SBU Coach Chuck Priore on right. Photo by Jim Harrison/Stony Brook Athletics
The Stony Brook football team is set to play an untraditional season this spring. And head coach Chuck Priore is bullish on the Seawolves’ potential during a six-game CAA schedule that begins in March. “Overall, as a team, I’m excited,” Priore said on a kickoff CAA Football conference call on Wednesday.
The Seawolves, who begin official practices Feb. 5, return a dozen starters from a 2019 squad that produced its signature win against fifth-ranked Villanova.
Fields engineered three game-winning or game-tying fourth-quarter drives last season en route to one of the best seasons from a quarterback in school history. He recorded a program single-season-record 2,809 yards of total offense. His 2,471 passing yards ranked second most, trailing only T.J. Moriarty (2,495 in 2004). Fields also tossed 16 touchdowns and rushed for four more. He accumulated 338 rushing yards.
“The interesting thing was he had the opportunity all spring and summer to study himself. He got drill work when he was home from our quarterback coach to do,” Priore said. “The biggest thing ended up becoming his accuracy — and his improvement in that [area of the] game. His play-action game was lights out for us, his ability to throw the ball up the field, yards per reception. But he needed to become more accurate. And I think those are the things we worked on. We saw great improvement.
“He’s been part of the team now as a starter. He’s captain. And he knows he has the fall [2021 season too], which he is coming back for us. It’s a win for all of us.”
Lawton earned Freshman All-American honors from Phil Steele in 2019 after tallying 648 yards and seven touchdowns on 152 carries.
Nunez already has been tabbed a second-team Preseason All-American from HERO Sports and Stats Perform as well as first-team Preseason All-CAA Football by Phil Steele.
Catapano has been selected a co-captain after seeing action in all 12 games and making nine starts in 2019.
Morrison actually is moving to free safety to anchor the defense because Priore felt the squad had great depth at the corner position.
On special teams, Aussie punter Mitchell Wright returns as the first-stringer. Kamara was granted an additional year of eligibility by the NCAA after suffering a season-ending injury five games into the 2019 schedule.
“We think he’s a next-level guy,” Priore said.
Kamara, Burns and Dimanche have been tabbed second-team Preseason All-CAA Football by Phil Steele.Contressa is first-team Preseason All-CAA Football by that same publication.
“Defensively we have six linebackers — two by transfer, two by freshmen getting older and two who were in the program last year,” Priore said. “We’re really excited about that position.”
The Seawolves also will be bolstered by tight end Tyler Devera (Maryland transfer) and wide receivers Hunter Hayek (Rutgers) and Malik Love (New Hampshire).
The season consists of six conference games, with the CAA split into North and South divisions.
“This has been a team that has attacked it with a passion for success,” Priore said. “I think it built great team morale when we got back here in the fall after being apart.”
The Public Libraries of Suffolk County announced last week that it reached a record-breaking 2.7 million eBook checkouts on Live-brary.com during 2020.This achievement is no surprise to many, as 2020 lead to the increased growth and importance of library digital lending of eBooks and audiobooks while many buildings were closed due to the global pandemic. Live-brary, consisting of 56 libraries in Suffolk County, is one of 102 public library systems worldwide that surpassed one million checkouts.
The Public Libraries of Suffolk County have been providing readers 24/7 access to eBooks and audiobooks for several years through OverDrive and its award-winning Libby reading app.Reader interest has grown every year.
“This past year, though difficult, Suffolk libraries have demonstrated their commitment to readers wherever they may be through Live-brary’s eBook and audiobook collections providing much needed access to entertainment and learning opportunities,” said Kevin Verbesey, Director of the Suffolk Cooperative Library System.
The highest circulating title Live-brary readers borrowed through OverDrive in 2020 was Where the Crawdads Sing by Delia Owens.The top-circulating genre, romance, represents the most popular in a vast catalog that also includes thrillers, biographies, children/young adult and more.
The top five eBook titles borrowed through Live-brary’s digital collection in 2020:
1. Where the Crawdads Sing by Delia Owens
2. The Giver of Stars by Jojo Moyes
3. American Dirt by Jeanine Cummins
4. Little Fires Everywhere by Celeste Ng
5. Educated by Tara Westover
The top five audiobook titles borrowed through Live-brary’s digital collection in 2020:
1. Where the Crawdads Sing by Delia Owens
2. Harry Potter and the Sorcerer’s Stone by J.K. Rowling
3. Becoming by Michelle Obama
4. American Dirt by Jeanine Cummins
5. The Dutch House by Ann Patchett
Readers in Suffolk County just need a valid library card to access digital books from Live-brary’s OverDrive-powered digital collection.Readers can use any major device, including Apple®, Android™, Chromebook™ and Kindle® (US only).Visit https://live-brary.com/overdrive.com/ or download the Libby app to get started and borrow eBooks and audiobooks anytime, anywhere.
