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• 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
Extreme heat is stretching the United States' electricity infrastructure to maximum capacity, and the reported disjointedness of the country's three electric grids has made it more difficult to deliver wind and solar power as reinforcements. Willett Kempton, professor of marine science and policy at the University of Delaware, led the development of a way to use electric car batteries to make grids more stable and resilient. Kempton advocates using electric storage through V2G technology to make electricity more reliable at a lower cost today and to enable the grid to use more renewable energy in the future. Kempton, associate director of vehicle-to-grid (V2G) technology for UD's Center for Research in Wind (CReW), pioneered technology for vehicle-to-grid (V2G) vehicles, which are capable of absorbing excess energy when demand for power is low and returning some back to the electric grid when the demand for power is high.
Aston University biofuel experts advise on how Ukraine can build back greener
• Aston University biofuel experts provide advice on Ukraine’s recovery • Professor Patricia Thornley and Dr Vesna Najdanovic were invited to Royal Society conference • Outcomes will be presented to policymakers at Ukraine Recovery Conference in June. Two Aston University scientists have provided expert advice on how the UK’s wealth of research can support Ukraine’s reconstruction. A two-day conference was organised by the Royal Society and its outcomes will be presented to policymakers ahead of the UK government-hosted Ukraine Recovery Conference in June. As Ukraine is one of the largest agricultural producers and exporters it also generates large amounts of agricultural waste which could be used to produce biofuels and valuable chemicals. This could decrease the country’s fuel import dependency and increase the revenues for the sector. Researchers at the conference explored how to tackle some of the many challenges facing Ukraine, from rebuilding its economy, health and wellbeing, regional security and planning for a green recovery. Professor Patricia Thornley who is director of Aston University’s Energy and Bioproducts Research Institute (EBRI), was one of the just three academics invited to contribute to an infrastructure roundtable session. Professor Thornley said: “I was honoured to be asked to attend the infrastructure roundtable and share my expertise on renewable energy and sustainable products. “Ukraine has significant sustainable agricultural and forestry residues, which can be valuable to plug potential gaps in oil and gas supply for heating in the short term. But in the long term these can provide opportunities to produce sustainable bio chemicals and materials which could provide a basis to grow green chemical, material and construction industries. “UK researchers, such as those at EBRI at Aston University and the Supergen Bioenergy Hub, have the experience needed to work on developing these solutions to build back greener. Research evidence and expertise have a vital role to play in supporting policy makers to tackle the complex and urgent challenges related to the reconstruction and recovery of a resilient, sustainable Ukraine.” Meanwhile, Dr Vesna Najdanovic presented opportunities to develop bioenergy and bioproducts in Ukraine at the event and participated as a panel member. Ukraine’s recovery: rebuilding with research, which brought together Ukrainian and UK researchers and policy makers, was held on 15 and 16 May in London. It was funded by Universities UK International, Research England and the British Council and supported by the Academy of Medical Sciences, British Academy and the Royal Academy of Engineering.
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Going green: Solar and wind power remain the best alternatives to fossil fuels
Find video for use here. In the U.S., more and more individuals, and even corporations, are making it a priority to go green in an effort to reduce the nation's dependence on fossil fuels. Studies have proven carbon dioxide is a main contributor to human-caused climate change, so we're tapping into natural elements more often to reduce the use of fossil fuels. From solar farms to solar panels on houses and wind turbines, it’s tough not to find efforts to go green, and that’s a move in the right direction, according to Jessica Reichmuth, PhD, professor in the Department of Biological Sciences in the College of Science and Mathematics at Augusta University. She said we’re heading in the right direction, but more can be done. “We are taking the right steps, but I’m not sure if we will be entirely able to be green energy, but we definitely need to be more green than we are today,” said Reichmuth. “Fossil fuels will eventually run out and are a non-renewable resource.” Homeowners and municipalities are tapping into solar panels most often as a green resource. Some concerns include the costs involved and the fact that in most cases, the panels are permanently attached to a house. Reichmuth points to California as an example of a state trying to ease that burden. Some people who are moving into rental houses and know they aren’t going to be there for a long period of time can have a company attach removable panels. There are other companies jumping into the business of leasing solar panels as well. Even small panels the size of a binder located in a backyard can make a big difference in producing a noticeable amount of electricity. These are great steps, said Reichmuth, but more progress can still be made. “We are at a point within society with green technology that we know and understand how to make solar panels, the infrastructure is there to support them, we just need a movement to get them so they’re used everywhere,” Reichmuth said. Wind turbines remain a big source of discussion. Yes, they provide an alternative electric source, but at what cost? A big negative is the possibility of bird strikes. “Birds will learn to navigate around wind turbines. They are not built in a way that they are impervious to long-distance migration.” Hydroelectricity and geothermal energy are two other green sources of energy. There are not a lot of areas in the U.S. that offer geothermal resources, and as far as hydroelectricity goes, there’s still concern in Reichmuth’s eyes. “I think it would be great to see if dams are going to be used for hydroelectricity, but not as a water containment system. There are portions of the U.S., especially in the southwest, that are dealing with water issues because we have dammed them. Hydroelectricity is good if the dam is used specifically for that purpose and not water containment.” Renewable energy, cost savings and ESG are top of mind for corporations, governments and populations as we look to the future, and if you're a journalist covering this topic, then let us help. Jessica Reichmuth is available to speak with media. Simply click on her icon now to arrange an interview today.
