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Tariffs are coming - and our experts can help with your coverage

The steel and aluminum industries are fundamental to the strength and stability of the U.S. economy, playing a critical role in infrastructure, manufacturing, and national security. These industries support millions of jobs, drive technological advancements, and serve as key components in everything from automobiles and construction to defense systems and clean energy. As global trade policies, sustainability efforts, and economic shifts impact these sectors, their significance continues to grow, making them a critical topic for public discourse. Journalists covering this issue can explore: The economic impact of steel and aluminum manufacturing on American jobs and industries Trade policies, tariffs, and their effects on domestic production and global competition The role of steel and aluminum in national security and defense manufacturing Innovations in sustainable metal production and efforts to reduce carbon emissions Supply chain challenges and how they affect construction, automotive, and technology sectors The future of American steel and aluminum in a rapidly evolving global economy This topic offers rich opportunities for coverage, highlighting the industries' influence on economic stability, innovation, and national security. Connect with an expert about the aluminum and steel industries: To search our full list of experts visit www.expertfile.com

Fervo Energy, Southern Utah University, and Elemental Impact Launch Geothermal Drilling & Completions Apprenticeship Program

Fervo Energy (“Fervo”), the leader in next-generation geothermal development, along with Southern Utah University (SUU), an institution known for its personalized approach to learning, and Elemental Impact (“Elemental”), a non-profit investing platform that invests in climate companies and projects with deep local impact, today announced the launch of a geothermal apprenticeship program to help oil and gas workers and Southwest Utah residents join the rapidly growing enhanced geothermal industry. The first-of-a-kind geothermal apprenticeship program advances labor momentum spurred by the Inflation Reduction Act. The program, administered by SUU and funded in part by Elemental, will provide those seeking new skill sets with the opportunity to learn geothermal directional drilling and well completions, while combining on-the-job training with college-level coursework on geology and energy systems. This unique approach offers pathways for traditional college students as well as adult and working learners interested in careers in the geothermal energy industry. “Thousands of Americans work in upstream oil and gas, and with the right tools, they can easily apply their skill sets to geothermal production,” said Tim Latimer, Fervo CEO and Co-Founder. “We can harness the full potential of this existing talent pool and attract new talent beyond current fossil fuel workers by providing on-the-ground and in-classroom training opportunities. We believe that our apprenticeship program with SUU can ignite that process, supporting local job growth across Southwest Utah.” Already, 22 individuals working with ten different oilfield service providers operating in the area have registered for the geothermal apprenticeship program. By the end of 2024, the program aims to enroll at least 40 apprentices, providing them with an opportunity to fill an immediate workforce need upon completion of the apprenticeship. “Southwest Utah has the resource potential to become a national clean energy hub, and we have the human potential to make that vision a reality,” said Dr. Bill Heyborne, Dean of the College of Natural Sciences and Professor of Biology. “Our new apprenticeship program will prepare Utahns to drive much-needed energy innovation in the communities they call home.” Funding from Elemental Impact, a nonprofit investor in climate technology and community focused initiatives, enabled Fervo to offer this workforce training program. "Demand for electricity is surging and expected to double in the US by 2030; geothermal sources, like those being deployed by Fervo, have the potential to meet that demand while boosting local jobs,” said Dawn Lippert, Founder and CEO of Elemental Impact. “We are thrilled to support this geothermal apprenticeship program and help power the transfer of valuable skills from oil and gas professionals to the geothermal industry. This initiative, in partnership with SUU, is an essential bridge to building a local workforce and advancing the clean energy transition." Dr. Heyborne is available to speak with the media. For more information click on his icon to arrange an interview.

Top Expert Placement: NYS Legislature Fails to Pass Environmental Bills

Lawrence Levy, associate vice president and executive dean of the National Center for Suburban Studies, talked to Newsday about New York state legislators failing to pass environmental measures that would have been transformative. “It’s fair to say that in a state that has passed some of the nation’s most ambitious clean energy and other environmental protections, the failure to support additional initiatives can’t be ascribed to a lack of concern about climate change, congestion and pollution,” Levy said. “It’s primarily about the economy, primarily inflation, and general uncertainty. These are volatile times, economically and even politically.” Lawrence Levy is available to speak with media - simply click on his icon now to arrange an interview today.

