Tag: SMU Department of Physics

CBS Channel 11: Long-fought discovery of elusive “God” particle brings joy to SMU physicists

Post author By Margaret Allen
Post date July 5, 2012

CBS DFW Channel 11 reporter Jack Fink with KTVT-TV interviewed SMU physicist Ryszard Stroynowski about the historic discovery of the new fundamental particle necessary for scientists to explain how matter acquires mass.

SMU physicist Stroynowski is a principal investigator in the search for the Higgs boson, and the leader of SMU’s team in the Department of Physics that is working on the experiment.

The experimental physics group at SMU has been involved since 1994 and is a major contributor to the research, the heart of which is the Large Hadron Collider particle accelerator on the border with Switzerland and France.

The discovery results, which are preliminary, were announced July 4 at CERN, the European Organization for Nuclear Research, near Geneva, Switzerland, and at the International Conference of High Energy Physics in Melbourne, Australia. CERN is the headquarters for the LHC lab, which is a collaborative experiment involving thousands of scientists worldwide.

SMU is a nationally ranked private university in Dallas founded 100 years ago. Today, SMU enrolls nearly 11,000 students who benefit from the academic opportunities and international reach of seven degree-granting schools. For more information see www.smuresearch.com.

SMU has an uplink facility located on campus for live TV, radio, or online interviews. To speak with an SMU expert or book an SMU guest in the SMU Broadcast Studio, call SMU News & Communications at 214-768-7650.

Tags Dedman College, Ryszard Stroynowski, SMU Department of Physics

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Dallas Observer: Has the “God Particle” Been Found? Let’s Ask the SMU Prof Who’s Been Looking.

Post author By Margaret Allen
Post date July 3, 2012

Dallas Observer science writer Brantley Hargrove interviewed SMU physicist Ryszard Stroynowski in advance of the announcement from CERN in Geneva about whether scientists have discovered the Higgs boson, a fundamental particle theorized to explain why matter has mass. Stroynowski and other SMU faculty and students have played a role in the recent findings as participants in the experiments.

Researchers at Switzerland-based CERN, the largest high-energy physics experiment in the world, have been seeking the Higgs boson since it was theorized in the 1960s. The so-called “God” particle is believed to play a fundamental role in solving the important mystery of why matter has mass.

Read the full article.

EXCERPT:

By Brantley Hargrove
Dallas Observer
In the early morning hours Wednesday, physicists in Switzerland may announce that they’ve discovered the elusive “God Particle,” aka the Higgs boson.
For more than half a century, the Higgs has been the theoretical mechanism that imbued matter with mass after the Big Bang, so that the swirling chaos of the universe could coalesce into planets and, eventually, life. Since 1994, Southern Methodist University physics professor Ryszard Stroynowski has been involved in the construction of a device that could detect the presence of the Higgs in the Large Hadron Collider. Back in December, the Organization for Nuclear Research (CERN) announced they’d narrowed their search down to a small range of masses. Reached Tuesday, he was tight-lipped about Wednesday’s announcement.

“I’m involved with (one of two CERN experiments, known as ATLAS) and I can tell you that we’re confident and that we have enough data to cover whatever statements we’re making,” Stroynowski tells Unfair Park. The wording of that statement, though, will be carefully couched. [fusion_builder_container hundred_percent=”yes” overflow=”visible”][fusion_builder_row][fusion_builder_column type=”1_1″ background_position=”left top” background_color=”” border_size=”” border_color=”” border_style=”solid” spacing=”yes” background_image=”” background_repeat=”no-repeat” padding=”” margin_top=”0px” margin_bottom=”0px” class=”” id=”” animation_type=”” animation_speed=”0.3″ animation_direction=”left” hide_on_mobile=”no” center_content=”no” min_height=”none”][…]

[…] “It’s like opening a door to a completely new field, so it’s really exciting,” he says. “I have never seen what I call ‘Higgs-teria’ at this level. The amount of interest in the media is something which I have never seen in my entire professional life, over 40 years now.”

Read the full article.