• Professor Patricia Thornley welcomes latest UK energy security plans • But calls for more exploration of bioenergy with carbon capture and storage • She believes plans shouldn’t concentrate solely on energy such as wind and solar power. A leading biomass scientist at Aston University has welcomed the government’s announcement to ensure UK energy is more secure. However, Professor Patricia Thornley, director of Aston University’s Energy and Bioproducts Research Institute (EBRI), believes the government shouldn’t just concentrate on energy such as wind and solar power. She is calling for the government to explore the use of power bioenergy with carbon capture and storage (or power BECCS). On 30 March the Department for Energy Security and Net Zero published the Powering Up Britain: Net Zero Growth Plan, and the Powering Up Britain: Energy Security Plan to set out steps to make the UK more energy independent, secure and resilient. Professor Thornley believes that the UK’s carbon reduction targets could be tackled by delivering negative emission BECCS projects. The process uses sustainable biomass and waste materials to generate electricity in combination with carbon capture and permanent storage. Through this physical removal of greenhouse gases from the atmosphere, power BECCS is able to deliver negative emissions. Professor Thornley said: “It is wonderful to see the government moving forward with its carbon reduction plans, whilst recognising the scale of the challenge faced. “Bioenergy is delivering carbon reductions around the UK today - 62% of our renewable energy and around 13% of our electricity comes from biomass - and developing sustainable biomass conversion with carbon capture and storage (CCS) would be a natural progression for the UK. “So it is good to see commitment to CCS, but to fully leverage the UK’s negative emission potential we need BECCS technology to be rapidly deployed.” EBRI and the Supergen Bioenergy hub, which is led by Aston University, are working on applied research to progress this ambition. Professor Thornley added: “Our research at Aston University has demonstrated the potential for sustainable BECCS facilities to deliver a substantial proportion of UK required negative emissions but that the exact amount of negative emissions achieved can vary hugely with plant design and operational choices. So we hope to use our knowledge and research outputs to support UK deployment of sustainable bioenergy moving forward.“ As well as her research at Aston University, Professor Thornley has been contributing her expertise to a government working group exploring the sustainable use of biomass for two years. ENDS
Permanent magnets play an indispensable role in renewable energy technologies, including wind turbines, hydroelectric power generators and electric vehicles. Ironically, the magnets used in these “clean energy” technologies are made from rare earth elements such as neodymium, dysprosium and samarium that entail environmentally hazardous mining practices and energy-intensive manufacturing processes, according to Radhika Barua, Ph.D., mechanical and nuclear engineering assistant professor. Access to these rare earth magnets is also heavily reliant on China and demand for them is expected to grow as the U.S. seeks to meet net-zero carbon emissions by 2050. “That anticipated demand poses a challenge to U.S. decarbonization goals as the rare earth elements are characterized by substantial market volatility and geopolitical sensitivity,” Barua says. “This is where our project comes in.” Barua and fellow VCU professors Afroditi Filippas, Ph.D., and Everett Carpenter, Ph.D., are part of a team of VCU researchers working to create new types of magnets. By using additive manufacturing, more commonly known as 3D printing, they hope to create replacements for those permanent magnets composed of rare earth elements that are made from materials readily available in the U.S. China mines 58 percent of the global supply of rare earth elements used to make neodymium magnets that are widely used in consumer and industrial electronics, the U.S. Department of Energy (DOE) noted in a February 2022 report. That dominance grows throughout the manufacturing process with China accounting for 92 percent of global magnet production, the DOE estimates. “It would be ideal if we could manufacture the same magnets with the same characteristics without using rare earth elements,” says Filippas, who teaches electromagnetics at VCU. “It would be even better if we could make these magnets using additive manufacturing techniques.” VCU researchers are trying to do that in collaboration with the Commonwealth Center for Advanced Manufacturing (CCAM), which brings university, industry and government officials together to tackle manufacturing challenges. The professors are conducting much of their work at CCAM’s lab in Disputanta, Virginia. “We have access to equipment that we would not have access to at VCU,” Filippas says of the benefits of the CCAM partnership. “They provide that level of expertise using the equipment and understanding the process.” The project is funded by the VCU Breakthroughs Fund and CCAM. Barua is working with Carpenter, a chemistry professor, on the materials science part of the project. Filippas is focusing on data analytics and is helping develop a monitoring process to ensure the newly-crafted replacement magnets are viable. In addition to providing a more stable source of supply, Barua says the replacement magnets could also bring environmental benefits. Providing an alternative to rare earth magnets would involve less hazardous mining techniques while also reducing emissions and energy consumption. The replacement magnets are made by filtering particles of iron, cobalt, nickel and manganese through a nozzle where a laser fuses them together through a process known as direct energy deposition. That metal 3D printing approach can make complex shapes while minimizing raw material use and manufacturing costs, Barua says. “Right now, we’re printing straight lines just to see what we’re going to get and see if we can even print them,” Filippas says. “Are we getting the composition of the materials that we want? It’s a slow painstaking process towards freedom from reliance on rare earth materials.” Barua says using additive manufacturing allows researchers to create a unique microstructure layer-by-layer instead of simply making magnets from a cast. Researchers do not expect their replacements to mimic the full strength of rare earth magnets, but they hope to produce mid-tier magnets that are as close as possible to current magnets. Carpenter adds their new magnets could potentially be smaller and weigh less than rare earth magnets, which could lead to numerous benefits. “This reduction would be a big savings to the automobile manufacturing industry, for example, where every ounce matters,” Carpenter says. “In an S-Class Mercedes, there are over 130 magnets used in sensors, actuators or motors. This approach could save pounds of weight which translates into fuel efficiency.” Barua says the team is working to establish the feasibility of their new magnet-making process. They are trying to get the microstructure of the new magnets just right and are using additive manufacturing to fine-tune their magnetic properties, Barua says. “When artificial diamonds, cubic zirconia, was synthetically produced in the lab, it changed the entire diamond industry,” Barua says. “That’s exactly what we’re trying to do. We’re trying to make synthetic magnets.”
