Undergraduate students in Kansas interested in atomic, molecular and optical science can gain a unique research experience this summer.
Kansas State University department of physics is hosting an NSF-funded Research Experiences for Undergraduate (REU) program entitled Interactions of Matter, Light and Learning for ten weeks this summer.
Kansas NSF EPSCoR will sponsor up to three undergraduate students attending school in Kansas or Nebraska who are willing to join a group of about a dozen undergraduate students selected nationwide. These students will be funded by the NSF-EPSCoR Track 2 grant, Imaging and Controlling Ultrafast Dynamics of Atoms, Molecules, and Nanostructures.
Student participants supported by Kansas NSF EPSCoR will be involved with a variety of atomic, molecular and optical (AMO) research projects at the leading edge of world-class research. For example, students will study the attosecond physics of electrons in matter; quantum and coherent control of atoms and molecules; atomic and molecular dynamics; and imaging techniques, using ultrafast lasers. They will have access to our state-of-the-art facilities, including three ultrafast high intensity laser systems. All students will be full participants in active research groups and will be mentored by faculty who are recognized both for their research and for their teaching abilities, including faculty in our highly rated atomic physics program.
Students selected to participate will receive a stipend of $4,500-$5,000, partial travel expenses, and room and board, a total value of over $8,000. They will live on campus with students in the physics and other REU programs and will have access to all the usual facilities at Kansas State: libraries, recreation centers, etc.
Online applications are available at www.phys.ksu.edu/reu. The same application is used for this program and K-State's nation-wide REU program. An unofficial transcript and letter of reference are also required. Applications will be reviewed beginning March 18 and will continue until all places are filled.
Additional information can be obtained by calling (785) 532-1612 or e-mail reu@phys.ksu.edu.
Welcome...
Welcome to the archive of Kansas NSF EPSCoR (KNE) news and announcements blog. Stay up-to-date with all the happenings, discoveries, events and funding opportunities associated with KNE by visiting https://nsfepscor.ku.edu./
Thursday, February 19, 2015
Thursday, February 12, 2015
Webinar: SEES: Interactions of Food Systems with Water and Energy Systems
The National Science Foundation announced they will host a webinar to provide further information to researchers from EPSCoR jurisdictions about the Dear Colleague Letter: SEES:
Interactions of Food Systems with Water and Energy Systems. It will
feature a live Q&A session.
The webinar will take place on Wednesday, February 25, 2015, 1:00pm-3:00pm EST. Preregistration is required and must be completed by Feb 24th
(see below).
Webinar topics include:
- Guidelines and eligibility,
- Proposal preparation guidance,
- Recommendations for showcasing the coupled nature of the food, energy and water system.
- Deadline for submissions to the Dear Colleague Letter announcement (March 30, 2015).
Registration
Webinar Registration will open February 11, and close February 24. To register for this event, go to: https://nsfevents.webex.com/nsfevents/onstage/g.php?MTID=e51b79e8035b167145527cd75f9423417 . Once registration is complete, you will receive additional information on how to join this event.
Webinar Registration will open February 11, and close February 24. To register for this event, go to: https://nsfevents.webex.com/nsfevents/onstage/g.php?MTID=e51b79e8035b167145527cd75f9423417 . Once registration is complete, you will receive additional information on how to join this event.
Related Websites
Dear Colleague Letter: SEES: Interactions of Food Systems with Water and Energy Systems
Dear Colleague Letter: SEES: Interactions of Food Systems with Water and Energy Systems
Additional Information
Researchers from EPSCoR jurisdictions can contact Dr. Audrey
Levine (703-292-7374; alevine@nsf.gov )
for additional information.
