Integrated Research | Engineering Magazine

Integrated Research | Engineering Magazine
Semiconductors Bridge the Jonsson School’s Past, Present and Future
A Shared Vision
A group of four friends met after work at a neighborhood burger and brew joint located in Richardson, Texas. This gathering would not have been unusual, except for who attended —
Dr. Joseph Pancrazio
, vice president of research and innovation at The University of Texas at Dallas and professor of bioengineering; Dr. Bruce Gnade, previous vice president for research at UT Dallas from 2000 to 2017, professor emeritus of materials science and engineering and former
Distinguished Chair in Microelectronics
; Dr. Manuel Quevedo-Lopez, professor and head of the Department of Materials Science and Engineering and
Texas Instruments Distinguished University Chair in Nanoelectronics
and
Dr. Theodore Moise
, a retired technical roadmap manager from Texas Instruments Inc. (TI) who is now a research professor of materials science and engineering at UT Dallas.
From left to right members of the North Texas Semiconductor Institute (NTxSI) outside of the UT Dallas Natural Science and Engineering Research Laboratory (NSERL) include Dr. Manuel Quevedo-Lopez, director of the Center for Harsh Environments Semiconductor Systems (CHESS); Dr. Eden Zielinski, assistant director; Dr. Robert Baumann, research scientist; Dr. Rajni Aggarwal, research scientist; Dr. Bruce Gnade, director of semiconductor workforce development; and Dr. Theodore “Ted” Moise, director.
“We like to get together,” Quevedo-Lopez said. “Sometimes we talk about sports or how to make the perfect brisket. This time we started brainstorming about semiconductors. We had this idea for what became the North Texas Semiconductor Institute (NTxSI).”
This casual meeting sparked UT Dallas’ accelerated involvement in semiconductor research and workforce development in the North Texas region. Critical supply shortages of semiconductors affected the United States during the COVID-19 pandemic, largely because of disruptions to facilities overseas where the chips were produced or assembled.
“Semiconductors play a vital role in biomedical applications from neural engineering interfaces and flexible bioelectronics to precision sensors and instrumentation. The role of semiconductors has evolved for biomedical applications, and there is an emphasis on biocompatibility and other aspects that impact their efficacy in medical uses.”
— Dr. Shalini Prasad, professor and head of the Department of Bioengineering and Cecil H. and Ida Green Professor in Systems Biology Science
Dr. Shalini Prasad
“We wanted a hub for companies and students to conduct research and training,” Quevedo-Lopez said. “NTxSI is a place where anyone from North Texas who wants to come and do research is welcome, not only in traditional areas but also in emerging technology.”
Government leaders at both the federal and state levels recognized the national security need and committed bipartisan funding toward expanding the production of microchips in the United States through the federal
Creating Helpful Incentives to Produce Semiconductors (CHIPS) and Science Act
in 2022 and the
Texas CHIPS Act
in 2023.
“We wanted a hub for companies and students to conduct research and training ... not only in traditional areas, but also in emerging technology.”
— Dr. Manuel Quevedo-Lopez, Director of CHESS
Dr. Joseph
Pancrazio
Dr. Bruce
Gnade
Dr. Manuel
Quevedo-Lopez
Dr. Theodore
Moise
Companies like TI and GlobalWafers who sought to expand semiconductor production facilities noted a critical shortage of trained operators and technicians who need extensive hands-on preparation in advanced manufacturing curriculum. While these roles typically do not require a bachelor’s degree, University leaders saw an opportunity to lead more broadly, connecting North Texas semiconductor companies, community colleges and universities into a regional workforce development ecosystem — the North Texas Semiconductor Workforce Development Consortium.
“We listened to our industry partners and viewed this as a systems engineering problem,” Pancrazio said. “It’s opened many partnerships.”
He added, “We asked ourselves — do we work with community colleges? Do we make state-of-the-art facilities available, particularly facilities that these colleges would not be able to provide? We are a public institution, so we need to serve the public.”
“The Computer Science Department advances semiconductor innovation through cutting-edge research in AI/ML-supported hardware security, AI for chip design automation and research on next-generation technologies for high-performance computing architectures.”
