Cathode Discharge Simulation

Slides:

Advertisements

Similar presentations

TIME VARYING MAGNETIC FIELDS AND MAXWELL’S EQUATIONS

Advertisements

ENE 325 Electromagnetic Fields and Waves Lecture 10 Time-Varying Fields and Maxwell’s Equations.

EELE 461/561 – Digital System Design Module #2 Page 1 EELE 461/561 – Digital System Design Module #2 – Interconnect Modeling with Lumped Elements Topics.

DC CIRCUITS: CHAPTER 4.

Capacitance and Dielectrics AP Physics C. Applications of Electric Potential Is there any way we can use a set of plates with an electric field? YES!

Dielectric Materials.

Chapter 17 Capacitance and Capacitors! C = q / V V= voltage q = charge

Capacitance and Dielectrics AP Physics C. Commercial Capacitor Designs Section

Objectives: 1. Define and calculate the capacitance of a capacitor. 2. Describe the factors affecting the capacitance of the capacitor. 3. Calculate the.

Capacitors and Inductors 1 svbitec.wordpress.com Vishal Jethva.

23. Electrostatic Energy and Capacitors. 2 Topics Capacitors Electrostatic Energy Using Capacitors.

Lesson 6 Capacitors and Capacitance

2/6/07184 Lecture 171 PHY 184 Spring 2007 Lecture 17 Title: Resistance and Circuits.

ELE1110C – Tutorial Luk Chun Pong Outline -Basic concepts of Capacitors -RC circuits (DC) -Examples.

Capacitors and Inductors Discussion D14.1 Section 3-2.

ECE 201 Circuit Theory I1 Natural Response of an RC Circuit.

Lecture - 4 Inductance and capacitance equivalent circuits

Storey: Electrical & Electronic Systems © Pearson Education Limited 2004 OHT 13.1 Capacitance and Electric Fields  Introduction  Capacitors and Capacitance.

1 TOPIC 5 Capacitors and Dielectrics. 2 Capacitors are a means of storing electric charge (and electric energy) It takes energy to bring charge together.

Lec. (4) Chapter (2) AC- circuits Capacitors and transient current 1.

-Self Inductance -Inductance of a Solenoid -RL Circuit -Energy Stored in an Inductor AP Physics C Mrs. Coyle.

AP Physics C Montwood High School R. Casao

Capacitance and Dielectrics AP Physics C. Commercial Capacitor Designs Section

The graded exams will be returned next Tuesday, Oct 4

Dielectric Materials. What is a dielectric material? E Dielectric materials consist of polar molecules which are normally randomly oriented in the solid.

Copyright © 2009 Pearson Education, Inc. Chapter 34 Electromagnetic Waves.

 Devices that can store electric charge are called capacitors.  Capacitors consist of 2 conducting plates separated by a small distance containing an.

Chapter 6 RL and RC Circuits. Inductors and Capacitors Energy Storage Components Voltages and currents are related through calculus rather than ohm’s.

1 Chapter 14 Inductive Transients Preview [page 519] Capacitive circuits capacitor voltage cannot change instantanously. Inductive circuits inductor.

ELECTRIC POTENTIAL ENERGY AND ELECTRIC POTENTIAL POTENTIAL ENERGY ELECTRIC POTENTIAL WORK-ENERGY THEOREM CAPACITANCE COMBINATIONS OF CAPACITORS STORED.

Capacitor An element that stores charge when a voltage is applied

Lecture 15 Review: Energy storage and dynamic systems Basic time-varying signals Capacitors Related educational modules: –Section 2.2.

Chapter 23 Electric Potential. Basics The potential due to an electric dipole is just the sum of the potentials due to each charge, and can be calculated.

Alexander-Sadiku Fundamentals of Electric Circuits

1 EEE 431 Computational Methods in Electrodynamics Lecture 17 By Dr. Rasime Uyguroglu

EKT 101 Electric Circuit Theory

1 ECE 3144 Lecture 26 Dr. Rose Q. Hu Electrical and Computer Engineering Department Mississippi State University.

Electric Field.

Capacitors and Inductors 1 Eastern Mediterranean University.

Self Inductance and RL Circuits

Review Question Describe what happens to the lightbulb after the switch is closed. Assume that the capacitor has large capacitance and is initially uncharged,

1 ECE 3301 General Electrical Engineering Section 22 Capacitance.

Objectives: 1. Define and calculate the capacitance of a capacitor. 2. Describe the factors affecting the capacitance of the capacitor. 3. Calculate the.

