First
Name |
Last Name |
Affiliation |
Paper ID |
Abstract Title |
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Tuesday,
July 12: Posters |
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|
Pierre |
Bauer |
FNAL |
TuP01 |
Discussion of Possible
Evidence for Non-linear BCS Resistance in SRF Cavity Data to Model Comparison |
|
Gianluigi |
Ciovati |
TJNAF |
Tup02 |
Analysis of the Medium
Field Q-slope in Superconducting Cavities Made of Bulk Niobium |
|
Gregory |
Eremeev |
Cornell University |
TuP03 |
Change in High Field
Q-Slope by Anodizing of the Baked Cavities |
|
Melissa |
Delheusy |
CEA-Saclay / Max-Planck-Institut fur Metallforsch |
TuP04 |
In-situ investigation of
the Nb/oxygen interfaces - correlation with the properties of the Nb RF
superconducting cavities |
|
Bernard |
Visentin |
CEA-Saclay |
TuP05 |
First
Experimental Results on “Fast Baking” |
|
Jim |
Norem |
ANL |
TuP06 |
Atom-Probe Tomography
Analyses of Niobium Superconducting RF Cavity Materials |
|
David |
Swenson |
Epion Corporation |
TuP07 |
Study of gas cluster ion
beam surface treatments for mitigating RF breakdown |
|
Andy |
Wu |
TJNAF |
TuP08 |
Investigation of Oxide
Layer Structure on Nb Surfaces Using a Secondary Ion Mass Spectrometer |
|
John |
Kaufman |
Cornell University |
TuP09 |
SIMS Analysis of the
Effects of Heating on the Oxygen Content of Niobium Using the NbO/Nb Signal |
|
John |
Kaufman |
Cornell University |
TuP10 |
Surface Roughness vs Grain Size Analysis on Nb Samples |
|
Arti |
Dangwal |
University of Wuppertal |
TuP11 |
DC Field Emission
Scanning Measurements on Electropolished Niobium |
|
Lou |
Hand |
Cornell University |
TuP12 |
Use of Precision X-Ray
Diffraction, Interstitial Gas Fusion Analysis and Squid Measurements to
Investigate CVD- and Bulk- Niobium Samples |
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TuP13 |
Abstract withdrawn |
|
|
Timergali |
Khabiboulline |
FNAL |
TuP14 |
Recent results of testing
3-cell 3.9 GHz accelerating cavity at Fermilab |
|
Mandi |
Meidlinger |
MSU |
TuP15 |
Design of Half-Reentrant SRF Cavities |
|
Kailash |
Mittal |
Bhaba Atomoic Research Center |
TuP16 |
RF Design of a Single
Cell Superconducting Elliptical Cavity with Input Coupler |
|
Kailash |
Mittal |
Bhaba Atomoic Research Center |
TuP17 |
Structural Analysis of
Single Cell Superconducting Elliptical Cavity With Static Lorentz Force |
|
Kailash |
Mittal |
Bhaba Atomoic Research Center |
TuP18 |
Optimization of Wall
Thickness of Superconducting 700 MHz Bulk Niobium and Niobium Coated OFHC
Copper Cavities by Thermal/Structural Analysis |
Yuichi |
Morozumi |
KEK |
TuP19 |
Design and Analysis of 45
MV/m Superconducting Structures |
|
Takayuki |
Saeki |
KEK |
TuP20 |
Fabrication of Four
9-cell IHCIRO High-Gradient Cavities for the R&D of ILC Accelerator in
KEK |
|
Kenji |
Saito |
KEK |
TuP21 |
Mechanical Structure Analysis for ICHIRO 9-Cell Cavity |
|
Friedrich |