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.
First Commercial-Scale Wind Farm in the U.S. Would Generate Electricity to Power 400,000 Homes
The Vineyard Wind project, located off the coast of Massachusetts, is the first major offshore wind farm in the United States. It is part of a larger push to tackle climate change, with other offshore wind projects along the East Coast under federal review. The U.S. Department of the Interior has estimated that, by the end of the decade, 2,000 turbines could be along the coast, stretching from Massachusetts to North Carolina. "While the case for offshore wind power appears to be growing due to real concerns about global warming, there are still people who fight renewable energy projects based on speculation, misinformation, climate denial and 'not in my backyard' attitudes," says Karl F. Schmidt, a professor of practice in Villanova University's College of Engineering and director of the Resilient Innovation through Sustainable Engineering (RISE) Forum. "There is overwhelming scientific evidence that use of fossil fuels for power generation is driving unprecedented levels of CO2 into our atmosphere and oceans. This causes sea level rise, increasing ocean temperature and increasing ocean acidity, all which have numerous secondary environmental, economic and social impacts." Schmidt notes that what's often missing for large capital projects like the Vineyard Wind project is a life cycle assessment (LCA), which looks at environmental impacts throughout the entire life cycle of the project, i.e., from raw material extraction, manufacturing and construction through operation and maintenance and end of life. These impacts, in terms of tons/CO2 equivalent, can then be compared with the baseline—in this case, natural gas/coal power plants. "With this comprehensive look, I suspect the LCA for an offshore wind farm would be significantly less than a fossil fuel power plant," says Prof. Schmidt. Complementing the LCA should be a thorough, holistic view encompassing the pertinent social, technological, environmental, economic and political (STEEP) aspects of the project, notes Prof. Schmidt. "This would include all views of affected stakeholders, such as residents, fishermen, local officials and labor markets. Quantifying these interdependent aspects can lead to a more informed and balanced decision-making process based on facts and data." "At Villanova's Sustainable Engineering Department, we've successfully used both the LCA and STEEP processes... for many of our RISE Forum member companies' projects," notes Prof. Schmidt.
Power Grid Expert Weighs in on Texas Outages And How to Build a Better System
Having run countless simulations and experiments aimed at building a more resilient power grid, Luigi Vanfretti is well acquainted with the weaknesses in the nation’s current system. This expertise was recently featured in a report about the factors that caused massive, ongoing power outages in Texas. Frozen well heads, gas pipes, and other factors contributed to a “perfect storm” of conditions, Vanfretti said. Some politicians and pundits have floated the notion that the catastrophe was primarily due to frozen wind turbines, but according to Vanfretti, an associate professor of electrical, computer, and systems engineering at Rensselaer Polytechnic Institute, the problem is far more complex. Additionally, the electrical grid in Texas is unique in that it has limited connections to neighboring states, which means there are limitations to how much assistance it can receive during a crisis. “It’s about the ability to route the power,” Vanfretti recently told the Times Union. Vanfretti is an expert in power grid modeling, simulation, stability, and control. His research focuses on creating a smarter, cleaner, more reliable power grid that is capable of integrating renewable energy. Within his Analysis Laboratory for Synchrophasor and Electrical Energy Technology (ALSET) Lab, Vanfretti and his team model the power grid and run simulations in order to develop, test, and improve smart inverters, software, and hardware that will be needed to create the smart grid of the future. You can watch him discuss his research here. Vanfretti is available to speak about what contributed to the devastating outages in Texas, as well as the changes and research necessary to create a more resilient power system.