This article first appeared in Prime Times, a supplement of TBR News Media, on Jan. 28, 2021.
Teresa Habacker, MD, FAAOS, FASSH and her practice, East End Hand Center, have joined Stony Brook Medicine Community Medical Group, Stony Brook Medicine’s expanding network of community practices.
“We are happy to welcome Dr. Habacker to a more inclusive role in Stony Brook Medicine. For more than five years, Dr. Habacker has served the Stony Brook Medicine community on the hand surgery/trauma team and the Hand Surgery Fellowship Training Program,” said Lawrence Hurst, MD, Professor and Chair of Orthopaedics, Chief of Hand Surgery at Stony Brook Medicine. “In our new relationship, we look forward to expanding her role in these areas, as well as the Center for Musculoskeletal Health, providing world-class care to patients on the East End.”
Dr. Habacker is a board-certified orthopedic surgeon with an additional certification in hand surgery. She provides comprehensive orthopedic care in Mattituck, Port Jefferson, Southampton and Wading River.
“I have had the pleasure of working with Dr. Hurst and the hand surgery team,” said Dr. Habacker. “I am pleased to be a part of the Center for Musculoskeletal Health and I look forward to working with the local physicians and ancillary teams as I continue to serve the communities on the East End of Long Island.”
Dr. Habacker completed her medical degree at the Medical College of Virginia in Richmond, VA. She completed her surgical residency at SUNY Downstate Medical School in Brooklyn, NY and her orthopedic surgical residencies at Louisiana State University in New Orleans, LA and Long Island Jewish Medical Center in New Hyde Park, NY. Dr. Habacker then went on to complete a hand surgery fellowship at Thomas Jefferson University in Philadelphia, PA. She is an Assistant Clinical Professor and has admitting privileges at Stony Brook University Hospital, Catholic Health Services and Northwell Health hospitals in Suffolk County.
East End Hand Center is accepting new patients. Office hours are Monday through Friday. To make an appointment, call 631-473-4263.
About Stony Brook Medicine
Stony Brook Medicine integrates and elevates all of Stony Brook University’s health-related initiatives: education, research and patient care. It includes five Health Sciences schools — Dental Medicine, Health Technology and Management, Medicine, Nursing and Social Welfare — as well as Stony Brook University Hospital, Stony Brook Southampton Hospital, Stony Brook Eastern Long Island Hospital, Stony Brook Children’s Hospital and more than 230 community-based healthcare settings throughout Suffolk County. To learn more, visit www.stonybrookmedicine.edu
About Stony Brook Medicine Community Medical Group
Stony Brook Medicine Community Medical Group, an arm of Stony Brook Medicine, includes over 35 community practices with over 50 locations across Long Island, from Farmingdale to Greenport. We offer exceptional care by more than 100 providers in 18 specialties committed to enhancing medical care coordination in the community. To learn more, visit sbcommunitymedical.org
From left, Richelle Rugolo and Debbie Loggia (Photo from Jefferson's Ferry)
Jefferson’s Ferry in South Setauket recognized two employees for their outstanding commitment and exceptional care and leadership at the award-winning life plan community located at One Jefferson Ferry Drive. Director of Nursing Richelle Rugolo was named Manager of the Year and Certified Nursing Assistant Debbie Loggia was named Employee of the Year. The announcement was made by Jefferson’s Ferry CEO Bob Caulfield.
“2020, though one of the most challenging we’ve faced due to COVID-19, showcased the caliber, dedication, and heart of our employees,” said Caulfield. “Individuals like Richelle and Debbie protect and care for our residents, inspire our teams, and exceed the high standards we set for ourselves as a premier life plan community.”
Rugolo has served as the director of nursing at Jefferson’s Ferry for six years. Under her leadership, Jefferson’s Ferry has resulted in an overall 5 Star Rating by The Centers for Medicare and Medicaid Services (CMS), and was named a “Best Of” nursing home by U.S. News & World Report.
