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Transcript
Experimental HEP at Syracuse
Marina
Artuso
Research Professors
Steven
Blusk
Postdoctoral Researchers
Tomasz
Skwarnicki
Sheldon
Stone
Mitch
Soderberg
Graduate Students
+Anna Phan
(At CERN)
1
Faculty hosts
Mitch
Soderberg
Welcome
Steven
Blusk
Ray
Mountain
Undergraduates who will be of help with the labs
Emily Kraus
Erika Cowan
Dylan Hsu
Anna Fadeeva
2
What is Quarknet
Program funded by NSF and DOE (~15 years)
Primary aims are to provide for teachers:
 a deeper understanding of particle physics
 a deeper appreciation of the machinery of modern science
 Build inquiry-based learning environment … researchers build knowledge through
inquiry, discussion, collaboration
Additional goal:
 Integrate some ideas of particle physics into the classroom.
This doesn’t necessarily mean “new topics”
E.g. Conservation of momentum, energy … can use particle collisions
3
Quarknet Centers
54 Centers at Universities and Laboratories, including
Syracuse University
4
The program – Year 1
• Two teachers for 8-week program
– Last year, Ranald Bleakley and Josh Buchman
spent their summer at CERN
– Goals were to:
• Get a taste of what it is like being engaged at the world’s
most energetic collider
• Learn a bit about the LHCb experiment
• Develop an event display to visualize interactions in
LHCb (software-based project).
– Lots to learn, and they did a great job!
5
Years 2 - ?
• Year 2: Approximately 10 more teachers for
3-week institute (that’s now!)
• Years 3 – 5: One-week program at Syracuse.
• Years > 5: Other possibilities, most likely
focused on projects that would involve
1-2 teachers + students.
6
Keep in mind
• If you have any questions, please don’t
hesitate to ask.
• We’ll do our best to answer.
• Learning is “inquiry-based”…
• Do you best to work within your group to
answer your questions as a team.
• Then, we’ll discuss questions at the end of the
day.
7
General schedule
(most days)
•
•
•
•
•
•
8:00 – 8:30: Light breakfast
8:30 – 9:30: Lecture presentation + Q&A
9:45 – 11:45 Work on experiments
11:45 – 12:45 Lunch
1:00 – 3:00 Work on experiments
3:00 – 3:30 Meeting, Q&A, teachers share
ideas about how they might
integrate what they’ve learned into
the classroom.
8
Overview of presentations/topics
•
•
•
•
•
•
•
•
•
•
•
General Overview – Particle Physics & Cosmology
Relativity
Quantum Physics
Accelerators and Detectors
Standard Model overview
Strong & EM forces
Weak forces and decays
High energy collisions as microscopes
Top quark and Higgs
Neutrinos
Applications of Particle physics in the “real” world
9
Today
•
•
•
•
•
•
Introductory Presentation – S. Blusk
Coffee break
Presentation on Relativity – M. Soderberg
Lunch
Introduction to the Experiments – R. Mountain
Breakout – Look over lab writeups, work on any
assigned “HW” problems
10
Overview of Particle Physics
• “Laws” or theories used to describe nature
– Driven by observation (measurement)
– Postdictive & (hopefully) predictive
• Particle Physics
– Aims to describe the most fundamental objects in nature
and the force laws that govern their interactions.
– Currently: Standard Model (SM)
• 6 Quarks, 6 leptons, and force carriers (g, gluon, W±, Z)
• Works very well, but certainly an effective theory
– #1 Goal in Particle Physics: Expose & elucidate the most
fundamental theory of matter…. and many reasons to
believe the SM is not it !
– ‘New Physics’ is any observation that is not
in accord with the SM.
11
The sub-standard model !
Many key questions unanswered by SM







Why 3 generations?
Hierarchy problem?
Explanation/origin of masses?
Unification ?
How does gravity fit in?
Matter dominance over antimatter ?
… + more
Many key question unanswered in Cosmology




What is the dark matter in the Universe?
What is the dark energy in the Universe?
What caused inflation?
...+ more
The Connection: Expected that whatever the “New Physics” is that addresses SM questions
also provides a candidate particle that forms the Dark Matter in the Universe
This “new particle” ought to be observable in accelerator-based experiments
12
The
future
of
Particle
Physics
Primary mission is to uncover and elucidate the New Physics
that will help answer the fundamental shortcomings
of the Standard Model
- more complete theory
of matter.
Need to understand
neutrinos, mass, oscillations.
Also need to
find the Higgs boson
- Origin of mass in SM
- Still on the loose!
Direct Searches for New
Particles (CMS & ATLAS)
X
Standard
Model
New
Physics
Precision measurements
& rare decays (e.g B decays)
B
=
SM
+
NP
13