Aston University to train the UK’s next generation of decarbonisation experts

Consortium led by the University is to receive almost £11 million to open doctoral training centre Will focus on use of biomass to replace fossil fuels and removal of CO2 “…part of the UK’s biggest-ever investment in engineering and physical sciences doctoral skills”. Aston University is to train the next generation of scientists tasked to remove greenhouse gases from the environment. A consortium led by the University is to receive almost £11 million to open a doctoral training centre which will focus on leading the UK towards net zero. The centre, based at Aston University, will bring together world-leading research expertise and facilities from the University of Nottingham, Queens University Belfast and the University of Warwick and more than 25 industrial partners. The funding has been announced by the UK science, innovation and technology secretary Michelle Donelan. The centre is to receive almost £8 million of government money while the remainder will be made up through match funding and support from industry and the four universities. The government has described it as part of the UK’s biggest-ever investment in engineering and physical sciences doctoral skills, totalling more than £1 billion. The Aston University centre will focus on the use of biomass to replace fossil fuels and removal (or capture) of CO2 from the atmosphere, with the potential to create new sources of fuels and chemicals. Integration of these two areas will lead to significant cost and energy savings. Called NET2Zero, the centre will train PhD students across the full range of engineered greenhouse gas removal techniques including direct air capture, CO2 utilisation (including chemical and material synthesis), biomass to energy with carbon capture and storage, and biochar. The students will work in the centre’s laboratories exploring the conversion of feedstock into alternative energy, improving conversion processes and measuring how the new technologies will impact the economy. Supported by a range of relevant industrial, academic and policy partners the centre will equip students to develop the broad range of skills essential for future leaders in decarbonisation. NET2Zero will be led by Professor Patricia Thornley, director of Aston University’s Energy and Bioproducts Research Institute (EBRI). She said: “I am delighted that this centre for doctoral training has been funded. The climate emergency is so stark that we can no longer rely on demand reduction and renewables to meet our decarbonisation targets. “If we are to have greenhouse gas removal options ready in time to be usefully deployed, we need to start now to expand our knowledge and explore the reality of how these can be deployed. This partnership of four leading UK universities with key industrial and policy partners will significantly augment the UK’s ability to deliver on its climate ambitions.” “We are absolutely delighted to be working with our partners to deliver this unique and exciting programme to train the technology leaders of the future. Our students will deliver research outcomes that are urgently needed and only made possible by combining the expertise and resources of all the centre’s academic and industry partners.” Science and technology secretary, Michelle Donelan, said: “As innovators across the world break new ground faster than ever, it is vital that government, business and academia invests in ambitious UK talent, giving them the tools to pioneer new discoveries that benefit all our lives while creating new jobs and growing the economy. “By targeting critical technologies including artificial intelligence and future telecoms, we are supporting world class universities across the UK to build the skills base we need to unleash the potential of future tech and maintain our country’s reputation as a hub of cutting-edge research and development.” Centres for doctoral training have a significant reputation in training future UK academics, industrialists and innovators who have gone on to develop the latest technologies. The University of Nottingham’s Dr Eleanor Binner said: “We are absolutely delighted to be working with our partners to deliver this unique and exciting programme to train the technology leaders of the future. Our students will deliver research outcomes that are urgently needed and only made possible by combining the expertise and resources of all the Centre’s academic and industry partners.” Her colleague Professor Hao Liu added: “We look forward to providing our best support to the NET2Zero CDT, including using our past and existing successful experience in leading other centres, to make this an exemplar.” Overall, there will be 65 new Engineering and Physical Sciences Research Council (EPSRC) centres for doctoral training which will support leading research in areas of national importance including the critical technologies AI, quantum technologies, semiconductors, telecoms and engineering biology. The funding is from a combination of £500 million from UK Research and Innovation and the Ministry of Defence, plus a further £590 million from universities and business partners. Notes to Editors EPSRC and BBSRC Centre for Doctoral Training in Negative Emission Technologies for Net Zero (NET2ZERO) Led by: Professor Patricia Thornley, Aston University The Engineering and Physical Sciences Research Council (EPSRC) is the main funding body for engineering and physical sciences research in the UK. Our portfolio covers a vast range of fields from digital technologies to clean energy, manufacturing to mathematics, advanced materials to chemistry. EPSRC invests in world-leading research and skills, advancing knowledge and delivering a sustainable, resilient and prosperous UK. We support new ideas and transformative technologies which are the foundations of innovation, improving our economy, environment and society. Working in partnership and co-investing with industry, we deliver against national and global priorities. The Biotechnology and Biological Sciences Research Council (BBSRC) invests in world-class bioscience research and training on behalf of the UK public. Our aim is to further scientific knowledge, to promote economic growth, wealth and job creation and to improve quality of life in the UK and beyond. Funded by government, BBSRC invested £451 million in world-class bioscience in 2019-20. We support research and training in universities and strategically funded institutes. BBSRC research and the people we fund are helping society to meet major challenges, including food security, green energy and healthier, longer lives. Our investments underpin important UK economic sectors, such as farming, food, industrial biotechnology and pharmaceuticals. About Centres for Doctoral Training A CDT trains doctoral students with each centre focused on a specific theme or topic. Most CDTs will support five cohorts (a new cohort starting each academic year) with a cohort supporting an average of thirteen students. Fourteen of the centres will have four cohorts rather than five. EPSRC supports doctoral students through three training routes (Doctoral Training Partnerships, ICASE awards and CDTs), and in the last 30 years has supported over 50,000 doctoral students. About Aston University For over a century, Aston University’s enduring purpose has been to make our world a better place through education, research and innovation, by enabling our students to succeed in work and life, and by supporting our communities to thrive economically, socially and culturally. Aston University’s history has been intertwined with the history of Birmingham, a remarkable city that once was the heartland of the Industrial Revolution and the manufacturing powerhouse of the world. Born out of the First Industrial Revolution, Aston University has a proud and distinct heritage dating back to our formation as the School of Metallurgy in 1875, the first UK College of Technology in 1951, gaining university status by Royal Charter in 1966, and becoming The Guardian University of the Year in 2020. Building on our outstanding past, we are now defining our place and role in the Fourth Industrial Revolution (and beyond) within a rapidly changing world. For media inquiries in relation to this release, contact Nicola Jones, Press and Communications Manager, on (+44) 7825 342091 or email: n.jones6@aston.ac.uk

