Banerjee elected for “seminal applied physics research on nanoscale materials, devices, interconnects, and circuits towards realizing ultra-low power electronics.”
The criterion for election as an APS Fellow is exceptional contributions to the physics enterprise; e.g., outstanding physics research, important applications of physics, leadership in or service to physics, or significant contributions to physics education. Fellowship is a distinct honor signifying recognition by one’s professional peers.
The membership of APS is diverse and global, and the Fellows of the APS should reflect that diversity. Fellowship nominations of women, members of underrepresented minority groups, and scientists from outside the United States are especially encouraged.
Xie elected for his for contributions to design automation and architecture of three-dimensional integrated circuits
Yuan Xie, Professor of ECE department, University of California, Santa Barbara, has been named an IEEE Fellow (class of 2015, effective 1 January 2015). He is being recognized for contributions to design automation and architecture of three-dimensional integrated circuits (3D ICs).
The IEEE Grade of Fellow is conferred by the IEEE Board of Directors upon a person with an outstanding record of accomplishments in any of the IEEE fields of interest. The total number selected in any one year cannot exceed one-tenth of one- percent of the total voting membership. IEEE Fellow is the highest grade of membership and is recognized by the technical community as a prestigious honor and an important career achievement.
Professor Xie is recognized as the world-class researcher in the areas of electronic design automation (EDA), computer architecture, VLSI design, and embedded systems. His most distinctive contributions lie in the revolutionary advances of design automation and architecture for three-dimensional integrated circuits (3D ICs), which offer new opportunities for system-level innovations that are not hinged only on technology scaling. He is recognized as the pioneer who have crossed traditional boundaries between architecture, design automation, and test for 3D ICs, and his cross-cutting research have made significant contributions to transform this emerging technology from research exploration to commercial adoption in semiconductor industry.
Prof Xie received BS degree and Ph.D. degree from Tsinghua University and Princeton University, respectively. He has worked for IBM and AMD, and was with Pennsylvania State University before joining UCSB in Fall 2014. He has published more than 200 scholarly articles in top journal and conference venues, and has received several Best Paper Awards (ICCAD, ASPDAC, ISLPED, ISVLSI, GLSVLSI) and several Best Paper Nominations (MICRO, HPCA, DATE, ASPDAC).
Ping Chi received the ACM SRC medal for her research project titled “Next-Generation Memory Design: Architecture-level and Application-level Perspectives.” She is advised by ECE Professor Yuan Xie.
The ACM SRC is sponsored by Microsoft Research and is an internationally recognized venue enabling undergraduate and graduate students who are ACM members to:
The ACM Special Interest Group on Design Automation (ACM SIGDA) organized this event in conjunction with the International Conference on Computer Aided Design (ICCAD) held in San Jose from Nov. 3-6, 2014.
Ping Chi, a 4th-year ECE Ph.D. student and co-author ECE Professor Yuan Xie receive the 2014 IEEE/ACM William J. McCalla ICCAD Best Paper Award.
Chi received the front-end design award for her paper titled “Using Multi-Level Cell STT-RAM for Fast and Energy-Efficient Local Checkpointing,” at the 2014 International Conference on Computer-Aided Design (ICCAD) held in San Jose, from Nov. 3-6, 2014. The paper was co-authored with Dr. Cong Xu (Penn State), Dr. Tao Zhang (Nvidia), Dr. Xiangyu Dong (Google), and her advisor Dr. Yuan Xie (UCSB).
Given in memory of William J. McCalla for his contributions to ICCAD and his CAD technical work throughout his career. The awards are split into three sections, two for the current year of the ICCAD conference and one for an ICCAD paper from 10 years prior. For the current year awards, one will be given for the best research paper covering the front-end of the design process and one will be given for the back-end of the design process. For the ten-year retrospective most influential paper, the award is given to the paper judged to be the most influential on research and industry practice in computer-aided design of integrated circuits over the ten years since its original appearance at ICCAD. The awards are jointly sponsored by IEEE Council on Electronic Design Automation (IEEE CEDA) and the ACM Speci al Interest Group on Design Automation (ACM SIGDA). The awards are decided by ICCAD Best Paper and Most Influential Awards Selection Committees and were first given in 2000.
“One Giant Step for Ocean Biodiversity” — the marine Biodiversity Observation Network in the Santa Barbara Channel has been established to addresses an information gap about marine habitats.