SMU has an uplink facility located on campus for live TV, radio, or online interviews. To speak with an SMU expert or book an SMU guest in the studio, call SMU News & Communications at 214-768-7650.[/fusion_builder_column][/fusion_builder_row][/fusion_builder_container]

Tags Dedman College, Ryszard Stroynowski, SMU Department of Physics

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Fiber-optic data link, now with DOE funding, is critical in the hunt for Big Bang’s “God” particle

Post author By Margaret Allen
Post date June 29, 2012

Tiny optoelectronic module plays a key role in the world’s largest physics experiments; new module will be 75 times faster than the current fiber-optic data link on Large Hadron Collider’s ATLAS experiment

1st gen link,pink,400x300 — The SMU fiber-optic data link (above) was made specifically for ATLAS and its extremely harsh low-temperature, high-radiation environment. More than 1,500 of the data link modules are installed on ATLAS. A second-generation link, which is five times faster but with a smaller footprint, is slated for the next upgrade of the LHC detectors. A planned third-generation data link, being funded by DOE, will be 75 times faster.(Credit: www.smuresearch.com)

A tiny optoelectronic module designed in part by SMU physicists plays a big role in the world’s largest physics experiment at CERN in Switzerland, where scientists are searching for the “God” particle.

The module, a fiber-optic transmitter, sends the Large Hadron Collider’s critical raw data from its ATLAS experiment to offsite computer farms. From there, thousands of physicists around the world access the data and analyze it for the long-sought-after particle, the Higgs boson.

Now as a result of SMU’s role on the LHC data link, SMU Physics Research Professor Annie Xiang has won a three-year research and development grant with $67,500 in support annually from the U.S. Department of Energy to advance the design of the optoelectronic module.

The grant calls for a customized multi-channel optical transmitter that can be deployed on many of the world’s high-energy particle detectors.

Xiang is principal investigator for SMU’s Data Links Group in SMU’s Physics Department, working in the Optoelectronics Lab of Physics Professor Jingbo Ye. She coordinates the lab’s development of optical data transmission systems for particle physics experiments.

More than 1,500 data link modules are installed on ATLAS
“We made the first-generation fiber-optic data link specifically for ATLAS and its extremely harsh low-temperature, high-radiation environment,” Xiang said.

More than 1,500 of the first-generation data link modules are installed on the calorimeter detectors of ATLAS. The link’s job is to reliably offload a continuous flood of raw data without failure or error. Scientists scour the data for signs of the Higgs boson, which has been theorized for decades but never actually observed. It is believed the Higgs gives mass to the matter that we observe.

A second-generation data link, which SMU also helped design, is slated for deployment in the next upgrade of the LHC in coming years. The current data link installed in ATLAS can transmit up to 1.6 gigabits a second in a single channel, which equates to writing an HD DVD in one minute, Xiang said. The second-generation link, a 5 gigabit transceiver, has a smaller footprint than the current link, but can transmit three times faster and is qualified for even higher radiation. “Many thousands of the second-generation link can be expected across the LHC detectors,” Xiang said.

The data link being supported by DOE will be even faster. A transmitter only, it will have a transmission capacity of 120 gigabits a second, or 75 times faster than the data link currently installed on ATLAS, Xiang said.

DOE project will customize off-the-shelf commercial components for on-detector installation
To design the links, SMU’s team and its collaborators start with qualified commercial transmitters and receivers, then customize them for the LHC detectors, Xiang said. They will repeat that process to develop the data link being supported by DOE.

Called a “generic” module, the link supported by DOE isn’t specified for any particular detector, but rather will be available to deploy on detectors at the LHC, at Fermi National Accelerator Laboratory (Fermilab) and others.

The module — a 12-channel transmitter — must be high speed and low footprint, and able to withstand an extremely cold and high-radiation environment, while at the same time maintaining low mass and low power consumption, Xiang said.

The DOE award is part of a collaborative project with Fermilab, the University of Minnesota, The Ohio State University and Argonne National Laboratory, with a total funding of $900,000. SMU designed the first-generation module in collaboration with Taiwan’s Academia Sinica. SMU collaborated on the second-generation module with CERN, Oxford University and Fermilab.