Tuesday, December 23, 2014
Kansas NSF EPSCoR Presents Six Faculty with First Award Grants related to Climate and Energy Research or Atomic/Molecular/Optical Sciences
Kansas NSF EPSCoR helps Kansas build its research capacity and competitiveness in science and technology. The Fall 2014 First Award program helps early career faculty become competitive for funding from the research directorates at the National Science Foundation by: 1) encouraging early career faculty to submit proposals to the NSF (or other federal funding agency) as soon as possible after their first faculty appointment, and 2) by accelerating the pace of their research and the quality of their subsequent proposals. This fall, Kansas NSF EPSCoR honored six faculty with First Award grants in the areas of Climate and Energy Research or Atomic/Molecular/Optical Science. The researchers and their projects that will receive Kansas NSF EPSCoR funding are:
Biomass: A Sustainable Approach to Unsustainable Times in Interior Alaska
Assistant Professor of Environmental Studies
The University of Kansas
This research will examine the role of local and Indigenous environmental knowledge in the design, management, and outcome of a unique off-the-grid biomass energy project in Fort Yukon, Alaska. Winter is harsh, 40-70 below zero Celsius, and heat is provided by costly and unsustainable fossil fuels. The goal of the Fort Yukon project is to offset diesel cost of $4,080,000 over five years or 145,000 gallons per year by cutting and chipping cottonwood trees and using the feedstock in a separate, non-gas dependent, boiler system. While the science and approach to identifying species and harvest areas are sound (EA, 2013), information on the areas harvested has yet to be document and calculated. The foundation of this research agenda is valuing local/Indigenous knowledge, researchers will gather and document that knowledge used in the decision-making processes. Using interdisciplinary approaches, the PI and two graduate students will investigate the decision to deck wood on site, extract data from the operations/logistics side of the harvest, measure the ecological impact of cutting and decking on-site, and measure water content of wood decked. Initial conversations have revealed rich local and ecological knowledge unique to this Indigenous community; this research will extend that important data collection.
Multilayer Strategies for the Investigation of Electron Recombination Reactions in Organic Photovoltaics
Dr. Caricato proposes to develop multiscale computational strategies that incorporate mutual polarization between layers based on extrapolation techniques. The goal is to treat complex molecular systems in a realistic environment through the best compromise between accuracy and computational effort. High levels of theory will be employed on the core system while the effect of the surrounding is introduced in a fully self-consistent manner. These methodologies will be used to study electron recombination reactions, which are one of the main causes of efficiency loss in dye-sensitized solar cells (DSSCs). The scope is to gain a mechanistic understanding of these reactions, and possibly suggest ways to minimize them.
Bandgap Tunable 2-D Nanomaterials for Advanced Energy Conversion and Storage
This project has been conceived to increase our knowledge of the field of 2-dimensional (2-D) nanomaterials for their applications in energy conversion and storage. 2-D nanomaterials such as graphene and molybdenum disulfide (MoS2) are very attractive for energy applications due to their tunable optical and electronic properties. In addition, they show very unique tunable interlayer thickness dependence properties which could be interesting for charge storage applications in a wide range of electrolytes. The development of promising new synthetic methodologies and the establishment of a fundamental approach to modify their properties will provide 2-D nanomaterials with potentially useful properties and applications. The objective of this research is thus to: (1) synthesize graphene quantum dots (GQDs) and nanosheets of MoS2; (2) study the effect of size, chemical doping and surface functionalization on the optical and electronic properties of GQDs; and (3) study the effect of these modifications on their ability to convert solar light into energy and energy storage efficiency. Funding for this project will enable us to enhance our fundamental understanding of 2-D nanomaterials and their applications in clean energy production and storage.
Future Efficient Electricity Distribution Network with Distributed Resources Growth
Chengzong Pang
Assistant Professor of Electrical Engineering and Computer Science
Wichita State University
Electricity plays an important and leading role in the flourishing of the world’s economy as sustainable and cost-efficient energy carrier for everyday needs. Due to rapid growth of electric vehicles in fast developing metropolitan areas, the reliability and stability of distributed system is impacted by optimal sitting and sizing of parking lots including different levels of charge and discharge stations with embedding renewable generation for utilities. This proposal hence deals with the fundamental demands of future distribution system development: efficiency, reliability, and sustainability. The research will focus on integration of several seemingly unrelated concepts: renewable generation and energy storage at dispersed locations or buildings, optimal sitting and sizing of parking lots with bi-directional charging/discharging stations, load leveling and efficiency optimization of energy consumption based on improved Demand Side Management (DSM) techniques, and improved asset and outage management based on Automatic Meter Reading (AMR). The final outcome of this research will be a demonstrated concept of an integrated solution for reaching the efficiency, reliability and sustainability goals.