Staufenbiel |
FZ-Rossendorf |
TuP22 |
Field Profile Measurement of the 3½ Cell SRF Gun |
|
Friedrich |
Staufenbiel |
FZ-Rossendorf |
TuP23 |
Status of the 3½ Cell SRF Gun Project in Rossendorf |
|
An |
Sun |
ORNL |
TuP24 |
Superconducting RF Cavity
Measurement Formulae for an Exponential Decayed Pulse Incident Power |
|
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Deiego |
Tonini |
INFN - LNL |
TuP25 |
Preliminari Study of Bulk
Niobium Superconductive Photonic Bandgap Accelerating Cavity |
|
Jim |
Norem |
ANL |
TuP26 |
High Electric Fields in rf Cavities |
|
Susan |
Musser |
MSU |
TuP27 |
X-Ray Imaging of
Superconducting Radio Frequency Cavities |
|
Genfa |
Wu |
TJNAF |
TuP28 |
Multipacting analysis for JLAB ampere class cavities |
|
Paolo |
Pierini |
INFN-Milano |
TuP29 |
The Fast Piezo-Blade Tuner for SCRF Resonators |
|
Rongli |
Geng |
Cornell University |
TuP30 |
Niobium-Copper Cavity Development for Muon Collider |
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TuP31 |
see student talk TuA06 |
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Ralf |
Eichhorn |
FZ-Juelich |
TuP32 |
The summarized fndings
from the Juelich halfwave Resonators |
|
Huimin |
Gassot |
IPN Orsay |
TuP33 |
Triple-Spoke Cavity
Design Improvement for HIPPI Collaboration |
|
Ivan |
Gonin |
FNAL |
TuP34 |
Design of 325 MHz Single Spoke Resonator at FNAL |
|
Ivan |
Gonin |
FNAL |
TuP35 |
Development of the
SCRF β=0.81 cavity for Proton
Driver |
|
Robert |
Laxdal |
TRIUMF |
TuP36 |
ISAC-II QWR
Cavity Characterizations and Investigations |
|
Guillaume |
Olry |
Institut de Physique Nucleaire |
TuP37 |
Development of Beta 0.12,
88 MHz, Quarter-Wave Resonator and its Cryomodule for the SPIRAL2 Project |
|
Guillaume |
Olry |
Institut de Physique Nucleaire |
TuP38 |
Development of Spoke
Cavities for the EURISOL and EUROTRANS Projects |
|
Michael |
Pekeler |
ACCEL |
TuP39 |
Performance of a
Prototype 176 MHz beta=0.09 Half-Wave Resonator for the SARAF Linac |
|
Kenneth |
Shepard |
ANL |
TuP40 |
Development of Spoke Cavities for RIA |
|
Evgeny |
Zaplatine |
FZ-Juelich |
TuP41 |
Multiti-Spoke
Cavity End Region Analysis |
|
Evgeny |
Zaplatine |
FZ-Juelich |
TuP42 |
FZJ SC Cavity Coupled
Analyses |
|
Rongli |
Geng |
Cornell University |
TuP43 |
High-Gradient Activities at Cornell: Reentrant Cavities |
|
Kenji |
Saito |
KEK |
TuP44 |
R&D Activities for ILC High Gradient Cavity in KEK |
|
Kenji |
Saito |
KEK |
TuP45 |
Feasibility Study of ~ 50MV/m by Single Cell Cavities |
|
Joe |
Ozelis |
TJNAF |
TuP46 |
A Sapphire Loaded TE011
Cavity for Surface Impedance Measurements – Design, Construction, and
Commissioning Status |
|
Pierre |
Bauer |
FNAL |
TuP47 |
Recent RRR Measurements on Niobium for SRF Cavities |
|
Cristian |
Boffo |
FNAL |
TuP48 |
Eddy Current Scanning at Fermilab |
|
Waldemar |
Singer |
DESY |
TuP49 |
SQUID-based Scanning
System for Detecting Defects in Nb Sheets for RF Cavities |
|
