1. Cosmic Ray e-Lab Bob Peterson Fermi National Accelerator Lab

2. Teaching and Learning with Cosmic Rays Agenda Workshop Objectives QuarkNet Overview Teaching and Learning with Cosmic Rays QuarkNet Cosmic Ray e-Lab and Detector Assemble CRMD hardware and take data. Cosmic Ray e-Lab Exploration Upload and analyze data.

3. Teaching and Learning with Cosmic Rays Workshop Objectives: Assemble CRMD: plateau, geometry, data-take. Record progress: LogBook. Design e-Lab investigation: data, tools, plots. Write poster, present results. Share “Implementation Plan” and strategy.

4. Teaching and Learning with Cosmic Rays Whata we doin’?  Bein’ kids!  Experience the CR e-Lab from a students vantage  Inquiry-based learning

5. Teaching and Learning with Cosmic Rays

6. Teaching and Learning with Cosmic Rays Active QuarkNet Centers http://physicsweb.phy.uic.edu/quarknet/mapUS_international.html http://physicsweb.phy.uic.edu/quarknet/mapUS_international.html http://quarknet.fnal.gov

7. Teaching and Learning with Cosmic Rays Paradigm: a good way to learn science?  Participate in data-based science.  Ask cosmic ray questions.  Marshal a research plan.  Engage hardware and technology.  Analyze realistic, not simulated data.  Share results with collaboration.

8. Teaching and Learning with Cosmic Rays

9. Alignment with National Science Education Standards Content Standards A: Science as Inquiry - Abilities necessary to do scientific inquiry and understandings about scientific inquiry B: Physical Science - Developing student understanding G: History and Nature of Science - Developing student understanding Teaching and Learning with Cosmic Rays More standards on e-Lab website http://www18.i2u2.org/elab/cosmic/teacher/standards.jsp

10. Teaching and Learning with Cosmic Rays Cosmic Ray e-Lab Stats: May 2011 899 teachers accounts 1,813 student research groups 537 DAQs worldwide 357 detectors in high schools 35,174 data files 811 posters

11. Teaching and Learning with Cosmic Rays QuarkNet creates a collaboration of users: Teachers  Students Teachers  Mentor Scientists Detector Schools  Non-Detector Schools World-wide Network: Students  Students

12. Sources of Cosmic Rays –Supernova remnants –Active galaxies (?) –Quasars (?) –Gamma Ray Bursters (?) –Dark Energy (?) Teaching and Learning with Cosmic Rays

13. Cosmic Rays at Earth –Primaries (protons, nuclei) –Secondaries (pions) –Decay products (muons, photons, electrons) 1-2  per second Teaching and Learning with Cosmic Rays

14. Teaching and Learning with Cosmic Rays RunRun: CR shower video if fast connection http://astro.uchicago.edu/cosmus/projects/aires/protonshoweroverchicago.mpeg

15. Cosmic Rays –Sources –Composition, energy spectrum –Detection –Current experiments The QuarkNet Classroom Detector –Hardware overview –Classroom use –Experiments, measurements Data Analysis –Upload, analyze data & save data products. –Share results. –Enter logbook notes. Teaching and Learning with Cosmic Rays

16. Teaching and Learning with Cosmic Rays Wealth of open, cool science questions Weather, lightning, biology, climate, data bits, solar storms, … CR e-Lab  not prescriptive, not recipes Provides resources and analysis tools Trusts the teacher to guide research

17. BIG science- Students use similar techniques and equipment Auger  Argentina http://www.auger.org MINOS Far Detector  Soudan Mine, Minnesota http://farweb.minos-soudan.org/events/ CMS  LHC, CERN, Switzerland http://cms.cern.ch/ Atlas  LHC, CERN, Switzerland http://atlas.ch/ IceCube  South Pole http://icecube.wisc.edu/  QuarkNet Cosmic Ray e-Lab Studies: Direct analog to detector-based particle physics Teaching and Learning with Cosmic Rays

18. Teachers & students: –Assemble. –Calibrate. –Set-up and run. Teaching and Learning with Cosmic Rays

19. Teaching and Learning with Cosmic Rays Questions??? Break?? 

20. Overview: Cosmic Ray Muon Detector Bob Peterson Fermi National Accelerator Lab Teaching and Learning with Cosmic Rays

21. Teaching and Learning with Cosmic Rays CRMD Expectation:  Not “plug & play”  Assembling and thinking required Direct analogue of the big Tevatron & LHC detectors CDF ATLAS CMS QuarkNet Note: Images are not to scale