— Dr. Ovidiu Daescu, professor and head of the Department of Computer Science and Jonsson School Chair
Dr. Ovidiu Daescu
Pancrazio supported a June 2023 grant from the U.S. Department of Education to fund and promote the workforce development consortium.
Moise notes that NTxSI has been fortunate to recruit industry veterans including
Dr. Robert Baumann
Dr. Rajni Aggarwal
and
Dr. Eden Zielinski
to join the institute. Today, NTxSI has three primary activities including the Center for Harsh Environments Semiconductor Systems (CHESS), the Custom Semiconductor Process Engineering and Characterization (C-SPEC) effort and the workforce development focus.
“We’re all at the stage of our careers where we want to make a positive impact on the community and the next generation of semiconductor professionals,” Moise said.
“The Electrical and Computer Engineering (ECE) Department advances semiconductor research through electronic design automation, semiconductor device innovation and circuit design. Our faculty develop next-generation tools, innovative devices and circuits that enable faster, smaller, more energy-efficient and trustworthy technologies.”
— Dr. Dinesh Bhatia, professor and head of the Department of Electrical and
Computer Engineering
Dr. Dinesh Bhatia
RAPID ADVANCEMENT
Not long after NTxSI planning began, Texas Governor Greg Abbott visited the UT Dallas Clean Research Laboratory in March 2023 to announce a new
Texas Semiconductor and Consortium
. In June 2023, Abbott signed the Texas CHIPS Act, signifying a statewide commitment to semiconductor research and workforce development.
As the University focuses on workforce development through assisting community colleges and community outreach, semiconductor research has also expanded. School leaders have focused on recruiting top-level researchers and expanding capabilities with existing research groups like the Texas Analog Center of Excellence (TxACE).
Dr. Nandika D’Souza
“We added Ted, Rob, Rajni and Eden from TI, and we are recruiting others including members of the National Academies,” said Gnade, who was recently appointed as senior advisor to Dr. Stephanie G. Adams, dean of the Erik Jonsson School of Engineering and Computer Science, for research to aid efforts to generate more industry-sponsored research.
In 2025, the Jonsson School added
Dr. Ron Rohrer
, research professor in materials science and engineering, associate director of CHESS and a member of the National Academy of Engineering, and Moise also was named a
fellow of the National Academy of Inventors
in 2025.
In 2024, Dr. Nandika D’Souza joined the Jonsson School as its
associate dean for strategic initiatives
and professor of mechanical engineering following 28 years as a faculty member at the University of North Texas.
“I joined the Jonsson School to work on semiconductors,” said D’Souza, whose research includes semiconductor packaging and sustainable materials. In addition to research, she also works on initiatives related to workforce development.
According to the University’s
Office of Research and Innovation
, the total active research portfolio at UT Dallas dedicated to semiconductor research totaled more than $40 million in June 2025. The influence of semiconductor research, however, reaches back to the founding of
UT Dallas.
STEM teachers from area school districts visit the UT Dallas cleanroom during a summer professional development week hosted by the North Texas Semiconductor Institute.
Semiconductors: A UT Dallas Legacy
Since Jack Kilby invented the first integrated circuit in the late 1950s, semiconductor research and development led to the University’s founding. Following significant investments in semiconductor research and technology over the past twenty years, the University has emerged as a leader in Texas and the U.S., where domestic semiconductor production has become a strategic national priority.
1959
Jack Kilby sparked a revolution with his invention of the integrated circuit, patented in 1959. A bronze statue of Kilby was given to the University in 2021 and is pictured at the
TI Plaza.
1969
Texas Instruments Inc. founders Eugene McDermott, J. Erik Jonsson and Cecil H. Green were instrumental in developing the Graduate Research Center of the Southwest, which became The University of Texas at Dallas in 1969.
1972
An aerial view shows an early UT Dallas campus view. The campus was built on the prairie near Richardson, Texas, close to TI's headquarters.
2002
Inventor Jack Kilby (center) attends the groundbreaking of ECS South in 2002 with Dr. William P. Osborne (left), dean of the Jonsson School from 1995 to 2002, and Charles Miller (right), a member of The University of Texas System Board of Regents, Kilby visited UT Dallas several times following the Jonsson School's founding in 1986.