Aston University scientist showcases research to convert rice straw into bioenergy for Philippines’ rural communities

• Rice straw could be a fuel of the future in rural Philippines • Across Asia 300 million tonnes of rice straw go up in smoke every year • New proposals includes scaling up harvesting system with straw removal, biogas-powered rice drying and storage and efficient milling. An Aston University bioenergy researcher has been explaining how rice straw could be a fuel of the future in rural Philippines. Dr Mirjam Roeder who is based at the University’s Energy & Bioproducts Research Institute (EBRI) is collaborating with the UK company Straw Innovations Ltd, Southeast Asian Regional Center for Graduate Study and Research in Agriculture (SEARCA) and Koolmill Systems Ltd to showcase their research. The Food and Agriculture Organisation (FAO) states that rice is the number one food crop globally and 91% of it is produced and consumed in Asia. As a crop it is responsible for 48% of global crop emissions and for every kilogram of rice, a kilo of straw is produced. Across Asia 300 million tonnes of rice straw go up in smoke every year when burnt after harvest, releasing emissions and air pollutants that triple risks of increased respiratory diseases and accelerate climate change. To raise awareness of sustainable uses for rice straw Dr Roeder has travelled to the sixth International Rice Congress in Manila, Philippines to explain the potential of the emerging technology. Rice straw is an underdeveloped feedstock and can be collected and digested to produce biogas, unlocking sustainable straw management options and renewable energy for farmers using anaerobic digestion (AD) from rice straw. Dr Roeder has been working with Straw Innovations on their UK Innovate project demonstration facility in the Philippines, the Rice Straw Biogas Hub, which is scaling up a complete harvesting system with straw removal, biogas-powered rice drying and storage, together with efficient milling. Craig Jamieson, Straw Innovations said: “The International Rice Congress is only held every four years and is a key event for coordinating and tracking progress in rice research. “Our partnership with Aston University and SEARCA adds independent, scientific rigour to the work we do and amplifies our message to government policy makers. We are grateful to Innovate UK for their ongoing support through the Energy Catalyst Programme, which is accelerating our development.” At the conference Dr Roeder has been explaining how independent environmental and social research can increase farmer incomes, equality of opportunity, food security and decarbonisation benefits. She said: “Engaging with stakeholders and working in partnership across organisations is vital to the successful adoption of new technologies. I am delighted to have had the opportunity to host an event with our project partners at this prestigious conference, bringing the cutting-edge research of using rice straw for clean energy to the forefront of the rice research community and supporting the pathway to net zero.” Dr Glenn B Gregorio, Center Director of SEARCA, added: "We are gaining insights into the environmental impact of rice straw utilisation and implementing policies to unleash its potential to empower us to make informed decisions that are instrumental to climate change mitigation and decarbonisation," Professor Rex Demafelis, University of the Philippines, is also working with SEARCA and is leading the project on life cycle analyses and measurements of rice straw greenhouse gas emissions. He said: “Rice straw is a valuable resource, and we are grateful to be part of this team which seeks to harness its full potential and promote circularity, which would ultimately contribute to our goal of reducing our greenhouse gas emissions.” ENDS The Supergen Bioenergy Hub works with academia, industry, government and societal stakeholders to develop sustainable bioenergy systems that support the UK’s transition to an affordable, resilient, low-carbon energy future. The Hub is funded jointly by the Engineering and Physical Sciences Research Council (EPSRC) and the Biotechnology and Biological Sciences Research Council (BBSRC) and is part of the wider Supergen Programme. For further information contact Rebecca Fothergill and Catriona Heaton supergen-bioenergy@aston.ac.uk Follow us on Twitter @SuperBioHub Visit our website at supergen-bioenergy.net Visit our YouTube Channel to watch the video on Carbon Balance FAO: RICE PRODUCTION IN THE ASIA-PACIFIC REGION: ISSUES AND PERSPECTIVES - M.K. Papademetriou* (fao.org) https://www.fao.org/3/x6905e/x6905e04.htm About Aston University For over a century, Aston University’s enduring purpose has been to make our world a better place through education, research and innovation, by enabling our students to succeed in work and life, and by supporting our communities to thrive economically, socially and culturally. Aston University’s history has been intertwined with the history of Birmingham, a remarkable city that once was the heartland of the Industrial Revolution and the manufacturing powerhouse of the world. Born out of the First Industrial Revolution, Aston University has a proud and distinct heritage dating back to our formation as the School of Metallurgy in 1875, the first UK College of Technology in 1951, gaining university status by Royal Charter in 1966, and becoming The Guardian University of the Year in 2020. Building on our outstanding past, we are now defining our place and role in the Fourth Industrial Revolution (and beyond) within a rapidly changing world. For media inquiries in relation to this release, contact Nicola Jones, Press and Communications Manager, on (+44) 7825 342091 or email: n.jones6@aston.ac.uk