22. Teaching and Learning with Cosmic Rays Typical QuarkNet Detector Setup 1. Counters-scintillators, photomultiplier tubes (two shown) 2. QuarkNet DAQ board 3. 5 VDC adapter 4. GPS receiver 5. GPS extension cable 6. Computer (PC preferred) 7. USB adapter or cable 8. Lemo or BNC signal cables 9. Daisy-chained power cables The QuarkNet Cosmic Ray Muon Detector (CRMD) 6

23. DAQ hardware measures: –Light pulse timing. –Ambient temperature. –Atmospheric pressure. Experiments include: –Flux studies. –Time correlation. –Shielding. –Particle speed. –Particle lifetime. –Altitude attenuation. Teaching and Learning with Cosmic Rays

24. Teaching and Learning with Cosmic Rays

25. Teaching and Learning with Cosmic Rays Types of Counter Configuration: 1) Array  shower Counters distributed 2) Stacked  flux Counters spaced on common center Determined by type of study Student defined

26. Teaching and Learning with Cosmic Rays NEXT SESSION: Break out into small teams.  Assemble cosmic ray muon detectors. 4 counters: one team for each counter Computer  DAQ: one team Geometry  GPS: one team Tomorrow: Cosmic Ray e-Lab and UPLOAD data

27. Teaching and Learning with Cosmic Rays QuarkNet Cosmic Ray e-Lab Teacher Accounts E-mail the following: Name: Account Name: School: City/State: E-mail: To: Bob Peterson  rspete@fnal.gov

28. Teaching and Learning with Cosmic Rays Explore tonight. Cosmic Ray e-Lab portal: http://www.i2u2.org/elab/cosmic

29. Teaching and Learning with Cosmic Rays

30. Cosmic Ray e-Lab Exploration Bob Peterson Fermi National Accelerator Lab Teaching and Learning with Cosmic Rays

31. DAQ hardware measures: –Light pulse timing. –Ambient temperature. –Atmospheric pressure. Experiments include: –Flux studies. –Time correlation. –Shielding. –Particle speed. –Particle lifetime. –Altitude attenuation. Teaching and Learning with the Cosmic Ray e-Lab

32. 02F17C70 AE 3E 23 30 00 01 00 01 01BAB196 053657.359 260105 A 10 0 +0365 19262F0A 80 01 00 01 00 01 3B 01 1814BD14 053706.358 260105 A 10 0 +0365 19262F0B 28 01 00 01 00 01 01 2A 1814BD14 053706.358 260105 A 10 0 +0365 19262F0C 01 21 00 01 00 01 00 01 1814BD14 053706.358 260105 A 10 0 +0365 23246B23 A5 34 00 01 00 01 2E 3A 2203DEA2 053710.358 260105 A 10 0 +0366... Raw Data Teaching and Learning with the Cosmic Ray e-Lab 24533966341848883424871634184888342607112.00

33. There has to be an easier way...  Cosmic Ray e-Lab Lower the threshold to analyzing real data. Teaching and Learning with the Cosmic Ray e-Lab

34. There are more e-Labs on the horizon... LIGO CMS Other science with large data sets... SDSS? Mars Rover? weather? ocean? Investigate further?  www.i2u2.org e-Labs

35. Major Strengths of e-Labs First time: teachers and students Large cluster of computer servers at Argonne National Lab e-Labs: same structure & format, “look/feel” e-Labs

36. Teaching and Learning with the Cosmic Ray e-Lab http://www.i2u2.org/elab/cosmic

37. Teaching and Learning with the Cosmic Ray e-Lab http://www.i2u2.org/elab/cosmic Login Username: Password:

38. Teaching and Learning with the Cosmic Ray e-Lab

39. Teaching and Learning with the Cosmic Ray e-Lab

40. Teaching and Learning with the Cosmic Ray e-Lab Go to: REGISTRATION 1st: Change password.  Update your previously created groups. !! min 6 characters : max 10 characters !! !! alpha/numeric !! !! no spaces !! 2nd: Create student group.  Register student research groups. Select “pencil”: yes pre/post test 3rd: Add DAQ #.  Update detector IDs for your group.