William |
Frisken |
York University |
TuP50 |
Laser Annealing Experiments with Niobium |
|
Zeke |
Insepov |
ANL |
TuP51 |
Computer Simulation of
Surface Modification with Ion Beams |
|
Hairong |
Jiang |
MSU |
TuP52 |
Cold Rolling Texture
Evolution in High Purity Niobium Using a Tapered Wedge Specimen |
|
Hairong |
Jiang |
MSU |
TuP53 |
Creep and Dimensional
Stability of High Purity Niobium Electron Beam Welds |
|
Peter |
Lee |
University of Wisconsin |
TuP54 |
Grain Boundary Flux
Penetration and Resistivity in Large Grain Niobium Sheet |
|
Anatolii |
Polyanskii |
University of Wisconsin |
TuP55 |
A Magneto Optical Study
of Grain Boundary Flux Penetration in Niobium Sheet Sampled Across Simulated
Cavity Production Route |
|
Ganapati Rao |
Myneni |
TJNAF |
TuP56 |
Contaminant Analysis of
Polycrystalline and Single Crystal Niobium Used in Accelerator Cavities by
SIMS |
|
Richard |
Ricker |
NIST |
TuP57 |
Comparison of Deformation
in High-Purity Single/Large Grain and Polycrystalline Niobium Superconducting
Cavities |
|
Xenia |
Singer |
DESY |
TuP58 |
Investigation of Ingot
Material with Large Grain for RF Cavities |
|
Kazuhiro |
Enami |
KEK |
TuP59 |
Development of Nb/Cu Clad Seamless Cavity |
|
Fumio |
Furuta |
KEK |
TuP60 |
Different materials
bonding by HIP technology and the reliability |
|
Andrew |
Gerhan |
Alameda Applied Sciences Corp |
TuP61 |
Studies of niobium thin
films deposited by coaxial energetic deposition |
|
Roberto |
Russo |
INFN Sezione di Napoli |
TuP62 |
Cathodic Arc Grown
Niobium films for RF Superconducting Cavity Applications |
|
Alexander |
Romanenko |
Cornell University |
TuP63 |
RF properties at 6 GHz of
Cathodic Arc Films up to 450 Oe |
|
Genfa |
Wu |
TJNAF |
TuP64 |
A prototype of 500MHz
cavity coating system by ECR plasma |
|
Mohammed |
Fouaidy |
IPN Orsay |
TuP65 |
RRR of Copper Coating and
Low Temperature Electrical Resistivity of Materials for TTF Couplers |
|
Chet |
Nieter |
Tech-X Corporation |
TuP66 |
Modeling RF Cavities and
Multipacting with the VORPAL Code |
|
Genfa |
Wu |
TJNAF |
TuP67 |
Studies of electron activities in SNS cavities using FishPact |
|
Enzo |
Palmieri |
INFN-LNL |
TuP68 |
Progress on Spun Seamless Cavities |
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Thursday,
July 14:Posters |
|
|
Cristian |
Boffo |
FNAL |
ThP01 |
EP on Small Samples at Fermilab |
|
Fabien |
Eozenou |
CEA/Saclay |
ThP02 |
Efficiency Of
Electropolishing Versus Bath Composition And Aging: First Results |
|
Fabien |
Eozenou |
CEA/Saclay |
ThP03 |
Aluminium and Sulphur Impurities in Electropolishing Baths |
|
Rongli |
Geng |
Cornell University |
ThP04 |
Vertical Electropolishing Niobium Cavities |
|
Nicolai |
Steinhau-Kühl |
DESY |
ThP05 |
Update on the Experiences
of Electro Polishing of Multi-Cell Resonators at DESY |
|
Lutz |
Lilje |
DESY |
ThP06 |
Electropolishing of
Niobium Mono-Cell Cavities at HENKEL Electropolishing Technology Ltd.
