High Energy Particle Detection Tomasz Hemperek
RD50 funding request Fabrication and testing of new AC coupled 3D stripixel detectors G. Pellegrini - CNM Barcelona Z. Li – BNL C. Garcia – IFIC R. Bates.
Special Focus Session On CMOS MAPS and 3D Silicon R. Yarema On Behalf of Fermilab Pixel Development Group.
Radiation hardness of Monolithic Active Pixel Sensors (MAPS)
Phase 2 Tracker Meeting 6/19/2014 Ron Lipton
Giulio Pellegrini 27th RD50 Workshop (CERN) 2-4 December 2015 Centro Nacional de MicroelectrónicaInstituto de Microelectrónica de Barcelona 1 Status of.
Simulation of new P-Type strip detectors 17th RD50 Workshop, CERN, Geneva 1/15 Centro Nacional de MicroelectrónicaInstituto de Microelectrónica de Barcelona.
Claudio Piemonte Firenze, oct RESMDD 04 Simulation, design, and manufacturing tests of single-type column 3D silicon detectors Claudio Piemonte.
Ideas for a new INFN experiment on instrumentation for photon science and hadrontherapy applications – BG/PV group L. Ratti Università degli Studi di Pavia.
Development of SOI pixel sensor 28 Sep., 2006 Hirokazu Ishino (Tokyo Institute of Technology) for SOIPIX group.
Selcuk Cihangir, Fermilab LCWS 2007, DESY 1 SOI, 3D and Laser Annealing for ILC S.Cihangir-Fermilab Representing Contributors from: Fermilab, Bergamo,
Pixel Meeting Nov 7, Status Update on Sensors and 3D Introduction Laser Annealed HPK sensors MIT-LL thinned sensors SOI devices –OKI –ASI 3D assembly.
Low Mass, Radiation Hard Vertex Detectors R. Lipton, Fermilab Future experiments will require pixelated vertex detectors with radiation hardness superior.
Andrei Nomerotski 1 Andrei Nomerotski, University of Oxford for LCFI collaboration LCWS2008, 17 November 2008 Column Parallel CCD and Raw Charge Storage.
Revolutions in Semiconductor Detectors R. Lipton (Fermilab) You probably don’t have to be told that we have been living in an age which has seen revolutionary.
Andrei Nomerotski 1 Andrei Nomerotski, University of Oxford Ringberg Workshop, 8 April 2008 Pixels with Internal Storage: ISIS by LCFI.
Dear Colleagues, In agreement with the CMS Upgrade Managers, the Tracker will hold a review of R&D activities related to outer tracker modules on.
Fully Depleted Low Power CMOS Detectors
New Mask and vendor for 3D detectors
10-12 April 2013, INFN-LNF, Frascati, Italy
Thinning and Plans for SuperBelle
Preliminary results from 3D CMS Pixel Detectors
L. Rattia for the VIPIX collaboration
Highlights of Atlas Upgrade Week, March 2011
Thin Planar Sensors for Future High-Luminosity-LHC Upgrades
Hexagons and 8” Sensor R&D Ron Lipton
Status of SOI Pixel Development
BONDING The construction of any complicated mechanical device requires not only the machining of individual components but also the assembly of components.
Presentation transcript:

1 FNAL Pixel R&D Status R. Lipton Brief overview due to 3 failed MS Powerpoint versions –3D electronics New technologies for vertical integration of electronics and sensors –Detector thinning after topside processing Thinning processes Laser annealing Handling and assembly –Silicon-on-Insulator Monolithic pixel detectors Technology R&D

2 VIP 3D Chip –Chip received in November –Needed FIB repair to bias analog test structures –These structures look good - gain, noise similar to simulation –Some work on one chip and not another – yield issue? –Beginning to work on full chip readout. –Plan for 2 nd DARPA run

Ronald Lipton 3 Future and Current 3D Work 3rd DARPA run expected next year Considering dedicated HEP MIT-LL multiproject run –Exploring interest, funding and technical options –Radiation hard BOX available (receiving test structures) Reduce costs for R&D –Two circuit tiers –Sensor on SOI handle –Use results from 2 DARPA runs and test structure measurements CuSn structures with RTI DBI demonstration with BTeV chips and MIT-LL sensors –Thin bonded chip-sensor pairs –Potentially most radiation hard process DARPA sponsored run with Tezzaron – 0.13 micron two tier commercial process

Ronald Lipton 4 Direct Bond Interconnect (DBI) Particularly interesting as a replacement for bump bonding –Robust mechanical connection - can be ground and thinned –Achieved 8 micron pitch PO stalled due to budget cuts.