Capacitors A capacitor is a device that has the ability “capacity” to store electric charge and energy.

CATHODE DISCHARGE SIMULATION William Kyle Dr. Glenn Horton-Smith.

An extension of Ramo's theorem to include resistive elements

Ch 29 The Electric Potential

Inductance and Capacitance Response of First Order RL and RC

Inductance and Capacitance

EKT 101 Electric Circuit Theory

System of charges in an external field

Recall Last Lecture Common collector Voltage gain and Current gain

Capacitors: parallel plate, cylindrical, spherical.

EKT 101 Electric Circuit Theory

Lecture 15 Review: Capacitors Related educational materials:

ENE 325 Electromagnetic Fields and Waves

Topics to be Discussed Steady State and Transient Response.

Chapter 7 – Response of First Order RL and RC Circuits

Inductors in Series. Inductors in Series Therefore inductor combine like resistor.

Capacitors 2 conducting plates separated by an insulator (or dielectric) Connect to a voltage source, stores +q and –q on plates: q = Cv C = capacitance.

Relation Between Electric Potential V & Electric Field E

Lattice (bounce) diagram

Capacitors Devices used to store charge.

ENE/EIE 325 Electromagnetic Fields and Waves

C H A P T E R 5 Capacitance. C H A P T E R 5 Capacitance.

Capacitor An element that stores charge when a voltage is applied

Chapter 24 Capacitance, Dielectrics, Electric Energy Storage

ELECTROSTATICS - POTENTIALS

Capacitor An element that stores charge when a voltage is applied

DC CIRCUITS: CHAPTER 4.

Presentation transcript:

Cathode Discharge Simulation William Kyle Dr. Glenn Horton-Smith

Dune Recap

It’s a Giant Capacitor

That Does Physics

Review of CPA Results

T = 40 us T = 100 us T = 200 us T = 400 us T = 1 ms

What’s the Difference Log Plot of Current (A) vs Time (s)

Log Plot of Energy (J) vs Time (s)

Adding the Field Cage After presenting this to the DUNE HV group, I was then asked if I could adding in a simulation of the field cage discharging as they are fed by the same HV cable. So I did that for both of the side lengths of the field cage. Short Side I Long Side I

Comparison Then, I made a SPICE circuit simulation of the field cage discharge to compare with my results …

Comparing Results SPICE PYTHON

Direct Comparison of FTCS and SPICE Shown data is for one complete side of the field cage on the shorter dimension of CPA / LArTPC of 1.15 m (vs long side of 6.0 m)

Induced Current at APA

What’s the Goal Here We have plenty of knowledge/understanding of what sort of behavior we should see from Voltage/E field in LArTPC/at APA in steady state of detector operation. However, the fields resultant of the CPA during a discharge are vastly more complicated, due to the non uniformities and wide ranges of voltages of different elements across the Cathode. Therefore, finding any sort of exact solutions to even the quasi-static approximations of the electric fields all but impossible, and completely impractical for our needs. So, I instead decided that I could get a close enough approximation to provide meaningful outputs using just the monopole term of a multipole expansion to get Voltages res. from cathode, at z=3.6m=dist. btw the APA and the CPA.

Method Used for Monopole Approx. However, what I did wasn’t a monopole approximation of the CPA as a whole. Rather, I realized that our FTCS method was already breaking up the CPA into many sections of CPA at set V’s, and with defined sizes and relative locations. So, I decided to do a monopole term approx. separately for each individual CPA section, (in this case: 5 cm x 5 cm sections) I.e. Since the CPA has a know Capacitance/m2 , I could find a C for each.05x.05 m section: C = (Capacitance/m2)*(.052). Hence, as Q=C/V, and our simulation give a V of each section at every time-step, we also know a total charge, (the monopole moment), of each section.

Monopole Method Cont’d We know the equations describing a point charge to be: And from our previously assumed geometry of CPA and APA as a finite parallel plate capacitor: Hence: where and

What Results Do We Get From This? Mathematica Test of Initial Cond. Python IC Result

Getting Induced Charge on APA from Voltage Assumed a conducting plane at 0V and used boundary conditions equation of This gives us a surface charge (sigma) for each element at each time step. We wanted worst case scenario so we summed over the 6m length of the anode plane

Results