The Ludlum Project

1. The Ludlum Project Advisors: Dr. Randal Ruchti, Dr. Dan Karmgard Mark Vigneault Teacher: Mark Kirzeder Students: Kristen Anderson Mengwen Zhang

2. History of Ludlum @ Notre Dame • Ongoing • Ludlum Measurements Inc. • In the past, separate wave shifting and scintillating materials were used in combination with one another.

3. Current Focus of Ludlum @ ND • Current experiments are focused on materials that are manufactured with both properties in a single fiber. • Old 3HF • New 3HF • OX-550F • 4CN-HBT

4. Current Goals of Ludlum • The goal of the project is to find a material that can be used in new particle detectors. • Several methods have been developed in the past and are in use at FermiLab and CERN currently.

5. Factors Tested This Summer • Brightness • How much light is transmitted along the fiber • Decay Time • How much time passes between excitation and relaxation of molecules in the fiber • Attenuation Length • How long can a fiber be before light begins to escape

6. Test – Scintillation • Used to test all three factors

7. Experiment Set Upwithin a light tight box Brass plate Radioactive source Data PMT Sr 90 Fiber PMT Counter Paddles Apiazon

8. Experiment Set Up Optical fiber Radioactive source Time- gate paddles Bronze plate

9. Data Gathering • Two paddles are used as triggers • Brass plate shields • Radioactive source • Data is stored on an oscilloscope • 2048 data points per run - averaged • 6 or more runs per graph - averaged • Several distances from source to PMT

10. Data Gathering

11. Calculating Brightness • Brightness is a measure of how much light the fiber transmits • Integration yields total light • Several integrations completed

12. Calculating Brightness Average brightness is 1021 units at 1.5 m.

13. Calculating Decay Time • Used for comparative analysis. • 90% - 10% of curve used • A best fit exponential or semi-log plot • 2.93m magic number

14. Calculating Decay Time

15. Calculating Decay Time Decay time = 1 / c =18.35ns

16. Calculating Attenuation Length • Lout = Lin * exp (-x / Attenuation Length) • Attenuation length is the distance at which 1/e of the original light remains • Light out data was gathered at 1.0m, 1.5m, 2.0m, 2.5m, and 2.93m • Incomplete data set

17. Calculating Attenuation Length Attenuation Length = 1 / c =4.96m

18. Test – LED Attenuation • A new test • UV LED’s 395nm and 405nm • Quicker • Easier

19. Test – LED Attenuation • Failures • Inconsistent data • Unexpected results • Success • Development of sound data analysis techniques • Improvement of experimental techniques

20. Experimental Set Upwithin a light tight box LED Photo Diode Sr 90 Fiber Apilazon

21. Experimental Set Up LED Photo Diode Fiber

22. Calculating Attenuation Length Attenuation Length = 1/c = 3.00m

23. Calculating Attenuation Length Attenuation Length = 1/c = 4.74m

24. Conclusions • Preliminary results indicate • New 3HF is the brightest fiber • 4CN-HBT has shortest decay time • 4CN-HBT has the longest attenuation length • The nature of future experiments will dictate which fibers will be used • There may not be one perfect fiber