(Germany) |
|
John |
Mammosser |
TJNAF |
ThP07 |
Status of The Electropolishing
Program At Jefferson Lab |
|
Axel |
Matheisen |
DESY |
ThP08 |
Preparation Sequences for
Electro-Polished High Gradient Multi-cell Cavities at DESY |
|
Arne |
Brinkmann |
DESY |
ThP09 |
Further Improvements with
Dry-Ice Cleaning om SRF-Cavities |
|
Paolo |
Michelato |
INFN-Milano |
ThP10 |
High Pressure Rinsing
Parameters Measurement and Process Optimization |
|
Michael |
Kelly |
ANL |
ThP11 |
A Joint ANL/FNAL Cavity Surface Processing Facility |
|
James |
Sears |
Cornell University |
ThP12 |
Developments in Electron
Beam Welding of Niobium Cavities |
|
Nicolay |
Krupka |
DESY |
ThP13 |
Quality Control Update of
the Cleanroom for Superconducting Multi-Cell Cavities at DESY |
|
Kurt |
Escherich |
DESY |
ThP14 |
Cleanroom Facilities for
High Gradient Resonator Preparation |
|
Jasper A. |
Dammann |
DESY |
ThP15 |
Towards
Industrialisation: Supporting the Manufacturing Processes of Superconducting
Cavities at DESY |
|
John |
Rathke |
Advanced Energy Systems Inc. |
ThP16 |
Prototyping Activities at
AES for ANL-RIA and ATLAS Cavities |
|
Katsuya |
Sennyu |
Mitsubishi Heavy Industries, ltd |
ThP17 |
Development of the
Superconducting Cavity at Mitsubishi Heavy Industries, Ltd. |
|
Takaaki |
Furuya |
KEK |
ThP18 |
Status of the
Superconducting Accelerating Cavity for KEKB |
|
Sergey |
Belomestnykh |
Cornell University |
ThP19 |
Status of the CESR Superconducting RF System |
|
Rama |
Calaga |
BNL |
ThP20 |
High Current Superconducting Gun at 703.5 MHz |
|
Dieter |
Gall |
DESY |
ThP21 |
A Database for
Superconducting Cavities for the TESLA Test Facility |
|
Rongli |
Geng |
Cornell University |
ThP22 |
Two-Cell Niobium Injector
Cavity for Cornell ERL Prototype |
|
Mykhaylo |
Gopych |
Institut fuer Kernphysik |
ThP23 |
Recent Results and Developments from the S-DALINAC |
|
Jiankui |
Hao |
Peking University |
ThP24 |
Recent Progresses on
DC-SC Photoinjector at Peking University |
|
Jiankui |
Hao |
Peking University |
ThP25 |
Possibility of Adopting Solenoid in DC-SC Photoinjector |
|
Douglas |
Holmes |
Advanced Energy Systems Inc. |
ThP26 |
Design and Fabrication of
the RHIC Electron-Cooling Experiment High Beta Cavity and Cryomodule |
|
Jens |
Iversen |
DESY |
ThP27 |
Single Cell Cavity Program for the XFEL |
|
Nicolai |
Lobanov |
ANU |
ThP28 |
Report on SRF Activities at ANU |
|
Donald |
Mitchell |
FNAL |
ThP29 |
Fermilab’s Mechanical
Design and Engineering of the 3.9 GHz, 3rd Harmonic SRF System |
|
Shuichi |
Noguchi |
KEK |
ThP30 |
STF Baseline Cavities and RF Components |
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ThP31 |
Abstract withdrawn |
|
Robby |
Tanner |
CLS |
ThP32 |
Canadian Light Source Storage Ring RF System |
|
Chaoen |
Wang |
NSRRC |
ThP33 |
Operational Status of the
Superconductivity RF at NSRRC |
|
Baocheng |
Zhang |
Peking University |
ThP34 |
The Progress Report at Peking University |
|
Jean-Luc |
Biarotte |
IPN Orsay |
ThP35 |
A European Advanced
Technology Programme for ADS Accelerator Development |
|
Catherine |
Thomas-Madec |
Synchrotron SOLEIL |
ThP36 |
HIGH POWER (35 KW AND 190
KW) SOLID STATE AMPLIFIERS FOR THE SOLEIL SYNCHROTRON |
|
Walter |
Hartung |
MSU |
ThP37 |
Cryomodule Development at
Michigan State University for the Rare Isotope Accelerator |
|
Joel |
Fuerst |
