Matthias Liepe Zachary Conway CLASSE, Cornell University June 1, 2009

Slides:

Advertisements

Similar presentations

Metastability and self-oscillations in superconducting microwave Eran Segev Quantum Engineering Laboratory, Technion, Israel resonators integrated with.

Advertisements

WP-M3 Superconducting Materials PArametric COnverter Detector INFN_Genoa Renzo Parodi.

Waves Wave Properties. Wave Definitions  Wave Rhythmic disturbance that transfers energy  Medium Material through which a disturbance travels  Mechanical.

Second Sound in Superfluid Helium. Superfluids “Superfluid” describes a phase of matter. In this phase, a liquid has no viscosity and may exhibit several.

Phy100: Blackbody radiation

Observationally-Inspired Simulations of the Disk-Jet Interaction in GRS David Rothstein Cornell University with assistance from Richard Lovelace.

Presented by Grigory Eremeev Grigory Eremeev. Presented by Grigory Eremeev Outline: - Cavities and Fields; - Results; - Tricks of the Trade: new shapes;

Phy100: Heat transport Three basic forms of thermal heat transport

Semiconductors n D*n If T>0

CHE/ME 109 Heat Transfer in Electronics

Rate in Thermal Systems. Objectives Define Heat flow rate and its SI and English units of measure. Describe the heat transfer processes of conduction,

Cavity Vertical Test and Diagnostics Kitty Liao Second Open Collaboration Meeting on Superconducting Linacs for High Power Proton Beams.

Case study 5 RF cavities: superconductivity and thin films, local defect… Group A5 M. Martinello A. Mierau J. Tan J. Perez Bermejo M. Bednarek.

Solenoid-Based Focusing Lens for a Superconducting RF Proton Linac Presentation prepared for AEM 11/08/20101I. Terechkine.

Radiation: Processes and Properties -Basic Principles and Definitions- Chapter 12 Sections 12.1 through 12.3.

Superconductivity and Superfluidity The London penetration depth but also F and H London suggested that not only To which the solution is L is known as.

ILC PM Meeting S0 Webex Global Design Effort 1 S0/S1 Next Steps Lutz Lilje GDE.

Modeling of a continous casting process. Introduction The purpose of this model is to describe the transition from melt to solid in the flow in the continous.

Superconducting-Niobium Accelerator Cavity Second- Sound Defect Localization and Repair Zachary A. Conway CLASSE, Cornell University Cornell Laboratory.

A. Verweij, TE-MPE. 3 Feb 2009, LHC Performance Workshop – Chamonix 2009 Arjan Verweij TE-MPE - joint stability - what was wrong with the ‘old’ bus-bar.

Penetration depth of quasi-static H-field into a conductor Section 59.

Surge current protection using superconductor.. Fault Current  The short ckt current can exceed by a factor of 100 of the nominal current.  Produce.

Defects in Solids 0-D or point defects –vacancies, interstitials, etc. –control mass diffusion 1-D or linear defects –dislocations –control deformation.

1 Numerical study of the thermal behavior of an Nb 3 Sn high field magnet in He II Slawomir PIETROWICZ, Bertrand BAUDOUY CEA Saclay Irfu, SACM Gif-sur-Yvette.

1 Superfluidity in Liquid Helium PHYS 4315 R. S. Rubins, Fall 2009.

Lesson Objectives By the end of this lesson, you will be able to: State the different types of waves and the difference between them Describe the diffraction.

Chapter 12 Using Energy.

5 장 Dielectrics and Insulators. Preface ‘ Ceramic dielectrics and insulators ’ is a wide-ranging and complex topic embracing many types of ceramic, physical.

Energy “The energy of the mind is the essence of life” Aristotle. “If you want to find the secrets of the universe, think in terms of energy, frequency.

Energy  an object is said to have “energy” if the object has the ability to change its environment Two ways to transfer energy  1. through the application.

Group 6 / A RF Test and Properties of a Superconducting Cavity Mattia Checchin, Fabien Eozénou, Teresa Martinez de Alvaro, Szabina Mikulás, Jens Steckert.

Last week: Magnets & transformers A magnet is a material or object that produces a magnetic field. A method to detect a magnetic field is to scatter iron.

L. Serio COPING WITH TRANSIENTS L. SERIO CERN, Geneva (Switzerland)

1 Linear Wave Equation The maximum values of the transverse speed and transverse acceleration are v y, max =  A a y, max =  2 A The transverse speed.

Microwave Cooking Modeling Heat and moisture transport Andriy Rychahivskyy.

Superconductivity and Superfluidity Temperature scales Lecture 14.

Diagnostics Tests and Studies for SPL cavities Kitty Liao CERN BE-RF-KS First Open Collaboration Meeting on Superconducting Linacs for High Power Proton.

SUPERCONDUCTORS mobile electrons in conducting material move through lattice of atoms or ions that vibrate (thermal motion) when conductor is cooled down.

