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 and look for everything in as many   have to be 100 per cent reliable and
 different ways as possible.”  have to be assembled in a reasonable
 “We know there are a lot of things   amount of time.”
 we don’t understand about the   Moreover, electronics students
 universe,” says Koffas, “so we have to   could be called upon to help refine the
 keep on looking.”  signal processing and data collection
 techniques, and Tait sees the potential
 Canada’s and Carleton’s focus for the   for further cross-pollination. “Anytime
 ATLAS-ITk project revolves around   you develop a capacity to do different
 20,000 silicon strip modules that   things, new applications are likely
 will have to be built between 2019   to appear,” he says. “I could imagine
 and 2023. These modules consist of   perhaps looking at applications in
 sensors, circuit boards and readout   security — a similar detector could be
 chips, and allow the inner tracker   used to monitor radiation. A similar
 to record the positions of charged   technology might be applied.”
 particles with extremely precise   “This technology is new for
 accuracy. Between 1,000 and 2,000   everyone,” adds Koffas, “and it has
 sensors will be tested at Carleton and   applications in aerospace, medical
 then distributed across the assembly   physics, nuclear physics and other
 sites — the university will be the North   fields. If the chips can survive at the
 American entry point for sensors.  LHC, they will survive at a nuclear
 In the meantime, Carleton   facility. It’s so complex, how the
 physicists are already collaborating   electronics are being designed, how
 with colleagues in the university’s   they will gather the particle physics
 Department of Electronics on the   data. Because of this complexity, there
 design and production of silicon strip   are applications to big data, Internet
 modules. Carleton’s MicroFabrication   banking. When you do a physics
 Facility, a cleanroom lab in the Minto   experiment of this magnitude, you can   Photo:
 Centre for Advanced Studies in   branch out in so many directions.
 Engineering, will be used to probe the   “We’ve never done anything with
 sensors and conduct research on their   them before research-wise,” Koffas   detector, and will manage hundreds of   and oil and gas industries as just two   by Koffas, is on the hardware side —   to understanding all these interactions.”
 effectiveness. The facility, which has   says about the interdisciplinary   megabits of data on the way toward   examples. “Working on these types   helping to test sensors before they go   Carleton students participating
 been operating since the late 1960s,   partnership with his electronics   further processing.  of projects can really help Canadian   into the silicon strip modules.  in the project are also learning how
 has decades of accumulated expertise   colleagues. “Once we learn how we   DA-Integrated will assemble and   companies broaden skillsets, which   “Because it’s such a large project,   to collaborate internationally and
 on developing, assembling and testing   can work together, we will see if there   test tens of thousands of circuits for   we need to compete in international   there are many levels of quality   partner with industry, and how to
 semi-conductors and other electronic   are other common areas of interest.   ATLAS over the next few years, and   markets.”  assurance and these preemptive tests   work with people at other Carleton
 devices. It has a long relationship with   This project could be a trailblazer.”  Alex Edwards, the company’s director   Projects such as ATLAS-ITk also   are extremely important,” says Hunter.   departments. “Students will be able
 medical physics researchers at Carleton,   of business development, is already   provide educational opportunities for   “Personally, I like the hands-on work   to see how a detector is built, which
 says Department of Electronics chair   Carleton’s ATLAS-ITk team is   thinking beyond this project to its   students like second-year Carleton   — to be able to physically test these   is not something that happens every
 Niall Tait, and is only starting to work   also collaborating with Canadian   broader implications.  master’s student, Robert Hunter, who   devices in the lab, to hook them up to   day,” says Koffas. “When you try to
 with particle physicists.  companies such as Ottawa-based   “The advanced micro-electronics   will be continuing with this work for   the equipment, develop the software,   teach someone how to become a
 “Most of the detector design has   DA-Integrated, which designs,   that are being developed and used   his PhD. Hunter spent about a month   and see if they’re doing what they’re   blacksmith, it’s one thing to show them
 been done, so to a large extent this will   develops and tests integrated circuits.   for this system, and the advanced   and a half at CERN in the summer of   supposed to be doing. These projects   a PowerPoint and something else to
 be an assembly activity,” says Tait. “But   Integrated circuits will read the low-  manufacturing techniques, are in so   2016, which gave him a sense of what   require a carefully measured synergy   give them a hammer and an anvil.
 there are research aspects — these   level electronic signals from hundreds   many products we use as consumers,”   this complex multi-faceted project is   of widely variant, technical fields and a   That’s what we’re doing.”
 devices have a fair number of parts,   of sensors at the core of the ATLAS   he says, citing the telecommunications   working toward. His role, supervised   robust experimental test setup is integral



 28  science.carleton.ca                                                                         science.carleton.ca  29