Preparing the clean hydrogen workforce

The University of Delaware will play a leading role in workforce development efforts associated with the Mid-Atlantic Clean Hydrogen Hub (MACH2), which has been selected by the U.S. Department of Energy to receive up to $750 million in funding through the historic Regional Clean Hydrogen Hubs program. MACH2 was chosen as one of seven hydrogen hubs, totaling up to $7 billion in grants, announced by the Energy Department on Oct. 13. In stiff national competition, MACH2 ranked among the most pro-labor and greenest hubs in the nation, according to the Delaware Sustainable Chemistry Alliance (DESCA), which brokered the proposal, involving industries, academic institutions, local governments and community partners from across Delaware, southeastern Pennsylvania and South Jersey. Hydrogen is the most abundant element in the universe, and the Energy Department is working to accelerate its use as a clean energy source and as a means to decarbonize heavy industry, transportation and energy storage to meet President Biden’s goal of a 100% clean electrical grid by 2035 and net-zero carbon emissions by 2050, with the regional hydrogen hubs leading the way. MACH2 will encompass a network of hydrogen producers, consumers, local connective infrastructure for hydrogen deployment, and the education and training needed to develop the region’s clean energy workforce. UD will lead the higher education component of MACH2’s workforce development with Cheyney University, Rowan University and the University of Pennsylvania. MACH2 is projected to create 20,000 well-paying jobs in the production, delivery and use of zero-emission hydrogen to repower the region’s industrial facilities, transportation systems and agriculture sectors. What kinds of jobs will MACH2 help prepare people for? There will be a need for technicians for hydrogen-powered vehicles, construction workers for installing hydrogen pipelines, fuel cell power system operators, hydrogen production plant managers, and directors of research and development (R&D) programs, to name a few. Some of these roles may require a high school diploma and an apprenticeship or specific credential; others may require a college degree, from bachelor’s to master’s to Ph.D. Yushan Yan, the Henry Belin du Pont Chair in Chemical and Biomolecular Engineering at UD, will direct the hub’s higher education workforce development efforts. This work will complement high school, vo-tech and community college training programs in energy and construction that will be expanded through the hub, along with pre-apprenticeship programs, particularly those that recruit from underserved communities, offered by building trade unions. “The University of Delaware and our collaborators at Cheyney, Rowan and Penn are well-poised to prepare students for rewarding careers in the new hydrogen economy,” Yan said. “Several engineering, energy and hydrogen programs are already in place at our institutions and will be expanded through the hub, offering students exciting opportunities.” UD will enhance hydrogen technology training at the master’s level through a new “4+1” master’s degree in electrochemical engineering, which would allow highly qualified undergraduate students to earn a bachelor’s degree in an area such as chemical and biomolecular engineering or mechanical engineering and then continue on to earn a master’s degree in electrochemical engineering in the fifth year.