Ronald Lipton CMS Workshop Nov 28, Edgeless Thinned Detector Concept Equipotential lines in detector near one detector edge Detector Cross section near one detector edge Deep trench etching used in 3D vias can be used as a high quality detector edge (same as 3D detectors) This edge can be used as a detector electrode - eliminating edge losses in tiling reticle-sized detectors –We have produced a set of detectors at MIT-LL thinned to 50 and100 microns –Need to thin and backside process Trench on detector edge filled with poly and connected to bottom implant Diode implants Trench Trenched 3D sensor From MIT-LL Implant with laser annealing Trench filled with Doped polysilicon

Ronald Lipton 6 Initial 6” wafer p+ pixel implants Deep trench etch, n poly fill Anneal, diffuse dopants Attach top pyrex handle (UV release adhesive) Thin, implant, laser anneal Detector Process Remove top handle Issues: How to hold wafer during backside thinning, implantation, anneal How to handle wafer once thinned to microns Commercial processes: Rim thinning Handle wafers Silicon with epoxy Thermal release adhesive UV release adhesive with glass handle

Ronald Lipton 7 Thinning and Laser Annealing Initial thinning – designed to avoid contamination in MIT-LL implanter failed –50  m trenched dummy silicon wafer on pyrex cracked curing epoxy removal –Used shards to study handling. We were able to removed the silicon from the pyrex to dicing tape, dice and then remove the diced detector Use this to study bonding, gluing … New study using Micron 6” donated wafers –More standard process – no epoxy, implantation at commercal firm –Stuck at grinding vendor due to argument with CMP subcontractor –Verify process soon – MIT LL will laser anneal If this works we will thin the MIT-LL wafers, and also thin and anneal one OKI SOI detector wafer. Laser annealing study with thinned HPK strip detectors almost done –Generally good results but some variation in IV characteristics with “identical” processing –Cornell student completing dedicated study of annealing parameters

Serial Powering Chip designed in collaboration with RAL/ATLAS –Demonstration of rad rad chip with pulsed power features –Bump bonded interconnects –Hope to submit in ~ 2 months old design Ronald Lipton 8

9 SOI Detector for HEP Backside implanted after thinning Before frontside wafer processing Or laser annealed after processing High resistivity Silicon wafer, Thinned to microns Active edge processing Minimal interconnects, low node capacitance not to scale

Ronald Lipton 10 Fermilab SOI Detector Activities SOI detector development is being pursued by Fermilab at three different foundries:OKI in Japan (via KEK), and American Semiconductor Inc. (ASI) and MIT Lincoln Labs in the US. OKIMIT-LLASI Feature size (  m) Wafer Diameter 150mm 200mm Transistor type Fully depleted Fully depleted Partially depleted dual gate Buried Oxide200 nm400 nm200 nm Work underway Test Structures Mambo chip Laser anneal Mambo II Test Structures 3D chip 3D RunII 3D Dedicated SBIR design Simulation Test Structures Sensor SBIR

Ronald Lipton 11 MAMBO - Monolithic Active pixel Matrix with Binary cOunters in SOI Technology OKI 0.15µm KEK sponsored multiproject run at OKI. 64 x micron pitch 12 bit counter array for a high dynamic range x-ray or electron microscope input charge ~1250 e-, 80e-<ENC<100e- Back gate limited combined analog/digital performance MAMBO II to be submitted this week 0.2 micron Test pulse Discriminator out

Ronald Lipton 12 SOI Device Simulation Study charge collection, coupling, and diffusion as a function of pixel implant and pinning layer dimensions. Keep bias at 10 V to limit back gate effects. (Silvaco 3D TCAD simulations) 6.4e-165.2e e-16 No isolation 8 micron pixel pinned 4 micron pixel pinned No pinning 10V Bias 8 micron pixels n+ pinning 10V Bias 8 micron pixels 25 micron pitch 2 micron pixel - pinning gap