“Richelle consistently strives for exceptional outcomes and manages performance to the highest standards which are reflected in the results of our third-party satisfaction surveys and NY State Department of Health surveys,” said Caulfield. “She’s a respected professional whose sound leadership created a safe haven for both residents and staff.”
Loggia joined Jefferson’s Ferry as a certified nursing assistant in 2011. “Debbie is a dedicated and respected member of the nursing team, who cares for residents with a smile and a positive attitude,” said Caulfield.
Residents and families express their respect and appreciation for Debbie through surveys and positive messages, and recognize her as an advocate, always trying to better accommodate residents’ needs.
The Ward Melville Heritage Organization in Stony Brook will offer a new Master Class series, “Here for You,” which will take place each month, from January to June.
“Here for You” will feature everything that Stony Brook Village has to offer to Long Islanders. Participants will be able to choose the format that is most enjoyable for them — in person or virtually.
Learn floral arrangement techniques with the owner of Village Florist and Events in Stony Brook Village on Jan. 29. Photo from WMHO
Subscriptions for the entire series is $85 per person, which includes a “taste kit” from the Crushed Olive, a “Stony Brook Village Booklet” with insider tips from experts in cooking, mindfulness exercises, floral arrangements and photography, and special “hot” deals throughout Stony Brook Village.
Participants will be a part of six content-rich experiences that span across the arts, health, science, history and culture. The monthly series will include virtual tours of Madagascar, South America and Europe, culinary lessons, open-air guided tours of Stony Brook Village, and much more.
The first class of the series, which will take place on Friday, January 29, is titled “The Power of Flowers” and features the Village Florist and Events owner Amanda Haggquist. In this virtual workshop, participants will utilize a floral arrangement kit, learn about popular winter flowers and arrangement techniques, and discover the origins of flower arranging. This class is available without the seasonal subscription at $20 per person.
Upcoming programs include guest appearances by Mona Rossero, owner of the Crushed Olive; Guy Reuge, the Executive Chef of the Mirabelle Restaurant; primatologist Patricia Wright and her husband, wildlife photographer Noel Rowe; and professional meditation and spirituality guide, Michael Opisso.
To learn more about the “Here for You” series and to register, call 631-751-2244.
Online education has been part of the School of Nursing since 1994. Photo from Stony Brook Medicine
For the second year in a row, the Stony Brook University School of Nursing’s Online Master’s Program was ranked in the top 10 schools nationwide by the U.S. News and World Report in its 2021 College Rankings.
The program has remained in the top 20 for online graduate nursing programs in all but one of the past eight years. In 2020, the program was ranked 7th and in 2021 ranked 9th in the list of Best Online Master’s in Nursing Programs. Officials at the school say the change in ranking from last year to this year may be due to the slight decline in faculty numbers because additional hiring remained difficult due to the pandemic.
The School of Nursing began offering online education in 1994. It started with a Midwifery program and developed into an array of other nurse practitioner education programs. This led to more than 25 years of developing and refining innovative online programs to provide a firm foundation of new online learning applications for nurses and future nurses.
“Our longstanding experience became critical to continued success with online learning this past year in responding to the health care needs and educational changes during the pandemic,” says Annette Wysocki, PhD, RN, FAAN, Dean of the School of Nursing. “Our constant attention to content and presentation methods provides students with visual, graphic and other ways to access content, and this even includes active engagement with simulated clinical experiences within online educational platforms.”
According to U.S. News, online graduate nursing data used as methodology to calculate the rankings included five areas of data: engagement (30 percent); expert opinion (20 percent); faculty credentialing and training (20 percent); services and technologies (20 percent); and student excellence (10 percent).
For more details about the methodology, see this link.
Results from a study of clouds and aerosols conducted in the Azores revealed that new particles can seed the formation of clouds in the marine boundary layer—the atmosphere up to about a kilometer above Earth's surface—even over the open ocean, where the concentration of precursor gases was expected to be low. Image courtesy of the U.S. Department of Energy Atmospheric Radiation Measurement (ARM) user facility.
Understanding previously undocumented source of new particle formation will improve models of aerosols, clouds, and their impact on Earth’s climate
New results from an atmospheric study over the Eastern North Atlantic reveal that tiny aerosol particles that seed the formation of clouds can form out of next to nothingness over the open ocean. This “new particle formation” occurs when sunlight reacts with molecules of trace gases in the marine boundary layer, the atmosphere within about the first kilometer above Earth’s surface. The findings, published in the journal Nature Communications, will improve how aerosols and clouds are represented in models that describe Earth’s climate so scientists can understand how the particles—and the processes that control them—might have affected the planet’s past and present, and make better predictions about the future.