2003
Senator Kay Bailey Hutchison speaks at a Project Emmitt press conference in Feb. 2003. Texas Instruments, the state of Texas and UT System formed a partnership leading to $300 million to expand the Jonsson School.
2016
Texas Governor Rick Perry (center) visits UT Dallas in 2013 to sign the Tier One bill into law, releasing hundreds of millions of dollars for education. UT Dallas was classified as a Carnegie R1 institution in 2016.
2023
President Richard C. Benson meets with U.S. Representative Collin Allred for a roundtable discussion on semiconductors in 2023. The University's semiconductor initiatives have drawn bipartisan support.
High-Resolution Microscopes Boost International Research Consortiums
Dr. Moon Kim, professor of materials science and engineering, brought several high-powered transmission electron microscopes in the early 2000s that enable atom-by-atom resolution and unmatched spatial resolution for atom-to-atom chemical mapping of materials to develop smaller and more efficient semiconductor chips and explore novel nanomaterials for new semiconductor devices. He led two semiconductor research consortiums in Texas: FUSION (Future Semiconductor Commercialization), which was funded by South Korea and a state of Texas technology fund, and the Silicon Wafer Engineering and Defect Science (SiWEDS) Industry/University Cooperative Research Center, funded by the National Science Foundation.
Kilby’s big breakthrough
When engineer Jack Kilby joined TI in the summer of 1958, he did not have enough accrued time off to take a summer vacation along with his colleagues, so he spent time working alone in the lab. He ultimately created the first prototype for a functional integrated circuit in September 1958. When his supervisors realized the significance of his invention, they applied for a patent which he was awarded in February 1959.
As the company grew rapidly over five years, by 1963, TI needed more qualified engineers. Rather than trying to recruit from the East Coast, the company founded the
Graduate Research Institute of the Southwest
to begin training STEM professionals. TI ultimately granted the private research institute to the state of Texas, and it became The University of Texas at Dallas in September 1969 following the 61st Texas Legislature session.
“Researchers in the Department of Mechanical Engineering are exploring advanced electronic packaging, mechanical reliability, innovative thermal management solutions including bubbleless vaporization for chip cooling and novel materials design for energy conversion and storage.”
— Dr. Edward White, professor and head of the Department of Mechanical Engineering and Jonsson School Chair
Kilby, whose invention sparked so many more innovations, was co-awarded a Nobel Prize in 2000 and continued to visit the University until his death in 2005. At TI Plaza located at the heart of campus, University leaders
dedicated a statue of Kilby
holding a prototype of the integrated circuit in 2021.
PROJECT EMMITT KICKS OFF NSERL
By 1986, the Erik Jonsson School of Engineering and Computer Science was established. The school initially focused heavily on telecommunications with the Telecom Corridor nearby in Richardson, so semiconductor science was less of a priority. However, as the University grew, school leaders wanted to be part of TI’s initiative to build a new facility in the early 2000s.
TI could have selected several alternative locations, but the University recognized the importance of semiconductor science and its roots in the University’s founding. Football player
Emmitt Smith was drafted by the Dallas Cowboys
in 1989 when the team had the 17th draft pick. He became the NFL’s all-time leading rusher and helped the Cowboys win three Super Bowls before being named MVP at Super Bowl XXVIII. The Jonsson School’s leaders saw a similar opportunity with the new TI facility.
TI, UT Dallas and the state of Texas ultimately created Project Emmitt to bring semiconductor science back to prominence and to bring UT Dallas to
Carnegie Tier One
status with a new research facility at the UT Dallas campus and a new fabrication facility constructed in the Richardson area.
The
Natural Science and Engineering Research Laboratory (NSERL)
was added to the UT Dallas campus, which includes the
Cleanroom Research Laboratory
onsite.
In addition to high-tech facilities for materials science and semiconductor research, the
Texas Analog Center of Excellence (TxACE),
a new research center designed to focus on analog technology, began in 2008.
While analog technology was a niche area at the time, it has increasingly moved to the center due to cyber-physical systems such as autonomous vehicles that depend upon both digital and analog technologies.