Mechanical Analysis Thermal Analysis Ø78 mm Ø106 mm L CLASSE facilities are operated by the Cornell Laboratory for Elementary Particle Physics (LEPP) and.

CONVECTION : An Activity at Solid Boundary P M V Subbarao Associate Professor Mechanical Engineering Department IIT Delhi Identify and Compute Gradients.

1 M. FOUAIDY ICEC26, New Delhi 9 March 2016 M. Fouaidy, D. Longuevergne, F. Dubois, O. Pochon Institut de Physique Nucléaire d’Orsay OST 2 nd Sound RESONATOR.

TE-type Sample Host Cavity development at Cornell Yi Xie, Matthias Liepe Cornell University Yi Xie – TE cavity developments at Cornell, TFSRF12.

Case study 5 RF cavities: superconductivity and thin films, local defect… 1 Thin Film Niobium: penetration depth Frequency shift during cooldown. Linear.

CHATS-AS 2011clam1 Integrated analysis of quench propagation in a system of magnetically coupled solenoids CHATS-AS 2011 Claudio Marinucci, Luca Bottura,

Possible Relationship Between Defect Pre-Heating and Defect Size H. Padamsee Cornell S0 Meeting, Jan 26, 2009.

Thermocline & Pycnocline

Hervé Allain, R. van Weelderen (CERN)

Cryogenic Heater Controls in C100 Cryomodules

Quench estimations of the CBM magnet

Results on second sound method

Nathaniel Garceau, Wei Guo, Thomas Dodamead

Hervé Allain, R. van Weelderen (CERN)

7. Ideal Bose Systems Thermodynamic Behavior of an Ideal Bose Gas

THE PROCESS OF CRACK INITIATION AND ITS PROPAGATION

Hervé Allain, R. van Weelderen (CERN)

Plasma-Gas-Condensation Deposition of Nb Clusters to Obtain Giant Permittivity 9 Jan 2013 Jennifer DeCerbo Materials Engineer AFRL/RQQE.

Heating and Cooling, the art of Thermal Energy

UNIT - 4 HEAT TRANSFER.

Static & dynamic stresses from beam heating in targets & windows

Case study 6 Properties and test of a Superconducting RF cavity

all Cooper pairs must behave in the same way

Matthias Liepe Zachary Conway CLASSE, Cornell University June 1, 2009

Zack Conway, Georg Hoffstaetter

Using the code QP3 to calculate quench thresholds for the MB

Energy Vocabulary.

5th Grade Vocabulary Part Five

Presentation transcript:

Matthias Liepe Zachary Conway CLASSE, Cornell University June 1, 2009 Oscillating Superleak Transducers For Quench Detection In Superconducting ILC Cavities Cooled With Superfluid Helium Matthias Liepe Zachary Conway CLASSE, Cornell University June 1, 2009

Superconducting Cavity Defects Localized electromagnetic power losses in a defect cause surface heating of both the defect and the adjacent superconducting surface. In a sufficiently high electromagnetic field, the superconducting surface adjacent to the defect is heated to the superconducting to normal conducting phase-transition temperature. Then the superconducting cavity becomes thermally unstable and the normal conducting region grows rapidly until all of the stored electromagnetic energy in the cavity is converted to heat. i.e. the instability is manifested at a well-defined critical field level by a sudden collapse of the electromagnetic field in the resonator. The time required for the collapse is typically 10 ms to 1 ms and is referred to as a cavity quench. May 9, 2019 Zachary A. Conway

Defect Location Simple defect localization schemes can be implemented by exploiting the properties of superfluid He, e.g. second sound waves. When a cavity quenches, typically several joules of thermal energy are transferred to the helium bath in a few microseconds. If the cavity is operated at T < 2.17K, the helium bath is a superfluid and a second sound wave propagates away from the heated region of the cavity. By locating several transducers in the helium bath around the cavity, the second sound wave front can be observed. The time of arrival of the second sound wave at a given transducer is determined by the time of flight from the heated region, which is centered on the defect causing quench. Measuring the time of flight to 3 or more uniquely located transducers, unambiguously determines the defect location. May 9, 2019 Zachary A. Conway

Superconducting Cavity Defect Example Defects are anything which cause the cavity to quench below the maximum theoretical critical field. Pits, bumps, inclusions, surface contamination, sharp-pronounced grain boundaries, etc. 4mm HAZ May 9, 2019 Zachary A. Conway

Verify the accuracy of the software The Project You will participate in the development of our second sound quench location system. The primary goal will be to modify existing software and hardware to handle multiple unique cavity geometries and use the system to help locate defects. Secondary areas: Verify the accuracy of the software Work on the development of the data acquisition hardware Integrate the data acquisition with the quench location software Participate in acquiring the cavity quench data May 9, 2019 Zachary A. Conway