“When we say ‘new particle formation,’ we’re talking about individual gas molecules, sometimes just a few atoms in size, reacting with sunlight,” said study co-author Chongai Kuang, a member of the Environmental and Climate Sciences Department at the U.S. Department of Energy’s Brookhaven National Laboratory. “It’s interesting to think about how something of that scale can have such an impact on our climate—on how much energy gets reflected or trapped in our atmosphere,” he said.
Using an aircraft outfitted with 55 atmospheric instrument systems, scientists traversed horizontal tracks above and through clouds and spiraled down through atmospheric layers to provide detailed measurements of aerosols and cloud properties. The aircraft data were supplemented by measurements made by ground-based radars and other instruments. Image courtesy of the U.S. Department of Energy Atmospheric Radiation Measurement (ARM) user facility.
But modeling the details of how aerosol particles form and grow, and how water molecules condense on them to become cloud droplets and clouds, while taking into consideration how different aerosol properties (e.g., their size, number, and spatial distribution) affect those processes is extremely complex—especially if you don’t know where all the aerosols are coming from. So a team of scientists from Brookhaven and collaborators in atmospheric research around the world set out to collect data in a relatively pristine ocean environment. In that setting, they expected the concentration of trace gases to be low and the formation of clouds to be particularly sensitive to aerosol properties—an ideal “laboratory” for disentangling the complex interactions.
“This was an experiment that really leveraged broad and collaborative expertise at Brookhaven in aerosol observations and cloud observations,” Kuang said. Three of the lead researchers—lead authors Guangjie Zheng and Yang Wang, and Jian Wang, principal investigator of the Aerosol and Cloud Experiments in the Eastern North Atlantic [https://www.arm.gov/publications/backgrounders/docs/doe-sc-arm-16-020.pdf] (ACE-ENA) campaign—began their involvement with the project while working at Brookhaven and have remained close collaborators with the Lab since moving to Washington University in St. Louis in 2018.
Land and sea
Brookhaven Lab atmospheric scientist Chongai Kuang (center) with Art Sedlacek (left) and Stephen Springston (right) aboard ARM’s Gulfstream-159 (G-1) aircraft during a 2010 atmospheric sampling mission that was not part of this study. Image courtesy of the U.S. Department of Energy Atmospheric Radiation Measurement (ARM) user facility.
The study made use of a long-term ground-based sampling station on Graciosa Island in the Azores (an archipelago 850 miles west of continental Portugal) and a Gulfstream-1 aircraft outfitted with 55 atmospheric instrument systems to take measurements at different altitudes over the island and out at sea. Both the ground station and aircraft belong to the DOE Office of Science’s Atmospheric Radiation Measurement (ARM) user facility [https://www.arm.gov/], managed and operated by a consortium of nine DOE national laboratories.
The team flew the aircraft on “porpoise flights,” ascending and descending through the boundary layer to get vertical profiles of the particles and precursor gas molecules present at different altitudes. And they coordinated these flights with measurements taken from the ground station.
The scientists hadn’t expected new particle formation to be happening in the boundary layer in this environment because they expected the concentration of the critical precursor trace gases would be too low.
“But there were particles that we measured at the surface that were larger than newly formed particles, and we just didn’t know where they came from,” Kuang said.
The aircraft measurements gave them their answer.
Many of the choreographed flight paths for this study traversed the open ocean and also crossed within the ranges of the ground-based scanning radars at DOE’s Atmospheric Radiation Measurement (ARM) Climate Research Facility on Graciosa Island in the Azores. Image courtesy of the U.S. Department of Energy Atmospheric Radiation Measurement (ARM) user facility.
“This aircraft had very specific flight patterns during the measurement campaign,” Kuang said. “They saw evidence that new particle formation was happening aloft—not at the surface but in the upper boundary layer.” The evidence included a combination of elevated concentrations of small particles, low concentrations of pre-existing aerosol surface area, and clear signs that reactive trace gases such as dimethyl sulfide were being transported vertically—along with atmospheric conditions favorable for those gases to react with sunlight.
“Then, once these aerosol particles form, they attract additional gas molecules, which condense and cause the particles to grow to around 80-90 nanometers in diameter. These larger particles then get transported downward—and that’s what we’re measuring at the surface,” Kuang said.