Ye and Xiang are members of SMU’s ATLAS team, which is led by SMU Physics Professor Ryszard Stroynowski. — Margaret Allen

Tags Annie C. Xiang, Dedman College, Jingbo Ye, Ryszard Stroynowski, SMU Department of Physics

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Dark matter search may turn up evidence of WIMPS: SMU Researcher Q&A

Post author By Margaret Allen
Post date April 3, 2012

Radioactivity interferes with our ability to observe dark matter. A banana would be more radioactive than the materials we use for our experiment. — Jodi Cooley

The XIA Alpha Particle Counter sounds like it belongs in a science fiction movie. In reality it’s housed in a clean room operated by SMU’s Department of Physics, where SMU physicist Jodi Cooley and her students rely on it as part of their search for dark matter.

Cooley is a member of the global scientific consortium called SuperCryogenic Dark Matter Search (SuperCDMS). SuperCDMS is searching for elusive dark matter — the “glue” that represents 85 percent of the matter in our universe but which has never been observed.

SuperCDMS operates a particle detector in an underground abandoned mine in Minnesota. The detector is designed to capture a glimpse of WIMPS (Weakly Interacting Massive Particles), which some physicists theorize constitutes dark matter. WIMPS are particles of such low mass that they rarely interact with ordinary matter, making them extremely difficult to detect.

Now SuperCDMS plans to build a larger and even more sensitive detector for deployment at SnoLab, an even deeper underground mine near Ontario, Canada. To prepare, Cooley’s team will advance analysis techniques and help determine ultra pure construction materials to increase the detector’s sensitivity to dark matter interactions.

In testing materials, Cooley’s team measures how much radon or radioactivity occurs as background interference on a sample. SuperCDMS scientists try to minimize background interference to improve the chances of observing WIMPS.

To assess background, Cooley and her team rely on the high-tech XIA Alpha Particle Counter. SMU is one of only five entities in the world to house the XIA.

An assistant professor in the SMU Department of Physics, Cooley was recently recognized by the National Science Foundation with its prestigious Faculty Early Career Development Award. The NSF awarded Cooley a 5-year, $1 million research grant toward her SuperCDMS dark matter research. Students assisting in the XIA counting include Bedile Karabuga, doctoral student, and Mayisha Nakib, first year.

What’s the importance of background?
Cooley: For people who are older, they’ll remember back before digital TVs to analog TVs. Sometimes you’d turn to a channel and it would be fuzzy, so you’d play with the antenna, play with the contrast. That’s sort of the same thing going on in our detectors.

We want our detectors to produce a clear image of dark matter. But we have a lot of background or static and fuzz getting in the way. So we have a bag of tricks for removing that static or fuzz to help us see if the dark matter interacts in our detectors.

Just like the TV, we don’t want to start with a channel that’s completely snow, but a channel that’s sort of coming in. You want to reduce the background as much as possible. That’s what we’re doing with SuperCDMS. So the studies we’re doing are trying to reduce the background around the instrument by selecting ultra pure material with which to construct the instrument.

The background is from radioactivity, cosmic rays, and just from the fact there are particles around us all the time. So we try to minimize them as much as possible. Even our finger essentially would introduce radioactivity onto our detectors.

How important are ultra pure materials?
Cooley: This is very critical. We’re looking for a very rare occurrence: dark matter interacting in these detectors. Radioactivity interferes with our ability to observe dark matter. The radioactivity in most materials is much higher than the rate of dark matter interactions. So we try to get the purest materials we can find. To describe how pure a material we’re seeking, it helps to know that a banana would be more radioactive. Touching the detectors with our fingers, because our fingers have potassium on them, would ruin the experiment. We’re looking for very trace levels of radioactivity in materials.

To select the best, we try to count the rate of radioactive decays in materials. Our SuperCDMS collaboration has several types of counters, and different ways and techniques to calculate a material’s radioactivity. Here at SMU in the LUMINA Lab — Laboratory for Ultra Pure Material Isotope and Neutron Assessment — we have the XIA counter, which we’ve named Peruna.

Where do neutrons enter the picture?
Cooley: Neutrons are nearly impossible to distinguish from dark matter in our detectors. They also form background. My postdoctoral researcher Silvia Scorza and SMU graduate student Hang Qiu are both characterizing neutrons that come from the materials. That’s primarily done through simulations. So once we have rates of these types of interactions, we can generate through simulations what this would mean for the experiment. That helps us determine the right materials.