41. Teaching and Learning with Cosmic Rays Debrief: Summarize in LogBook

42. Teaching and Learning with the Cosmic Ray e-Lab

43. Teaching and Learning with the Cosmic Ray e-Lab

44. Teaching and Learning with the Cosmic Ray e-Lab Quick Links

45. Teaching and Learning with the Cosmic Ray e-Lab

46. Teaching and Learning with the Cosmic Ray e-Lab Students can tour the site.

47. Teaching and Learning with the Cosmic Ray e-Lab

48. Teaching and Learning with the Cosmic Ray e-Lab

49. Teaching and Learning with the Cosmic Ray e-Lab Pause: Live action demo  UPLOAD data: Follow me.  GEOMETRY: Review tutorial.

50. Teaching and Learning with the Cosmic Ray e-Lab

52. Blessing

53. Teaching and Learning with the Cosmic Ray e-Lab More live action  Examples Data Search Shower Analysis Flux Analysis

54. Teaching and Learning with the Cosmic Ray e-Lab

55. Teaching and Learning with the Cosmic Ray e-Lab Reproduce analysis:  Click on plot.  Run study again.  Change parameters.

56. Teaching and Learning with the Cosmic Ray e-Lab

57. Teaching and Learning with the Cosmic Ray e-Lab

58. Teaching and Learning with the Cosmic Ray e-Lab

59. Teaching and Learning with the Cosmic Ray e-Lab

60. Teaching and Learning with the Cosmic Ray e-Lab

61. Teaching and Learning with the Cosmic Ray e-Lab

62. Teaching and Learning with Cosmic Rays Debrief: Summarize in LogBook

63. Teaching and Learning with the Cosmic Ray e-Lab

64. Teaching and Learning with the Cosmic Ray e-Lab Follow upper right: 

65. Teaching and Learning with the Cosmic Ray e-Lab Cosmic Ray e-Lab Investigation  Team Task: Data Analysis a) Pose a simple CR research question. b) Select small CR data set. c) Run CR analysis. d) Save PERF and analysis plots. e) Track your progress using the LOGBOOK. f) Write online poster about study with plot; include PERF and analysis plot. g) Share “tricks of the trade” about the e-Lab. Judge your constraints: time and $$$.

66. Teaching and Learning with Cosmic Rays Debrief: Summarize in LogBook

67. Teaching and Learning with Cosmic Rays

68. Teaching and Learning with the Cosmic Ray e-Lab Implementation Plan http://www.learnaboutenergy.org/quarknet/Blog-Facebook-Notes.pdf Science Experiment Goals: In one or two sentences, describe or list the goals of the science experiment to which this e-Lab is related. Grade(s)/Context: (Such as Science Club) in which you will implement the e-Lab. Challenges: To implementing the e-Lab. When/Where: You implement the e-lab (e.g., after the AP exam in the spring for two weeks before the end of school). Learning Objectives: (What will you expect students to know and be able to do as a result of conducting the e-Lab). Standards: (Whichever ones you are being held responsible for) being addressed. Steps: In the plan (e.g., 1. assess prior knowledge by?; 2. provide background information by?; 3.?4.?5. have students complete the poster).

69. Teaching and Learning with the Cosmic Ray e-Lab Cosmic Ray e-Lab Investigation  Teacher Task: Implementation Plan a)Teacher Home: Community  “Required Elements for an Implementation Plan” b)Load  Community Forum: Workshop Deliverables... do not yet have an account, you can create one here. Invitation Code: inquiry Password: same as your e-Lab password !! !! Minimum 6 character: alpha/numeric; no spaces !! Guiding Questions: How would you use the CR e-Lab in your classroom? How do the learner outcomes apply to your activity? What makes self-guided research beneficial? Highlight one interesting feature you found in the QN e-Lab.

70. Teaching and Learning with the Cosmic Ray e-Lab CRMD/e-Lab Workshop Deliverables Every project constrained: time and $$$ Cosmic Ray e-Lab Investigation  Team Task: POSTER  Teacher Task: Implementation Plan  Community Forum: Workshop Deliveriables Workshop Evaluation --> Participants: http://www13.i2u2.org/cosmic/library/upload/4/45/QNetSurveyforFellows_061207.doc Workshop Report --> Fellow: http://www13.i2u2.org/cosmic/library/upload/f/f0/Fellows-wkshop-form.doc CRMDs  Center placement list and plan

71. Teaching and Learning with Cosmic Rays Debrief: Summarize in LogBook

72. Teaching and Learning with the Cosmic Ray e-Lab Workshop Review  How’d we do? Assemble CRMD: plateau, geometry, data-take. Record progress: LogBook. Design investigation: search data, use analysis. Write poster, present results. Share “Implementation Plan” for the e-Lab.