“The surface measurements plus the aircraft measurements give us a really good spatial sense of the aerosol processes that are happening,” he noted.
At a certain size, the particles grow large enough to attract water vapor, which condenses to form cloud droplets, and eventually clouds.
Both the individual aerosol particles suspended in the atmosphere and the clouds they ultimately form can reflect and/or absorb sunlight and affect Earth’s temperature, Kuang explained.
Study implications
Framed by a brilliant rainbow, ARM’s Gulfstream-159 (G-1) research aircraft sits on the tarmac on Terceira Island during the Aerosol and Cloud Experiments in the Eastern North Atlantic (ACE-ENA) winter 2018 intensive operation period in the Azores. Image courtesy of the U.S. Department of Energy Atmospheric Radiation Measurement (ARM) user facility.
So now that the scientists know new aerosol particles are forming over the open ocean, what can they do with that information?
“We’ll take this knowledge of what is happening and make sure this process is captured in simulations of Earth’s climate system,” Kuang said.
Another important question: “If this is such a clean environment, then where are all these precursor gases coming from?” Kuang asked. “There are some important precursor gases generated by biological activity in the ocean (e.g., dimethyl sulfide) that may also lead to new particle formation. That can be a nice follow-on study to this one—exploring those sources.”
Understanding the fate of biogenic gases such as dimethyl sulfide, which is a very important source of sulfur in the atmosphere, is key to improving scientists’ ability to predict how changes in ocean productivity will affect aerosol formation and, by extension, climate.
The research was funded by the DOE Office of Science, DOE’s Atmospheric System Research, and by NASA. In addition to the researchers from Brookhaven Lab and Washington University, the collaboration included scientists from Pacific Northwest National Laboratory; Missouri University of Science and Technology; the University of Washington, Seattle; NASA Langley Research Center; Science Systems and Applications Inc. in Hampton, Virginia; the Max Planck Institute for Chemistry in Mainz, Germany; and the Scripps Institution of Oceanography, University of California, San Diego.
Brookhaven National Laboratory is supported by the Office of Science of the U.S. Department of Energy. The Office of Science is the single largest supporter of basic research in the physical sciences in the United States, and is working to address some of the most pressing challenges of our time. For more information, please visit science.energy.gov [https://www.energy.gov/science/office-science].
From left to right; Edna Louise Spears Elementary School Students Clara Pearce, Kemp Garrett and Nina Gnatenko. Photo from PJSD
Fifth grade students in Port Jefferson’s Edna Louise Spear Elementary School have been learning the engineering design process. They have used their skills to construct pompom launchers with a set number of simple objects including straws, popsicle sticks, tape, string and plastic cups to see how far their experiments could go.
As engineers, they examined the materials they could use, came up with their designs and moved on to building, testing, modifying and testing again.
The students in Kari Costanzo’s class conducted an informal contest to see who developed the simplest and cheapest one (Nina Gnatenko), the sturdiest one (Kemp Garrett) and the one that went the farthest (Clara Pearce).
Students in Michelle Landetta's class. Photo from PJSD
It’s no wonder Port Jefferson Middle School students have been treating one another with more empathy, compassion and acceptance.
Students in Michelle Landetta’s class read R. J. Palacio’s bestselling book “Wonder” together, discussed its theme and steps they can take to promote kindness to others. Students and staff decorated and wrote inspirational quotes, positive affirmations and words of hope on the popsicle sticks that were provided to them.
They then created a “PJMS – We Stick Together” bulletin board right in a hallway of the school for all to not only admire their creative work, but to share in their refreshing ideas and promote everyone’s appreciation for the simple and joyful act of friendship.
Accelerator physicist Chuyu Liu, the run coordinator for this year's experiments at the Relativistic Heavy Ion Collider (RHIC), in the Main Control Room of the collider-accelerator complex at Brookhaven National Laboratory.
Final stage of Beam Energy Scan II will collect low-energy collision data needed to understand the transition of ordinary nuclear matter into a soup of free quarks and gluons
Accelerator physicists are preparing the Relativistic Heavy Ion Collider (RHIC), a DOE Office of Science user facility for nuclear physics research at DOE’s Brookhaven National Laboratory, for its 21st year of experiments, set to begin on or about February 3. Instead of producing high-energy particle smashups, the goal for this run is to maximize collision rates at the lowest energy ever achieved at RHIC.