ANL |
ThP38 |
Status of the ATLAS Upgrade Cryomodule |
|
Eiji |
Kako |
KEK |
ThP39 |
Pulsed Operation of the
972MHz Prototype Cryomodule for ADS Superconducting Linac |
|
Robert |
Laxdal |
TRIUMF |
ThP40 |
Magnetic Field Studies in the ISAC-II Cryomodule |
|
Matthias |
Liepe |
Cornell University |
ThP41 |
Design of the CW Cornell ERL Injector Cryomodule |
|
Marc |
Louvet-Monsanglant |
Synchrotron SOLEIL |
ThP42 |
Design of the Liquid
Helium Supply Unit of the SOLEIL Superconducting RF System |
|
Paolo |
Pierini |
INFN-Milano |
ThP43 |
The Wire Position Monitor
(WPM) as a Sensor for Mechanical Vibration of the TTF Cryomodules |
|
Tom |
Powers |
TJNAF |
ThP44 |
Commissioning and
Operational Experience With an Intermediate Upgrade Cryomodule for the CEBAF
12 GeV Upgrade |
|
Catherine |
Thomas-Madec |
Synchrotron SOLEIL |
ThP45 |
Successful RF and
Cryogenic Tests of the SOLEIL Cryomodule |
|
Robert |
Rimmer |
TJNAF |
ThP46 |
The JLab
Ampere-Class cryomodule |
|
Quan-sheng |
Shu |
AMAC International Inc. |
ThP47 |
Development and Testing
of RF Double Window Input Power Couplers for TESLA |
|
|
Hassen |
Jenhani |
LAL Orsay |
ThP48 |
Preparation and
Conditioning of the TTF VUV-FEL Power Couplers |
|
Yoon |
Kang |
ORNL |
ThP49 |
RF Processing of the
Couplers for the SNS Superconducting Cavities |
|
Timergali |
Khabiboulline |
FNAL |
ThP50 |
Power Couplers Design for
Third Harmonic and Spoke Cavities at Fermilab |
|
Hiroshi |
Matsumoto |
KEK |
ThP51 |
A New Design for The
ILC-45MV/m Cavity Input Coupler |
|
Shinji |
Mitsunobu |
KEK |
ThP52 |
High Power Test of Input
Couplers and HOM dampers for KEKB
Superconducting Cavity |
|
Mehdi |
Souli |
IPN Orsay |
ThP53 |
Study of Thermal
Interaction Between a Power Coupler and a 700 MHz Superconducting Cavity |
|
|
Vadim |
Veshcherevich |
Cornell University |
ThP54 |
Design of High Power
Input Coupler for Cornell ERL Injector Cavities |
|
Jacek |
Sekutowicz |
DESY |
ThP55 |
A Beam Line HOM Absorber
for the European XFEL linac |
|
Harald |
Hahn |
BNL |
ThP56 |
R-square Impedance of ERL Ferrite HOM absorber |
|
Matthias |
Liepe |
Cornell University |
ThP57 |
Broadband HOM absorber for the Cornell ERL |
|
Genfa |
Wu |
TJNAF |
ThP58 |
Electromagnetic simulations of coaxial type HOM coupler |
|
Salman |
Tariq |
FNAL |
ThP59 |
3.9 GHz HOM Coupler & Coaxial Cable Thermal FEA |
|
|
Mohammed |
Fouaidy |
IPN Orsay |
ThP60 |
Electromechanical,
Thermal Properties and Radiation Hardness Tests of Piezoelectric Actuators at
Low Temperature |
|
Yasuo |
Higashi |
KEK |
ThP61 |
Coaxial ball screw tuner for ICHRO 9-cell cavity |
|
Paolo |
Pierini |
INFN-Milano |
ThP62 |
Characterization of an
Elliptical Low Beta Multicell Structure for Pulsed Operation |
|
Tomasz |
Plawski |
TJNAF |
ThP63 |
Digital Cavity Resonance
Monitor – Alternatively Way to Measure Cavity Microphonics |
|
Tom |
Powers |
TJNAF |
ThP64 |
Transient Microphonic
Effects In Superconducting Cavities |
|
Herve |
Saugnac |
IPN Orsay |
ThP65 |
Cold Tuning Sysytem for
700 MHz Elliptical Superconducting Cavity for Protons |
|
Matthias |
Liepe |
Cornell University |
ThP66 |
Pushing the Limits: RF Field Control at High Loaded Q |
|
Matthias |
Liepe |
Cornell University |
ThP67 |
Experience with the New
Digital RF Control System at the CESR Storage Ring |
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