Assistant Professor of Electrical Engineering and Computer Science
Wichita State University
Electricity plays an important and leading role in the flourishing of the world’s economy as sustainable and cost-efficient energy carrier for everyday needs. Due to rapid growth of electric vehicles in fast developing metropolitan areas, the reliability and stability of distributed system is impacted by optimal sitting and sizing of parking lots including different levels of charge and discharge stations with embedding renewable generation for utilities. This proposal hence deals with the fundamental demands of future distribution system development: efficiency, reliability, and sustainability. The research will focus on integration of several seemingly unrelated concepts: renewable generation and energy storage at dispersed locations or buildings, optimal sitting and sizing of parking lots with bi-directional charging/discharging stations, load leveling and efficiency optimization of energy consumption based on improved Demand Side Management (DSM) techniques, and improved asset and outage management based on Automatic Meter Reading (AMR). The final outcome of this research will be a demonstrated concept of an integrated solution for reaching the efficiency, reliability and sustainability goals.
Structural Characterization of Atomic Nanosystems Using Ion Mobility Spectrometry with Mass Spectrometry
Alexandre Shvartsburg
Assistant Professor of Chemistry
Wichita State University
Assistant Professor of Chemistry
Wichita State University
A major research area formed over the last decade is nanotechnology, as seen in the US Nanotechnology Initiative and parallel foreign programs. Most new nanomaterials that emerged from those efforts are carbon assemblies such as fullerenes and associated graphenes, which were first discovered in the gas phase using mass spectrometry (MS). Here we propose to apply the novel approach of differential or field asymmetric waveform ion mobility spectrometry (FAIMS), coupled with MS, to separate and probe the isomers of nanoclusters, specifically carbon species including fullerenes. Such moieties have been studied by linear IMS, but FAIMS that is much more orthogonal to MS has shown superior power to distinguish species with fine structural variances. Hence application of FAIMS should lead to a fuller understanding of the morphological diversity of atomic nanosystems and detection of previously unresolved geometries. Subsequently, the structures separated by FAIMS would be further characterized by a following linear IMS stage and/or spectroscopic methods.
Three Dimensional Integrated Circuit (3D IC) Design and Analysis for Green Computing and Renewable Energy System
Yang Yi
Assistant Professor of Electrical Engineering and Computer Science
University of Kansas
Renewable energy sources are mostly affected by climate change and other environmental factors like irradiance, temperature, wind speed, fog that makes the energy source unstable, how to minimize the effect of climate changes, maximize the use of the renewable energy, and optimize the workload performance become more and more important. Three dimensional (3D) integrated circuits could enable new paradigm for green computing and renewable energy applications, by integrating different technological compartments such as CMOS (complementary-metal-oxidesemiconductor-transistor), nano-devices, logics, memory, and analogue sensors. This project provides promising modeling and design solutions for the through silicon via (TSV), which is one of the most critical components in 3D integrated circuits for green computing and renewable energy applications. In the first research thrust, we will focus on introducing an accurate and efficient TSV model for 3D integrated circuit design and analysis. In the second thrust, we will design TSV structures that could resolve the signal integrity issues at high speed data transmission in renewable energy system. This project will lay a solid foundation for a practical design methodology providing higher reliability, lower power consumption, reduced delay, and system miniaturization for green computing and renewable energy system.