STAR co-spokesperson Lijuan Ruan noted that this year’s run is the third and final leg of Beam Energy Scan II, a systematic study of RHIC collisions at low energies.
“Run 21 is the final step of Beam Energy Scan II (BES-II), a three-year systematic study of what happens when gold ions—gold atoms stripped of their electrons—collide at various low energies,” said Brookhaven physicist Lijuan Ruan, co-spokesperson for RHIC’s STAR experiment collaboration.
Nuclear physicists will examine the BES-II data, along with data from RHIC’s high-energy collisions, to map out how these collisions transform ordinary protons and neutrons into an extraordinary soup of free quarks and gluons—a substance that mimics what the early universe was like some 14 billion years ago. By turning the collision energy down, RHIC physicists can change the temperature and other variables to study how these conditions affect the transition from ordinary matter to early-universe hot quark-and-gluon soup.
“Out of the five energies of BES-II—9.8, 7.3, 5.75, 4.6, and 3.85 billion electron volts, or GeV—this year’s run at 3.85 GeV is the most difficult one,” said Brookhaven Lab accelerator physicist Chuyu Liu, the run coordinator. That’s because “RHIC’s beams of gold ions are really difficult to hold together at the lowest energy,” he explained.
In Run 21, the accelerator team will use a variety of innovative components and schemes to maintain the lifetime and intensity of the colliding ion beams under challenging conditions. Read on to learn more about RHIC’s Run 21 science goals and the accelerator features that will make the science possible.
Scanning the transition
Mapping nuclear phase changes is like studying how water changes under different conditions of temperature and pressure (net baryon density for nuclear matter). RHIC’s collisions “melt” protons and neutrons to create quark-gluon plasma (QGP). STAR physicists are exploring collisions at different energies, turning the “knobs” of temperature and baryon density, to look for signs of a “critical point.” That’s a set of conditions where the type of transition between ordinary nuclear matter and QGP changes from a smooth crossover observed at RHIC’s highest energies (gradual melting) to an abrupt “first order” phase change that’s more like water boiling in a pot.
As Ruan explained, the quest to map out the phases of nuclear matter and the transitions between them is somewhat similar to studying how water molecules transform from solid ice to liquid water and gaseous steam at different temperatures and pressures. But nuclear matter is trickier to study.
“We need a powerful particle collider and sophisticated detector systems to create and study the most extreme forms of nuclear matter,” she said. “Thanks to the incredible versatility of RHIC, we can use the ‘knob’ of collision energy and the intricate particle-tracking capabilities of the STAR detector to conduct this systematic study.”
RHIC’s highest collision energies (up to 200 GeV) produce temperatures more than 250,000 times hotter than the center of the Sun. Those collisions “melt” the protons and neutrons that make up gold atoms’ nuclei, creating an exotic phase of nuclear matter called a quark-gluon plasma (QGP). In QGP, quarks and gluons are “free” from their ordinary confinement within protons and neutrons, and they flow with virtually no resistance—like a nearly perfect liquid.
But QGP lasts a mere fraction of a second before “freezing out” to form new particles. RHIC physicists piece together details of how the melting and refreezing happen by taking “snapshots” of the particles that stream out of these collisions.
By systematically lowering the collision energy, the physicists are looking for signs of a so-called “critical point.” This would be a set of conditions where the type of transition between ordinary nuclear matter and QGP changes from the smooth crossover observed at RHIC’s highest energies (picture butter melting gradually on a counter), to an abrupt “first order” phase change (think of how water boils suddenly at a certain temperature and holds that temperature until all the molecules evaporate).
As physicists turn RHIC’s collision energy down, they expect to see large event-by-event fluctuations in certain measurements—similar to the turbulence an airplane experiences when entering a bank of clouds—as conditions approach a “critical point” in the nuclear phase transition. This year’s run at the lowest collision energy will contribute to this search.
“Theorists have predicted that certain key measurements at RHIC will exhibit dramatic event-by-event fluctuations when we approach this critical point,” Ruan said.
Some RHIC physicists liken these fluctuations to the turbulence an airplane experiences when it moves from smooth air into a bank of clouds and then back out again. Measurements from phase I of RHIC’s Beam Energy Scan (BES-I, with data collected between 2010 and 2017) revealed tantalizing hints of such turbulence. But because collisions are hard to achieve at low energies, the data from BES-I aren’t strong enough to draw definitive conclusions.