Finally, soon after Project Emmitt, the new
Department of Bioengineering
was launched with research focused heavily on biomedical sensor applications. Today, NSERL is an interdisciplinary facility where faculty from multiple schools and disciplines conduct research related to semiconductors.
TxACE RESEARCH POWERHOUSE
TxACE began through support from Texas Instruments Inc., the Emerging Technology Fund of the state of Texas and the Semiconductor Research Corp. (SRC), and it has since become an international leader in analog, mixed signal and radio frequency (RF) circuits research, which have become integral parts of integrated circuits.
The mission of the center is to create fundamental analog, mixed signal and RF design innovations in integrated circuits and systems that improve energy efficiency, health care and public safety and security. TxACE is now the largest analog circuit research design center housed at an academic institution that has supported more than $100 million in research.
“The Department of Materials Science and Engineering has a long history in semiconductors and has dedicated over 20 years most of its research agenda to semiconductors. Recently, the department speared the creation of the North Texas Semiconductor Institute, which has helped organize and catalyze new research opportunities in this area across UT Dallas.”
— Dr. Manuel Quevedo-Lopez, professor and head of the Department of Materials Science and Engineering and Texas Instruments Distinguished University Chair in Nanoelectronics
Dr. Kenneth K. O, director of TxACE, professor of electrical and computer engineering and
Texas Instruments University Chair,
began leading the research center in 2009. Dr. O is a pioneer in the field of high-frequency complementary metal-oxide-semiconductor (CMOS) integrated circuits including RFIC for communication and millimeter-wave circuits for sensing and communications.
Dr. O has focused on several innovations with broad impact related to analog technology, including an electronic nose device that has enabled breath analysis for numerous applications. The device imitates other sensing modalities and is both affordable and widely available.
Additionally, Dr. O and researchers from Seoul National University developed a
“Superman” imager chip
that enables the detection of objects inside of packages or behind walls and uses signals at 200 to 400 gigahertz instead of X-rays. The imager chip, whose development over 15 years captured worldwide acclaim, can now fit into a mobile device.
“The entire integrated circuits industry has evolved into a mixed-signal industry,” Dr. O said. “We started on the periphery, but we have ended up right in the center.”
Dr. O continued, “Analog circuitry is a critical component of nearly every product of the $600-billion-per-year integrated circuits industry, as a part of sensing, actuation, communications, power management and more. Digital integrated circuits such as microprocessors, logic circuits and memories are now integrating analog functions like input/output circuits, phase-locked loops, temperature sensors and power management circuits.”
"The entire integrated circuits industry has evolved into a mixed-signal industry ... We started on the periphery, but we have ended up right in the center."
— Dr. Kenneth K. O, director of TxACE, professor of electrical and computer engineering and Texas Instruments Distinguished University Chair
NSERL
The Department of Materials Science and Engineering at UT Dallas is housed in the $85 million Natural Science and Engineering Research Laboratory (NSERL). The facility, completed in 2006, was funded with support from Project Emmitt.
NSERL is home to research faculty specializing in engineering, physics, chemistry and microbiology, along with their graduate students. Equipment for advanced work supports characterization techniques including high-resolution transmission electron microscopy, focused ion beam, X-ray diffraction and X-ray photoelectron spectroscopy.
The Cleanroom Research Laboratory housed at NSERL is a particle-free environment with facilities for semiconductor device fabrication and characterization with equipment including plasma tech; plasma-enhanced chemical vapor deposition; low-pressure chemical vapor deposition; metallization including sputter, e-gun and thermal evaporation; wet chemical stations; thermal oxidation and diffusion; rapid thermal processing lithography; and surface analysis tools.
Both internal and external researchers use the NSERL facilities.
In 2025, TxACE connected nearly 28 institutions across the world with nearly 100 research tasks related to analog technology. The center typically supports more than 100 PhD students each year. Since 2008, more than 350 students of TxACE have completed their PhD degrees, and they drive innovation in the semiconductor industry. Technologies developed by the center include integrated power management techniques, low-cost analog-to-digital converter (ADC) testing, millimeter-wave CMOS radar circuits, system-level electrostatic discharge (ESD) protection, condition monitoring of power transistors and many more. As a result, TxACE has become a critical part of the innovation ecosystem for the semiconductor industry.