University of Kansas
Renewable energy sources are mostly affected by climate change and other environmental factors like irradiance, temperature, wind speed, fog that makes the energy source unstable, how to minimize the effect of climate changes, maximize the use of the renewable energy, and optimize the workload performance become more and more important. Three dimensional (3D) integrated circuits could enable new paradigm for green computing and renewable energy applications, by integrating different technological compartments such as CMOS (complementary-metal-oxidesemiconductor-transistor), nano-devices, logics, memory, and analogue sensors. This project provides promising modeling and design solutions for the through silicon via (TSV), which is one of the most critical components in 3D integrated circuits for green computing and renewable energy applications. In the first research thrust, we will focus on introducing an accurate and efficient TSV model for 3D integrated circuit design and analysis. In the second thrust, we will design TSV structures that could resolve the signal integrity issues at high speed data transmission in renewable energy system. This project will lay a solid foundation for a practical design methodology providing higher reliability, lower power consumption, reduced delay, and system miniaturization for green computing and renewable energy system.
Tuesday, December 9, 2014
Faculty Receive 2015 Education and Diversity Grants Building on Kansas NSF EPSCoR Climate and Energy Research or Atomic/Molecular/Optical Science
The 2015 Kansas NSF EPSCoR Education and Diversity Grants are designed to enhance science, technology, engineering and mathematics (STEM) education in Kansas by supporting activities that will lead to an expanded STEM workforce or prepare a new generation for STEM careers in the areas of climate or energy research or atomic/molecular/optical science. This Fall, Kansas NSF EPSCoR awarded five Education and Diversity grants in the areas of Climate and Energy research or Atomic/Molecular/Optical Science. The projects that will receive Kansas NSF EPSCoR funding are:
Anschutz Professor of Education and
Professor of Physics
Fort Hays State University
The Next Generation Science Standards (NGSS) have a significant focus on climate change education that will engage students in observations of the climate and analysis of climate change data for K-12 students to demonstrate their knowledge and understanding. While the vision advocated by the NGSS is a significant step to improving science education in the country, the knowledge and skills necessary to implement this vision lags behind. K-12 teachers often do not have sufficient background with climate-based observations and the skills to deal with climate datasets. The proposed teacher workshop is designed to address this issue through a four day workshop that will introduce teachers to climate observation protocols developed through GLOBE (Global Learning and Observation to Benefit the Environment) and databases and database analysis tools in MY NASA DATA (Mentoring and inquiry using NASA Data on Atmospheric and earth science for Teachers and Amateurs). Introduction to these tools with academic year follow-up will increase teachers’ pedagogical content knowledge for teaching earth science, specifically climate change, in alignment with the NGSS and the Kansas NSF EPSCOR focus on climate (Track 1).
Deepak Gupta
Assoc. Professor and
Director of Engineering Technology
Wichita State University
The objective of this proposal is to expand and prepare a new generation of STEM workforce. This objective will be achieved through the development of sustainable energy systems based curriculum modules that can be seamlessly adopted by K-12 and community colleges as well as professional development of K-12 teachers and community college faculty members. To achieve this objective, Wichita State University (WSU) will partner with Wichita Area Technical College (WATC), Butler Community College, and regional high schools. The project deliverables include: (a) Modular sustainable energy systems curriculum (with the focus on solar energy) using the problem based learning (PBL) model; (b) Train the trainer program (professional development of K-12 teachers and 2-year college faculty); and (c) Mentorship program with college students as mentors for K-12 students. These deliverables focus on the following activities: (a) expand student career options with modular curriculum design that can be adopted at different grade levels, (b) partnership with K-12 and community college, (c) development of curriculum and educational materials including a focus on underrepresented population, (c) professional development program for educators, and (d) introducing K-12 students to STEM fields through mentoring and schools visits. This project will stimulate the interest of high schools students and facilitate the transition from high schools to STEM based 2-year and 4-year climate and energy research related programs. It will also use existing resources available from US Department of Energy, Brightergy and other resources.