How does the XIA work?
Cooley: The instrument is essentially a drift chamber. We put a material sample on the surface of a tray in the chamber. An electric field goes through the instrument. When the charged particles give off radioactivity in the electric field they drift upward, and then we can measure the energy of the particles and the number of them from any given sample.

Can that be challenging?
Cooley: It’s not trivial. There are subtleties in the instrument. In trying to understand the data and trying to get an accurate count off certain types of materials such as plastics, we have to decide on certain conditions, like how long should the purging process last.

Why is there more than one dark matter experiment in the world?
Cooley: Dark matter is an important question and there are a variety of experiments using different techniques to solve the question. It’s not enough for one technique and one experiment to say they’ve made a discovery. It always has to be verified and looked at by another experiment, independently, with a different technique. If different techniques and different instruments prove the finding, then you can have a lot more confidence in the result. — Margaret Allen

Tags Dedman College, Jodi Cooley, SMU Department of Physics

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Quantum Diaries: Cleaning the world’s biggest machine

Post author By Margaret Allen
Post date March 22, 2012

SMU postdoctoral researcher Aidan Randle-Conde, SMU Department of Physics, posted about his experience working at CERN on the blog Quantum Diaries. His March 6 entry details his thoughts about “Cleaning the world’s biggest machine,” CERN’s Atlas detector.

Researchers at Switzerland-based CERN, the largest high-energy physics experiment in the world, have been seeking the elusive fundamental particle the Higgs boson since it was theorized in the 1960s. The so-called “God” particle is believed to play a fundamental role in solving the important mystery of why matter has mass.

Thousands of scientists from around the world seek evidence of the Higgs particle through experiments at CERN’s Large Hadron Collider. The researchers analyze a flood of electronic data streaming from the breakup of speeding protons colliding in the massive particle accelerator.

Read Randle-Conde’s Quantum Diaries blog post.

EXCERPT:

ATLAS Control Room, Aidan Randle-Conde — Our shift starts with a briefing in the control room.

By Aidan Randle-Conde
Quantum Diaries
Tuesday, March 6th, 2012
Today I spent much of my time crawling around on hands and knees, picking pieces of rubbish from the innards of the ATLAS detector. It’s just one of those things that comes with the job and gives you a different view of the experiment (literally.) Before we start taking data we need to make sure that the ATLAS cavern is clean and safe. I call this process “Grooming the Beast”.

The ATLAS detector is housed in the ALTAS cavern, just behind the Globe at CERN. The journey down is long (more than 100 meters) and convoluted, with all kinds of doorways, locks, passages and elevators. Work has been taking place in the cavern during the winter shutdown to make improvements and sort out minor problems with the detector. Is a piece of the hardware getting damaged by interactions with matter? This is an excellent time to replace it!

Some of the team survey the work ahead of them.

Cleaning the cavern just as people start to leave it may seem like an unusual thing to do, but it serves a very important purpose. There has been a lot of work to improve the detector during the shutdown, and this leaves some debris. The engineers clear up as much as they can as they go along, but the odd screw or piece of wire goes missing, and over the months this builds up. The real danger to the machine is metal debris. The detector contains large magnets and these can interact with metallic objects lying around. They need to be removed before we turn on and take data!

Read Randle-Conde’s Quantum Diaries blog post.

SMU has a team of researchers led by SMU Physics Professor Ryszard Stroynowski working on the CERN experiment. The team includes three other Physics Department faculty: Jingbo Ye, Robert Kehoe and Stephen Sekula, six postdoctoral fellows, including Randle-Conde, and five graduate students.

Quantum Diaries, as the site explains, “is a Web site that follows physicists from around the world as they experience life at the energy, intensity and cosmic frontiers of particle physics. Through their bios, videos, photos and blogs, the diarists offer a personal look at the daily lives of particle physicists.”

Tags Aidan Randle-Conde, Dedman College, SMU Department of Physics

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Tiny optoelectronic module plays a key role in the world’s largest physics experiments; new module will be 75 times faster than the current fiber-optic data link on Large Hadron Collider’s ATLAS experiment

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Radioactivity interferes with our ability to observe dark matter. A banana would be more radioactive than the materials we use for our experiment. — Jodi Cooley

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