In its second decade, TxACE has focused on developing technologies that will enable prediction of time-to-failure. These technologies enable implementation of digital twins for semiconductor design, fabrication, testing and reliability that are critical to semiconductor manufacturing. With the establishment of SMART USA operated by the Semiconductor Research Corporation (SRC), a billion-dollar investment that seeks to use digital twins to improve semiconductor manufacturing, TxACE is well positioned to expand its longstanding collaboration with SRC, TI and the semiconductor industry and to continue to drive innovation in the semiconductor industry.
NTxSI LEADS THE WAY
With University leaders supporting NTxSI, the initiative expanded to three main areas: CHESS, C-SPEC and workforce development.
Quevedo-Lopez, a member of the Texas Semiconductor Innovation Consortium that advises the governor and legislators to maintain Texas’ leadership in semiconductors, established CHESS in 2023. This highly regarded interdisciplinary research center focuses on how harsh environments — including those with high radiation and high heat — impact semiconductor materials, devices and performance, a highly specialized field of inquiry.
“We are pioneering the use of hydrogen depassivation lithography (HDL) for the atomically precise fabrication of solid-state quantum devices, which are critical for developing next-generation quantum computing and other advanced semiconductor technologies. Our work focuses on overcoming manufacturing challenges to enable large-scale production of these highly precise devices.”
— Dr. Reza Moheimani, professor and head of the Department of Systems Engineering and James Von Ehr Distinguished Chair in Science and Technology
National defense applications include quantum computing; resilient grids, networks and communication systems; autonomous vehicles; space exploration; and hypersonic weapons.
The research efforts also support numerous industries that encompass energy production, power distribution, electric vehicles, data centers and health care.
Members of the group include experts in physics, chemistry, materials science, bioengineering and electrical engineering.
“Radiation stress and testing is quite involved for individual companies to perform, so we try to help with that,” Moise said. “Dr. Robert Baumann is a radiation expert from TI, and we have several research projects looking at the effects of
radiation on semiconductor devices
.”
Baumann, who was previously a chief technologist for high reliability products at TI, recently commented on
NASA’s Europa Clipper
mission that sent a spacecraft to Jupiter’s fourth moon in October 2024, arriving at Jupiter in April 2030 after a 1.8 billion km journey. Jupiter has a high radiation field, so transistors onboard the spacecraft can break down over time. As a result, the spacecraft will only spend about one day in the harsh environment with high radiation, and the transistors will recover through a self-healing annealing process.
NTxSI OFFERS SCHOLARSHIPS FOR MS STUDENTS
As of fall 2025, NTxSI has launched a new scholarship program to promote careers in the high-demand field of semiconductor engineering. The NTxSI MS Scholar Program will provide qualified students pursuing master’s degrees with tuition, a stipend, an industry-relevant curriculum, a summer research opportunity and access to industry mentors. The program will support 20 full-time students, 10 in each of the academic years beginning in 2026 and 2027.
Dr. Manuel Quevedo-Lopez (right) and researchers in the CHESS laboratory test semiconductor materials’ performance under harsh environmental conditions.
CHESS has focused on
evaluating microelectronic devices
used in applications ranging from hypersonic weapons traveling five times the speed of sound to electronics for space and energy production that can withstand high-heat or high-radiation environments.
Related
projects
include test optimization for capacitors, reliability testing for electronics in harsh conditions, heat-resistant nuclear batteries, radiation detectors, perovskite materials’ performance when exposed to extreme ultraviolet radiation and X-rays, and solid-state batteries that can withstand extreme temperatures. Overall, the center’s research activities will have a broad impact in support of national security while ensuring improved safety and reliability of critical systems.
“Taking advantage of the capabilities of UT Dallas, the C-SPEC team, led by Dr. Rajni Aggarwal, works with semiconductor companies and startups to evaluate new devices and materials,” Moise said. “Rajni is an expert in device integration and testing with decades of experience from her work at TI. To accelerate technology commercialization stemming from C-SPEC’s efforts, the University has several other resources available on campus including the
Institute for Innovation and Entrepreneurship
and the Venture Development Center to help start-up companies and founders market their inventions.”