With 13 scientific investigators and 10 partner institutions, the marine biodiversity observation network (BON) centered on the Santa Barbara Channel is the epitome of collaboration. Funded with $5 million by NASA, the Bureau of Ocean Energy Management (BOEM) and the National Oceanic and Atmospheric Administration (NOAA), the UC Santa Barbara-led project officially kicked off Thursday, Oct. 23, at UCSB’s Marine Science Institute (MSI).
“We’ve got principal investigators here from two colleges, a professional school, over six different department on campus, as well our friends at NOAA,” said MSI Director Mark Brzezinski. “It’s an incredibly interdisciplinary team ranging from biology to engineering, and it’s no small feat to bring that kind of group together. Here at UCSB, we really pride ourselves on this kind of interdisciplinary work. It’s our normal mode of operation.”
Designed to fill a gap not addressed by NASA’s Group on Earth Observations (GEO) BON, which focuses on terrestrial biomes, this prototype marine BON seeks to eventually cover a huge range of biodiversity in the oceans. The effort begins in the Santa Barbara Channel where various groups have been gathering a breadth of scientific data ranging from intertidal monitoring to physical oceanographic measurements.
“There have been a huge number of observations taken over time in the channel,” said Robert Miller, a research biologist with MSI and a principal investigator of the marine BON. “The channel has also been a hotspot for remote sensing research, which gives us a wider picture of the area, which we can then match with in-situ observations.”
The marine BON has three goals: to integrate biodiversity data to enable inferences about regional biodiversity; to develop advanced methods in optical and acoustic imaging and to improve monitoring biodiversity in partnership with ongoing monitoring and research programs; and implement a tradeoff framework that optimizes allocation of sampling effort, given the cost of that effort and the information gained from it.
UCSB investigators involved in the project are B.S. Manjunath, director of UCSB’s Center for Bio-Image Informatics; Craig Carlson, chair of the Department of Ecology, Evolution and Marine Biology (EEMB); Deborah Iglesias-Rodriguez, an EEMB professor; Phaedon Kyriakidis, a professor in the Department of Geography; Kevin Lafferty, a principal investigator with MSI and a marine ecologist with the United States Geological Survey’s Western Ecological Research Center; Milton Love and Daniel Reed, research biologists with MSI; Douglas McCauley, an assistant professor in EEMB; Andrew Rassweiler, an assistant research biologist at MSI; and David Siegel, director of the Earth Research Institute. Additional investigators include Andrew Thompson of NOAA’s Southwest Fisheries Science Center.
UCSB scientists lead a team designing a network to track many species of marine organisms over time
Is life in the oceans changing over the years? Are humans causing long-term declines in ocean biodiversity with climate change, fishing and other impacts? At present, scientists are unable to answer these questions because little data exist for many marine organisms, and the small amount of existing data focuses on small, scattered areas of the ocean.
“Currently most of the information we have for marine species is on economically important species like fish and lobster,” said Robert Miller, a research biologist at UC Santa Barbara’s Marine Science Institute. “Little is known about the majority of species out there, even though they may be very important from an ecological point of view. A comprehensive observation network that looks at a broad suite of marine organisms would tell us how marine ecosystems as a whole are doing.”
A group of researchers from UCSB, the USGS, NOAA, National Marine Fisheries Service and UCSD’s Scripps Institution of Oceanography are creating a new prototype system — the Marine Biodiversity Observation Network — to solve this problem. The five-year project led by Miller will center on the Santa Barbara Channel, but the long-term goal is to expand the network around the country and around the world to track over time the biodiversity of marine organisms, from microbes to whales. After a highly competitive proposal process, NASA, the Bureau of Ocean Energy Management (BOEM) and NOAA chose to fund UCSB’s approximately $5 million project.
The Marine Biodiversity Observation Network will integrate existing data over large spatial scales using geostatistical models and will utilize new technology to improve knowledge of marine organisms. Scientists will rely on genetics to accomplish three goals: begin learning about the many kinds of microbes in our coastal waters; identify plankton that would otherwise have to be counted under the microscope over many, many hours; and detect larger animals such as whales and fish by looking for fragments of DNA they have shed into the water. This is known as environmental DNA or eDNA.
The group will use imaging to survey organisms such as kelp forests and deep reefs in underwater habitats where dive-time constraints limit the ability for firsthand exploration. To further this effort, UCSB’s Center for Bio-Image Informatics will use advanced image analysis to automatically identify different species including fish.
