stripline kicker under construction

Some of our projects


Mu2e linac-based calibration

Mu2e mixed-signal calorimeter electronics

ILC damping ring kickers

ILC high availability/high reliability control systems

Axions

Acoustic techniques for studying high-voltage breakdown


Mu2e links


ILC links


HEP links


UIUC links


1961 New York Yankees team photo

Group Members

Alumni

UIUC International Linear Collider projects

Photo gallery

Basic science advocacy and sociology

Presentations concerning physics research

Contact information

Past projects: research concerning the ILC



The International Linear Collider
Why do the quarks and leptons, as well as the W and Z bosons, have non-zero mass while photons remain massless? What is the nature of the missing mass that provides the gravitational binding necessary to explain the stability of galaxies? Do supersymmetric particles exist, and does supersymmetry unify the fundamental forces at the highest energy scales?

We hope to learn the answers to some of these questions through results from experiments performed at the Large Hadron Collider, nearing completion at CERN in Geneva, Switzerland. The International Linear Collider has similar physics goals, but its electron-positron collisions are expected to allow precision measurements that cannot be performed at the LHC, and are needed to understand more fully the nature of "electroweak symmetry breaking," the properties of the Higgs boson(s), and the characteristics of supersymmetric particles, should they exist.

The ILC will be a challenging machine to design and build. Its initial version will accelerate beams of electrons and positrons to an energy of 250 GeV and focus these beams to a thickness comparable to the size of a hemoglobin molecule. The focused beams will collide head-on after each travels through a fifteen kilometer linear accelerator built from superconducting niobium that has been cooled to within two degrees of absolute zero.

The UIUC ILC group had worked primarily on technical issues relating to the design of the accelerator. Because many of the problems to be resolved require a working knowledge of classical mechanics and electrodynamics, most of our research projects lent themselves well to the participation of undergraduate research assistants. The undergraduates in the group found solutions to problems that had stumped PhD-level scientists. Results produced by the group's students featured prominently in our presentations at international conferences on the ILC. At the time Congress eliminated most funding for university-based work on the ILC in December 2007, five members of the UIUC ILC group were undergraduate physics majors. The research work was a great deal of fun for all of us.


We made a roadtrip to Fermilab and Argonne 8/3/07:


Introduction, George Gollin

AØ beamline simulation, Alex Lang
Tests at AØ of a stripline kicker, George Gollin
Initial Studies into the Design of an Axion Cannon, Will Dluger

Overview of ATCA Shelf, Shelf Manager, Blades and IPMC Organization, Yehan Liu
Studies of the I2C Shelf Manager, Perry Chodash
Physics and ATCA, Mike Kasten
An Introduction to OpenClovis, Jason Chang


Other ILC stuff:


The U.S. HEP community had been discussing a reorganization of the university-based ILC R&D effort. See U.S. university engagement with the ILC: a report to the Americas Regional Team (356 kB pdf).

A neat idea, but probably not feasible due to nonlinear effects: a "Fourier Series Pulse Compression Kicker" for the ILC's damping rings. Here's a long technical memo about it: Performance Modeling of a Fourier Series Pulse Compression Kicker for the International Linear Collider Damping Rings (845 kB MSW).

I was a Proposal Coordinator for the Linear Collider Research and Development Working Group.

Fermilab International Linear Collider damping ring work: Studies Pertaining to a Small Damping Ring for the International Linear Collider.

My LCRD proposals... LCRD 2.15: Investigation of Acoustic Localization of rf Cavity Breakdown (1.7 MB pdf, complete with two movies [4.9MB and 12.5 MB]!) and LCRD 2.22: Investigation of Novel Schemes for Injection/Extraction Kickers (2.2 MB pdf).

2007 progress report from LCRD 2.22


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