Kevin Leonard
Assistant Professor in Chemical and
Petroleum Engineering
The University Of Kansas
One of the grand challenges of our time is to directly convert solar energy to chemical energy (also known as solar fuels). If successful, this would have an enormous impact on how fuels and chemicals are made by lessening human dependence on fossil fuels and inhibiting greenhouse gas emissions. Dr. Kevin Leonard uses custom-built devices, robotics and 3D printers to overcome this challenge. His research demonstrates how creativity and innovation are used to address real-world energy challenges. It offers an ideal launch pad for challenging and inspiring children. This project will foster a new partnership between KU and Project CREATE, a non-profit group focused on Cultivating Responsible, Enriched, Artistic, Tech-Savvy Enthusiasts. We will pilot innovative ways to use 3D printing with children in grades 4-7 for an energy-themed summer camp. The hands-on activities will emphasize science, technology, engineering and math (STEM) concepts as well as creativity, problem-solving and teamwork. A special effort will be made to encourage female and minority youth to retain interest in STEM beyond middle school.
C. Matt Seimears
Chair and Associate Professor in
Education/Early Childhood/Special Education
Emporia State University
The overarching goal of the Advancement Via Individual Determination (AVID) – Climate Initiative (ACI) is a systemic reform involving Emporia State University, USD 259 Wichita, Kansas and USD 490 EL Dorado, Kansas
K–12 public school partners (USD 259 is an urban district, USD 490 is a rural school district both with underrepresented populations of minority and first generation education students) and Butler Community College (BCC). ACI aims to develop an advantage for the high school AVID and rural students to expand their access to STEM climate career opportunities as students of underrepresented groups within the central part of the state of Kansas. ACI’s goal is to introduce and prepare all students that are part of this initiative for STEM climate career pathways, and provide climate experiences and expanding it district/school wide. Two ESU faculty, one BCC science faculty member and five high school AVID programs from USD 259 and rural students from USD 490 will be part of the initiative. ACI will also train each participant in the use of newly developed materials to create an extended assessment process of STEM climate career pathways. Four spring 2015 mini-camps and a summer 2015 camp will take place with the AVID Climate Initiative student groups to study the impact aerosols have on the climate and environment. Students will study aerosols in the air during their mini-camp and summer camp experiences at the BCC Andover, Kansas campus location. The second location will be held in various locations in the city of Wichita, Kansas. The overall goal of this project will be to develop and test a targeted partnership that will support the continued growth of AVID and rural students into STEM climate career pathways, as well as implement a model that can exist beyond the last funding date.
Betsy Yanik
Professor in Mathematics and
Economics
Emporia State University
This proposal is a collaboration between Emporia State University (ESU) and Flint Hills Technical College (FHTC). The main components of the program will be a STEM Opportunities Day on each campus and a five day summer workshop offered jointly by FHTC and ESU. These programs will particularly focus on reaching out to the Hispanic population in the Flint Hills region of Kansas. The STEM Day on each campus will focus on the STEM programs offered by each institution. This daylong celebration of STEM opportunities will consist of four science hands on workshops which connect to the topic of energy. The summer workshop will allow for a more in-depth experience for students to work with STEM faculty and undergraduate students. The educational message to these young students is to value looking at situations using quantitative skills and scientific inquiry. This program will not only make Hispanic participants aware of the diversity of STEM careers, but also will better inform faculty and undergraduate students about the STEM opportunities at their “sister” institution. The pre-college participants will receive both STEM career information as well as some enrichment mathematical and scientific instruction. The summer program will extend the depth and variety of STEM activities in which Hispanics students will be engaged. The program is local in its scope but if successful may serve as a national model for better informing both faculty and students of the wide array of STEM careers facilitated by these schools; as well as develop a deeper understanding and appreciation for the educational opportunities at technical schools and universities.
Improving Climate Education through Field Observations and Data Analysis
Paul AdamsAnschutz Professor of Education and
Professor of Physics
Fort Hays State University
The Next Generation Science Standards (NGSS) have a significant focus on climate change education that will engage students in observations of the climate and analysis of climate change data for K-12 students to demonstrate their knowledge and understanding. While the vision advocated by the NGSS is a significant step to improving science education in the country, the knowledge and skills necessary to implement this vision lags behind. K-12 teachers often do not have sufficient background with climate-based observations and the skills to deal with climate datasets. The proposed teacher workshop is designed to address this issue through a four day workshop that will introduce teachers to climate observation protocols developed through GLOBE (Global Learning and Observation to Benefit the Environment) and databases and database analysis tools in MY NASA DATA (Mentoring and inquiry using NASA Data on Atmospheric and earth science for Teachers and Amateurs). Introduction to these tools with academic year follow-up will increase teachers’ pedagogical content knowledge for teaching earth science, specifically climate change, in alignment with the NGSS and the Kansas NSF EPSCOR focus on climate (Track 1).