Fashioning Fusion: Villanova Professor Explains Clean Energy Breakthrough

On December 13, scientists at Lawrence Livermore National Laboratory announced a breakthrough that could change the future of clean energy. The long-awaited achievement of nuclear fusion was accomplished by researchers and, if harnessed on a larger scale, fusion energy could provide an energy option without the pollution of fossil fuels and without the radioactive waste of nuclear energy. A new world running on clean energy may not be imminent, but the state of ignition achieved is an important first step. Villanova University professor of mechanical engineering David Cereceda, PhD, received a U.S. Department of Energy Early Career Award from the Office of Fusion Energy Sciences for his research on fusion energy materials—and has worked at the Lawrence Livermore National Laboratory, located in California. "Ignition means that a nuclear fusion reaction becomes self-sustainable," Dr. Cereceda said. "The experiments performed at NIF [National Ignition Facility] last week reached for the first time in history a condition called scientific breakeven, meaning the scientists produced more energy from fusion than the laser energy used to drive it." The breakthrough discovery was made when 192 lasers focused on a cylinder the size of a pencil eraser. That container was filled with a small amount of hydrogen that was encased in a diamond. The resulting reaction that occurred was brief but significant, as this important step has proved allusive to researchers for decades. "Those who criticized fusion said that fusion was always five decades away. That's not true anymore," Dr. Cereceda remarked. "I'm not surprised about the announcement. It finally arrived after decades of hundreds of brilliant scientists and engineers carefully working on it." Still, the national laboratory says much work still lies ahead. Scientists will continue to push toward a higher fusion output and are looking at more efficient ways to produce ignition. Researchers also believe they may still be decades away from making fusion energy a mainstay and usable for the general public. "In my opinion, some of the most important challenges that remain on the path to commercial fusion energy are related to structural materials, tritium breeding blankets and laser technology, among others," mentioned Dr. Cereceda. "Multiple challenges remain to making it a commercial energy source, but this recent and historic breakthrough was a critical milestone."

Expert Says Financial Technologies Can Help Address Climate Change

“Financial technologies offer great promise to tackle climate change and provide pathways for developing sustainable economies and lifestyles,” says Aparna Gupta, a professor of quantitative finance at Rensselaer Polytechnic Institute and co-director of the Center for Research toward Advancing Financial Technologies (CRAFT), the first-ever fintech research center backed by the National Science Foundation. CRAFT brings together industry partners and policy makers to conduct research that is relevant for industry and has potential for commercialization. Dr. Gupta says that blockchain technologies combined with smart contracts and Internet of Things (IoT) devices are set to transform property and casualty insurance that is subject to increasing threats from climate change. Similarly, distributed ledger technologies can be utilized for issuing innovative climate finance securities, such as green bonds and climate derivatives, by facilitating traceable, transparent, and standardized transactions. Regulatory readiness to support blockchain-enabled green bonds and other climate finance securities issuance is underway across the globe. Climate fintech is also set to play a pivotal role in increasing renewable power generation and accelerating the transition to clean energy, according to Dr. Gupta. Digital lending platforms use crowdsourcing models to provide debt financing for residential solar energy systems. Climate-conscious consumers can make spending decisions that minimize their carbon footprint through solutions such as using a credit card that allows them to round up their purchases and use the change for planting trees. In the investment management and advisory space, there is a growing recognition of the need for environmentally sustainable investing. Responding to this need, fintech startups are offering platforms for clean energy investments and enabling investors to construct low-carbon-impact financial portfolios. “Financial technologies innovations are poised to transform almost all aspects of financial services, and in doing so, offer great opportunities to address climate change challenges,” Dr. Gupta says. In addition to her leadership in fintech, Dr. Gupta is at the helm of a team of financial and renewable energy experts developing risk management tools to incorporate renewable energy into the energy market. They will set and standardize risk factors to make it easier for this critical industry to be both productive for investors and creators and systematized for users, similar to the rating system created for the bond market. Dr. Gupta also serves on the Climate Risk Working Group of the Financial Risk Manager Advisory Committee for the Global Association of Risk Professionals tasked with identifying the important climate issues for the training of future global risk professionals. Dr. Gupta is among the many experts and researchers at Rensselaer available to speak on this topic.