Innovation Through Interdisciplinary Research Thrusts
Semiconductor science and technology research is a high priority as it is one of five
research thrusts
established by the Jonsson School in 2024. Semiconductor science and technology researchers across the Jonsson School aim to address the technical, social, cultural, environmental and economic challenges facing the North Texas region and society at large.
The third component, workforce development, is possibly NTxSI’s most unique endeavor. Both the federal and state CHIPS acts are designed to support a fully trained workforce to produce microchips in the United States, which requires training operators, technicians and engineers to work in these facilities with appropriate technical knowledge and skills.
Zielinski, assistant director of NTxSI, has worked with community colleges in the North Texas area to coordinate training programs over the past two years. While UT Dallas is not training operators and technicians directly, its cleanroom facility is currently used for outreach programs including teacher- and counselor-training programs. A cleanroom training facility is also planned primarily to introduce high school, community college and undergraduate students to semiconductor production.
Community colleges have different needs according to their demographics, Zielinski said. At
Grayson College
, located near the TI semiconductor facility in Sherman, Texas, many students were interested in community college and in staying locally, but they did not have an appropriate curriculum to train operators and technicians when the consortium started in 2023.
NTxSI has worked with Grayson College to create a new program in advanced manufacturing, which provides the skills needed to work in the semiconductor production facility and also provides the students with some career flexibility if they decide to work in a different industry. Students are excited to stay locally while training for high-paying careers.
Other community colleges like
Collin College
where advanced manufacturing programs were well established needed funding for marketing to attract students. Additionally, the programs are designed to transfer credits to full degree programs at UT Dallas. The consortium partners with five community colleges in North Texas with a total enrollment exceeding 120,000 students. The University of Texas at Arlington, under the direction of Dr. Cory Forbes, serves as the evaluator/assessor for the consortium and provides critical feedback and leadership.
BECOME A STATE AND NATIONAL LEADER
At NTxSI, the diversification of three main areas later provided a blueprint for
Batteries and Energy to Advance Commercialization and National Security
(BEACONS), a UT Dallas battery research center funded by a $30 million Department of Defense grant awarded in 2023, as well as programs outside of North Texas.
“Within NTxSI, we focus on collaboration with industry, universities, community colleges and other stakeholders to make a positive impact on the region and beyond,” Moise said. “We’re very fortunate to partner with research and development experts and workforce development leaders to learn best practices and to share lessons learned throughout our network.”
NTxSI’s workforce development consortium serves as a model for other institutions who have received CHIPS funding or who are striving to create regional semiconductor workforce ecosystems.
“We have been invited by the CHIPS program office to share our workforce consortium approach with several institutions across the nation,” Moise said. “We recognize that effective workforce development should be customized to local needs while sharing best practices, and we’re happy that our experiences in North Texas may provide some examples for other regions to emulate.”
Kilby’s invention in the late 1950s sparked a technological revolution that led to the creation of UT Dallas, enabled NASA and led to the sale of more than $1 trillion of semiconductor chips annually. In the early 2000s, it inspired Project Emmitt, and after a gathering among friends, it galvanized UT Dallas to become a destination for semiconductor research. With support from federal and state government and industry, the Jonsson School and UTD are well positioned to continue as a regional, national and global leader in semiconductor science and technology.
The Jack Kilby Collection
The Jonsson School was recently
given a collection
from Jack Kilby, Nobel Prize winner and inventor of the integrated circuit, by the family and friends of Kilby’s friend Steven McQuay. The collection includes signed wafers, photos, TI calculators and more artifacts from Kilby’s life as an engineer and inventor. The collection will be displayed in the Department of Electrical and Computer Engineering.
“We are deeply honored to house this extraordinary collection honoring Jack Kilby’s legacy,” said Dinesh Bhatia MS’97, PhD’90, professor and department head of Electrical and Computer Engineering. “The Jack Kilby Collection embodies the intersection of creativity, innovation and impact that defines electrical and computer engineering at UT Dallas. It will be inspirational for students, faculty and visitors alike.”
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