STEM Education Through Sustainable
Energy Curriculum
Deepak Gupta
Assoc. Professor and
Director of Engineering Technology
Wichita State University
The objective of this proposal is to expand and prepare a new generation of STEM workforce. This objective will be achieved through the development of sustainable energy systems based curriculum modules that can be seamlessly adopted by K-12 and community colleges as well as professional development of K-12 teachers and community college faculty members. To achieve this objective, Wichita State University (WSU) will partner with Wichita Area Technical College (WATC), Butler Community College, and regional high schools. The project deliverables include: (a) Modular sustainable energy systems curriculum (with the focus on solar energy) using the problem based learning (PBL) model; (b) Train the trainer program (professional development of K-12 teachers and 2-year college faculty); and (c) Mentorship program with college students as mentors for K-12 students. These deliverables focus on the following activities: (a) expand student career options with modular curriculum design that can be adopted at different grade levels, (b) partnership with K-12 and community college, (c) development of curriculum and educational materials including a focus on underrepresented population, (c) professional development program for educators, and (d) introducing K-12 students to STEM fields through mentoring and schools visits. This project will stimulate the interest of high schools students and facilitate the transition from high schools to STEM based 2-year and 4-year climate and energy research related programs. It will also use existing resources available from US Department of Energy, Brightergy and other resources.
“Fun in the Sun: Using Solar Fuel Research to Educate, Challenge and Inspire Children”
Kevin Leonard
Assistant Professor in Chemical and
Petroleum Engineering
The University Of Kansas
One of the grand challenges of our time is to directly convert solar energy to chemical energy (also known as solar fuels). If successful, this would have an enormous impact on how fuels and chemicals are made by lessening human dependence on fossil fuels and inhibiting greenhouse gas emissions. Dr. Kevin Leonard uses custom-built devices, robotics and 3D printers to overcome this challenge. His research demonstrates how creativity and innovation are used to address real-world energy challenges. It offers an ideal launch pad for challenging and inspiring children. This project will foster a new partnership between KU and Project CREATE, a non-profit group focused on Cultivating Responsible, Enriched, Artistic, Tech-Savvy Enthusiasts. We will pilot innovative ways to use 3D printing with children in grades 4-7 for an energy-themed summer camp. The hands-on activities will emphasize science, technology, engineering and math (STEM) concepts as well as creativity, problem-solving and teamwork. A special effort will be made to encourage female and minority youth to retain interest in STEM beyond middle school.
Advancement Via Individual Determination
(AVID) – Climate Initiative (ACI)
C. Matt Seimears
Chair and Associate Professor in
Education/Early Childhood/Special Education
Emporia State University
The overarching goal of the Advancement Via Individual Determination (AVID) – Climate Initiative (ACI) is a systemic reform involving Emporia State University, USD 259 Wichita, Kansas and USD 490 EL Dorado, Kansas
K–12 public school partners (USD 259 is an urban district, USD 490 is a rural school district both with underrepresented populations of minority and first generation education students) and Butler Community College (BCC). ACI aims to develop an advantage for the high school AVID and rural students to expand their access to STEM climate career opportunities as students of underrepresented groups within the central part of the state of Kansas. ACI’s goal is to introduce and prepare all students that are part of this initiative for STEM climate career pathways, and provide climate experiences and expanding it district/school wide. Two ESU faculty, one BCC science faculty member and five high school AVID programs from USD 259 and rural students from USD 490 will be part of the initiative. ACI will also train each participant in the use of newly developed materials to create an extended assessment process of STEM climate career pathways. Four spring 2015 mini-camps and a summer 2015 camp will take place with the AVID Climate Initiative student groups to study the impact aerosols have on the climate and environment. Students will study aerosols in the air during their mini-camp and summer camp experiences at the BCC Andover, Kansas campus location. The second location will be held in various locations in the city of Wichita, Kansas. The overall goal of this project will be to develop and test a targeted partnership that will support the continued growth of AVID and rural students into STEM climate career pathways, as well as implement a model that can exist beyond the last funding date.