Rensselaer Experts Available To Discuss Federal Infrastructure Proposal

Federal lawmakers are discussing sweeping infrastructure improvements to transportation, manufacturing, and digital infrastructure, among other projects. Researchers at Rensselaer Polytechnic Institute, the country’s first technological research university, are leaders in improving the sustainability, safety, and performance of transportation systems, energy systems, and wireless networks, among other areas. Experts in civil and environmental engineering, electrical engineering, and mechanical engineering are available to discuss what impact large-scale infrastructure projects could have on a multitude of systems that impact people across the country. Improving Transportation and Freight Systems: José Holguín-Veras, the director of the Center for Infrastructure, Transportation, and the Environment at Rensselaer, and Cara Wang, an associate professor of civil and environmental engineering at Rensselaer, are leading experts on the role of infrastructure on freight systems and transportation, and the environmental impacts of both. Their research focuses on improving transportation and freight systems in order to increase efficiency, reduce traffic congestion and, in turn, reduce vehicle emissions. Professors Holguín-Veras and Wang are available to discuss the ways in which improved roads, bridges, railways, and ports could affect shipping and delivery of goods, congestion in cities, and emissions in the environment. They can also discuss what their research has uncovered that could guide policymakers as new projects are planned. Expanding Broadband: Alhussein Abouzeid, a professor of electrical, computer, and systems engineering, is an expert in networked systems, the smart grid, and the Internet of Things. Some of his research focuses on modeling wireless networks, as well as wireless spectrum and policies to optimize its use. Koushik Kar, also a professor of electrical, computer, and systems engineering, researches communication networks, particularly modeling, analysis, and optimization of the internet and wireless networks. Both researchers are available to discuss the ways in which digital infrastructure can meet future needs. Next-Generation Manufacturing: Part of the President’s infrastructure plan would allocate $300 billion to manufacturing. Next-generation manufacturing is a central area of expertise at Rensselaer, with the Institute’s Manufacturing Innovation Center and the Rensselaer Manufacturing Innovation Learning Lab. Faculty and staff from both state-of-the-art centers, including John Wen, the head of the Department of Electrical, Computer, and Systems Engineering, who is an expert in robotics, are available to discuss the role that Rensselaer research plays in preparing the manufacturing sector for the nation’s current and future needs. Upgrading Electric Grid, Investing in Clean Energy: Joe Chow, Jian Sun, and Luigi Vanfretti, all professors in the Department of Electrical, Computer, and Systems Engineering, hold extensive expertise in modeling, monitoring, and optimizing the electric power grid. Their work will be integral to the development of a cleaner, more resilient power grid, especially as clean energy sources are increasingly integrated. Christopher Letchford, the head of the Department of Civil and Environmental Engineering, is a global expert in wind engineering. His expertise includes wind power modeling, wind climatology, and the impacts of climate change on infrastructure, transportation, and energy production. Each of these experts is available to discuss the importance of upgrading the nation’s electric grid, and the move toward clean and renewable energy. Boosting Electric Vehicle Numbers: Part of President Biden’s plan focuses on increasing the number of electric vehicles on the road. A key component of improved and more cost-efficient electric vehicles is greener, cheaper, more efficient, and longer-lasting batteries. Nikhil Koratkar, an endowed chair professor of mechanical engineering, is a leading expert in energy storage technologies. He has dedicated his research to improving the batteries that society already uses, while also developing batteries of the future. He can discuss current battery technology and how advancements in energy storage research could help put more electric vehicles on United States roads. Upgrading Water, Wastewater, and Stormwater Systems: Chip Kilduff, an associate professor of civil and environmental engineering, is an expert in managing water quality and water treatment. He has a particular focus on water treatment approaches like membrane and adsorption-separation processes. Kilduff is available to discuss the importance of upgrading water and wastewater systems and what his research has uncovered about the best methods for managing water quality.