Now, in BES-II, a host of accelerator improvements have been implemented to maximize low-energy collision rates.
Cooling the ions
One of the innovations that Chuyu Liu and the other Collider-Accelerator Department (C-AD) physicists managing RHIC operations will take advantage of in Run 21 is a first-of-its-kind beam-cooling system. This Low Energy RHIC electron Cooling (LEReC) system operated at full capacity for the first time in last year’s RHIC run, making it the world’s first implementation of electron cooling in a collider. But it will be even more important for the lowest-of-low collision energies this year.
“The longer the beam stays at low energy, the more ‘intra-beam scattering’ and ‘space charge’ effects degrade the beam quality, reducing the number of circulating ions,” said Liu. Simplistic translation: The positively charged ions tend to repel one another. (Remember: The ions are atoms of gold stripped of their electrons, leaving a lot of net positive charge from the 79 protons in the nucleus.) The scattering and the repulsive space charge cause the ions to spread out, essentially heating up the beam as it makes its way around the 2.4-mile-circumference RHIC accelerator. And spread-out ions are less likely to collide.
A host of accelerator improvements have been implemented to maximize RHIC’s low-energy collision rates. These include a series of components that inject a stream of cool electron bunches into the ion beams in these cooling sections of the two RHIC rings. The cool electrons extract heat to counteract the tendency of RHIC’s ions to spread out, thereby maximizing the chances the ions will collide when the beams cross at the center of RHIC’s STAR detector.
“The LEReC system operates somewhat similar to the way the liquid running through your home refrigerator extracts heat to keep your food cool,” said Wolfram Fischer, Associate Chair for Accelerators in C-AD, “but the technology needed to achieve this beam cooling is quite a bit more complicated.”
A series of components (special lasers and a photocathode gun) produces bunches of relatively cool electrons, which are accelerated to match the bunching and near-light-speed pace of RHIC’s ions. Transfer lines inject the cool electrons into the stream of ion bunches—first in one RHIC ring, then, after making a 180-degree turn, into the other. As the particles mix, the electrons extract heat, effectively squeezing the spread-out ion bunches back together. The warmed-up electron bunches then get dumped and replaced with a new cool batch.
“To add more flexibility for cooling optimization during this year’s run at RHIC’s lowest energy, where the space-charge effects and beam lifetime degradation are concerns for both the electrons and the ions, we installed a new ‘second harmonic’ radiofrequency (RF) cavity in the electron accelerator,” said Alexei Fedotov, the accelerator physicist who led the LEReC project.
These cavities generate the radio waves that push the electrons along their path, with the higher (second harmonic) frequency helping to flatten out the longitudinal profile of the electron bunches. “This should help to reduce the space charge effect in the electron beams to achieve better cooling performance at low energy,” Fedotov said.
“We plan to commission the new electron beam transport line in late January and start cooling ions with the new electron beam setup in early February,” he added.
More accelerator advances
Similarly, third-harmonic RF cavities installed in the ion accelerator rings will help to flatten the longitudinal profile of the ion bunches, reducing their peak intensity and space charges, Liu explained. “With that, more bunch intensity can be injected into RHIC to produce higher luminosity—a measure closely tied to collision rates,” he said.
The accelerator team will also be commissioning a new bunch-by-bunch feedback system to help stabilize the beam for a better lifetime. “This system measures how each ion bunch deviates from the center of the beam pipe, and then applies a proportional correction signal through a component called a kicker to nudge each bunch back to where it should be,” Liu said.
All this cooling and nudging will counteract the ions’ tendency to spread, which maximizes chances of collisions happening when the two beams cross at the center of STAR.
“This run will bring together many of the advances we’ve been working on at RHIC to meet the challenging conditions of low-energy collisions,” said Fischer. “STAR would have preferred to test the lowest energy first, but we needed to learn everything possible (and develop the electron cooling system) before we could embark on operation at the most difficult energy.”
RHIC operations are funded by the DOE Office of Science.
Brookhaven National Laboratory is supported by the U.S. Department of Energy’s Office of Science. The Office of Science is the single largest supporter of basic research in the physical sciences in the United States and is working to address some of the most pressing challenges of our time. For more information, visit https://www.energy.gov/science/ [https://www.energy.gov/science/].
The highest circulating title Live-brary readers borrowed through OverDrive in 2020 was Where the Crawdads Sing by Delia Owens.
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