Energizing Underrepresented Student Populations to Enhance the STEM Workforce in Kansas
Betsy Yanik
Professor in Mathematics and
Economics
Emporia State University
This proposal is a collaboration between Emporia State University (ESU) and Flint Hills Technical College (FHTC). The main components of the program will be a STEM Opportunities Day on each campus and a five day summer workshop offered jointly by FHTC and ESU. These programs will particularly focus on reaching out to the Hispanic population in the Flint Hills region of Kansas. The STEM Day on each campus will focus on the STEM programs offered by each institution. This daylong celebration of STEM opportunities will consist of four science hands on workshops which connect to the topic of energy. The summer workshop will allow for a more in-depth experience for students to work with STEM faculty and undergraduate students. The educational message to these young students is to value looking at situations using quantitative skills and scientific inquiry. This program will not only make Hispanic participants aware of the diversity of STEM careers, but also will better inform faculty and undergraduate students about the STEM opportunities at their “sister” institution. The pre-college participants will receive both STEM career information as well as some enrichment mathematical and scientific instruction. The summer program will extend the depth and variety of STEM activities in which Hispanics students will be engaged. The program is local in its scope but if successful may serve as a national model for better informing both faculty and students of the wide array of STEM careers facilitated by these schools; as well as develop a deeper understanding and appreciation for the educational opportunities at technical schools and universities.
Monday, December 8, 2014
Research yields material made of single-atom layers that snap together like Legos
EPSCoR research
discovery yields new synergistic materials
Exciting scientific
breakthroughs are milestones that Kansas NSF EPSCoR strives for in its mission
to tackle global challenges like climate change and solar-based renewable
energy. EPSCoR supported physicists at the University of Kansas have achieved
such a milestone by creating a new substance from two different atomic sheets
that interlock much like Lego toy bricks. According to the researchers, the
objective of this investigation was to design new synergistic materials by
combining two single-atom thick sheets. Prior to this discovery, building
artificial materials with synergistic functionality was challenging because
most materials had different atomic arrangements at the interface and could not
connect.
Top Row: Tungsten Disulfide Bottom Row: Graphene |
Chiu worked with Hui Zhao,
associate professor of physics and astronomy at KU using ultrafast laser
spectroscopy in KU’s Ultrafast Laser Lab to analyze the movement of electrons
between the two materials. Their research along with the use of the facility
also contributes directly to another NSF EPSCoR funded project called Imaging
and Controlling Ultrafast Dynamics of Atoms, Molecules, and Nanostructures.
It is a collaboration between Nebraska and Kansas studying how light interacts
with matter that involves 30 researchers including Zhao.
The research groups led by
Chiu and Zhao are further testing this Lego approach to fabricate more
synergistic materials. By combining atomic sheets that absorb light of
different colors, they can potentially produce a large number of new
synergistic substances that react to the solar spectrum and convert energy
between electricity and radiation.
For more information please visit the full story at: http://goo.gl/spfVXF
The KU story was also featured as research news on the NSF web page: http://goo.gl/jd75Wb
To access the published article go to: http://goo.gl/d1vGkL
The KU story was also featured as research news on the NSF web page: http://goo.gl/jd75Wb
To access the published article go to: http://goo.gl/d1vGkL
This material is based upon work supported by the National Science
Foundation of USA (DMR-0954486, IIA-1430493), Kansas NSF EPSCoR First Award (EPS-0903806) and start-up funding by the University of Kansas. The National Basic Research
Program 973 of China (2011CB932700, 2011CB932703), Chinese Natural Science Fund
Project (61335006, 61378073), Beijing Natural Science Fund Project (4132031).
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