Difference between revisions of "Particle Detection B"

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** See this Saulson lecture, this topic is covered from about minute 45 onwards: https://www.youtube.com/watch?v=m4IKvv0AqAI&list=PL04QVxpjcnjgs5aJ-BN3CRiMhJNyB1Ekr&index=4
 
** See this Saulson lecture, this topic is covered from about minute 45 onwards: https://www.youtube.com/watch?v=m4IKvv0AqAI&list=PL04QVxpjcnjgs5aJ-BN3CRiMhJNyB1Ekr&index=4
 
** You can also use Saulson Chapter 2: https://surfdrive.surf.nl/files/index.php/s/xATgIBO2OOEIM5o
 
** You can also use Saulson Chapter 2: https://surfdrive.surf.nl/files/index.php/s/xATgIBO2OOEIM5o
 +
** Write notes according to slide 18: [https://www.nikhef.nl/~nielsvb/PDB-2019/intro-GWDetection-NvB2019-students.pdf slides]
  
  

Revision as of 20:18, 31 March 2020

Put here all relevant material for students

To do

  • Email to students with Zoom details

Guidelines

Lecture format:

  • Divide each lecture in 2 (or 4) topics,
  • Ask the students to write lecture notes of 4-6 pages of a topic in groups of 3 students,
  • Derivation of equations in an appendix
  • A template of the lecture notes for each topic will be provided.

Exam:

  • The written lecture notes
  • Each group takes lecture notes on 1 (or 2) topic(s) they were not involved in, and will present this in 15 minutes to the rest of the group.
  • Each group will get a total number of points which can be subdivided over the different students.


Groups

Groups of 3 students each to work on the assignments.

  • Group 1:
  • Group 2:
  • Group 3:
  • Group 4:

Lectures

Lecture 1: Intro and Power Spectral Density

The Intro should contain:


The PSD chapter should contain


Date to hand in assignment: Wednesday April 6


Lecture 2: Gaussian beam, Fabry-Perot cavities

Topic should contain:

Date to hand in assignment:

Lecture 3: Interferometry (general, Michelson) and Interferometer for GW detection (power and signal recycling)

Topic should contain:

Date to hand in assignment:

Lecture 4: Low frequency noise: seismic and Newtonian noise, suspension systems

Lecture 5: Low to mid frequency noise: suspension wire and mirror thermal noise, coatings, monolithic suspensions

Lecture 6: Low to high frequency noise: quantum noise, laser (power), squeezing

Lecture 7: Sensing & control and/or future detectors

Literature

APPLICATIONS OF CLASSICAL PHYSICS, 2012-2013 Version of Textbook by Roger D. Blandford and Kip S. Thorne:

For copyrighted material we use a password protected link to Surfdrive