Electrical and Computer Engineering is one of the most popular disciplines with 90 graduate students among the 758 new graduate students entering UCSB. These incoming students are diverse in many ways, such as their ages, countries of origin, and fields of study.
Ehsan Omidi comes to UCSB all the way from Tehran, Iran. He earned both a bachelor of science and a master of science in electrical engineering from Amirkabir University of Technology in Tehran. He enters the Ph.D. program in electrical and computer engineering under guidance of Associate Professor Yasamin Mostofi with a concentration in control, communication, and signal processing.
Both of Omidi’s parents were schoolteachers, and he has always excelled in academics. Growing up, he had many of the same hobbies as his friends, including soccer, cartoons and video games.
“But,” he said, “my real hobby started when we had a computer in our home and I started programming with it. Since then, programming has been my main entertainment.”
When he realized that computer programming didn’t challenge him enough, he began to study electrical engineering in order to figure out what goes on inside a computer. He also worked on his university’s robotics team in creating a simple robot that could do funny tasks such as playing with a golf ball.
Omidi is very excited to be studying at UCSB, which is among the top 10 engineering schools in the world (Academic Ranking of World Universities). It also doesn’t hurt that Santa Barbara is, in Omidi’s words, “totally a perfect city.” He said, “Living in an always-sunny city with beautiful landscapes wherever you look and doing your desired research is what every grad student dreams.”
Omidi’s hobbies include soccer, violin and chess, and he hopes to add hiking and surfing in Santa Barbara to the list.
Eight researchers from the UCSB College of Engineering included in the 2014 Thomson Reuters report on the the most “Highly Cited researchers” in the world
Highly Cited Researchers 2014 represents some of world’s leading scientific minds. Over three thousand researchers earned the distinction by writing the greatest numbers of reports officially designated by Essential Science Indicators as Highly Cited Papers – ranking among the top 1% most cited for their subject field and year of publication, earning them the mark of exceptional impact.
UCSB College of Engineering researchers include:
U.S. News & World Report includes UC Santa Barbara in its annual listing of the “Top 30 Public National Universities” in the country, as well on its list of the “Best National Universities.” UCSB’s College of Engineering undergraduate program is also included in their list of “Best Programs at Engineering Schools Whose Highest Degree is a Doctorate.”
According to U.S. News & World Report, UCSB — which this year experienced the most competitive admissions process in campus history — has jumped to number 10 among the “Top 30 Public National Universities.” Among national universities, including both public and private institutions, UCSB moved up to number 40. The campus tied with Lehigh University.
In addition, the undergraduate program in UCSB’s College of Engineering is ranked number 36 on the U.S. News & World Report list of “Best Programs at Engineering Schools Whose Highest Degree is a Doctorate.” Among engineering schools at public universities, UCSB’s College of Engineering placed at number 20. UCSB is tied with the University of Colorado-Boulder, the University of Florida and the University of Notre Dame.
UC Santa Barbara Professors Kaustav Banerjee (ECE) & Samir Mitragotri (ChemE) and graduate student researcher Deblina Sarkar demonstrate atomically thin, ultrasensitive and scalable molybdenum disulfide field-effect transistor based biosensors and establish their potential for single-molecule detection
Move over, graphene. An atomically thin, two-dimensional, ultrasensitive semiconductor material for biosensing developed by researchers at UC Santa Barbara promises to push the boundaries of biosensing technology in many fields, from health care to environmental protection to forensic industries.
Based on molybdenum disulfide or molybdenite (MoS2), the biosensor material — used commonly as a dry lubricant — surpasses graphene’s already high sensitivity, offers better scalability and lends itself to high-volume manufacturing. Results of the researchers’ study have been published in ACS Nano.
“This invention has established the foundation for a new generation of ultrasensitive and low-cost biosensors that can eventually allow single-molecule detection — the holy grail of diagnostics and bioengineering research,” said Samir Mitragotri, co-author and professor of chemical engineering and director of the Center for Bioengineering at UCSB. “Detection and diagnostics are a key area of bioengineering research at UCSB and this study represents an excellent example of UCSB’s multifaceted competencies in this exciting field.”
The key, according to UCSB professor of electrical and computer engineering Kaustav Banerjee, who led this research, is MoS2’s band gap, the characteristic of a material that determines its electrical conductivity.