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REDMOND, Ore., Dec. 20, 2024 (GLOBE NEWSWIRE) -- Expion360 Inc. XPON ("Expion360" or the "Company"), an industry leader in lithium-ion battery power storage solutions, announced today the resignation of Greg Aydelott, Chief Financial Officer of the Company, effective December 31, 2024, due to family health concerns. Mr. Aydelott intends to remain available to the Company on an ongoing basis as a consultant to ensure a smooth transition. The Company's Board of Directors has appointed the Company's Chief Executive Officer, Brian Schaffner, as interim Chief Financial Officer, and Principal Financial and Accounting Officer, effective December 31, 2024, and is conducting a search process to identify a new CFO. Mr. Schaffner previously served as the CFO of Expion360 from March 2021 through January 2023. "On behalf of our Board of Directors, leadership team and employees, I would like to thank Greg for his outstanding service and commitment over the past three years," said Mr. Schaffner. "He has made significant contributions to Expion360's success, including managing our growth, strengthening our balance sheet, enhancing our planning and budgeting process, and overseeing investments in new technologies and batteries." "This has been an incredible journey with talented people, and it has been a privilege to help lead this passionate team," said Mr. Aydelott. "I look forward to following the success of Expion360 for years to come." About Expion360 Expion360 is an industry leader in premium lithium iron phosphate (LiFePO4) batteries and accessories for recreational vehicles and marine applications, with residential and industrial applications under development. On December 19, 2023, the Company announced its entrance into the home energy storage market with the introduction of two premium LiFePO4 battery storage systems that enable residential and small business customers to create their own stable micro-energy grid and lessen the impact of increasing power fluctuations and outages. The Company's lithium-ion batteries feature half the weight of standard lead-acid batteries while delivering three times the power and ten times the number of charging cycles. Expion360 batteries also feature better construction and reliability compared to other lithium-ion batteries on the market due to their superior design and quality materials. Specially reinforced, fiberglass-infused, premium ABS and solid mechanical connections help provide top performance and safety. With Expion360 batteries, adventurers can enjoy the most beautiful and remote places on Earth even longer. The Company is headquartered in Redmond, Oregon. Expion360 lithium-ion batteries are available today through more than 300 dealers, wholesalers, private-label customers, and OEMs across the country. To learn more about the Company, visit expion360.com . Forward-Looking Statements and Safe Harbor Notice This press release contains certain forward-looking statements within the meaning of Section 27A of the Securities Act of 1933, as amended, and Section 21E of the Securities Exchange Act of 1934, as amended, which statements are subject to considerable risks and uncertainties. The Company intends such forward-looking statements to be covered by the safe harbor provisions contained in the Private Securities Litigation Reform Act of 1995. All statements other than statements of historical facts included in this press release, including statements about our beliefs and expectations, are "forward-looking statements" and should be evaluated as such. Examples of such forward-looking statements include statements that use forward-looking words such as "projected," "expect," "possibility," "believe," "aim," "goal," "plan," and "anticipate," or similar expressions. Forward-looking statements included in this press release include, but are not limited to, statements relating to the expected timing and impact of the executive transition, including Mr. Aydelott's continuing role as a consultant to the Company, and the Company's ability to build on its momentum and achieve its financial and strategic objectives. Forward-looking statements are subject to and involve risks, uncertainties, and assumptions that may cause the Company's actual results, performance or achievements to be materially different from any future results, performance or achievements predicted, assumed or implied by such forward-looking statements. Company Contact: Brian Schaffner, CEO 541-797-6714 Email Contact External Investor Relations: Chris Tyson, Executive Vice President MZ Group - MZ North America 949-491-8235 XPON@mzgroup.us www.mzgroup.us © 2024 Benzinga.com. Benzinga does not provide investment advice. All rights reserved.December 20, 2024 This article has been reviewed according to Science X's editorial process and policies . Editors have highlightedthe following attributes while ensuring the content's credibility: fact-checked peer-reviewed publication trusted source proofread by Rice University Researchers at Rice University have made a meaningful advance in the simulation of molecular electron transfer—a fundamental process underpinning countless physical, chemical and biological processes. The study, published in Science Advances , details the use of a trapped-ion quantum simulator to model electron transfer dynamics with unprecedented tunability, unlocking new opportunities for scientific exploration in fields ranging from molecular electronics to photosynthesis. Electron transfer, critical to processes such as cellular respiration and energy harvesting in plants, has long posed challenges to scientists due to the complex quantum interactions involved. Current computational techniques often fall short of capturing the full scope of these processes. The multidisciplinary team at Rice, including physicists, chemists and biologists, addressed these challenges by creating a programmable quantum system capable of independently controlling the key factors in electron transfer : donor-acceptor energy gaps, electronic and vibronic couplings and environmental dissipation. Using an ion crystal trapped in a vacuum system and manipulated by laser light , the researchers demonstrated the ability to simulate real-time spin dynamics and measure transfer rates across a range of conditions. The findings not only validate key theories of quantum mechanics but also pave the way for novel insights into light-harvesting systems and molecular devices. "This is the first time that this kind of model was simulated on a physical device while including the role of the environment and even tailoring it in a controlled way," said lead researcher Guido Pagano, assistant professor of physics and astronomy. "It represents a significant leap forward in our ability to use quantum simulators to investigate models and regimes that are relevant for chemistry and biology. The hope is that by harnessing the power of quantum simulation, we will eventually be able to explore scenarios that are currently inaccessible to classical computational methods." The team achieved a significant milestone by successfully replicating a standard model of molecular electron transfer using a programmable quantum platform. Through the precise engineering of tunable dissipation, the researchers explored both adiabatic and nonadiabatic regimes of electron transfer, demonstrating how these quantum effects operate under varying conditions. Additionally, their simulations identified optimal conditions for electron transfer, which parallel the energy transport mechanisms observed in natural photosynthetic systems. "Our work is driven by the question: Can quantum hardware be used to directly simulate chemical dynamics?" Pagano said. "Specifically, can we incorporate environmental effects into these simulations as they play a crucial role in processes essential to life such as photosynthesis and electron transfer in biomolecules? Addressing this question is significant as the ability to directly simulate electron transfer in biomolecules could provide valuable insights for designing new light-harvesting materials." The implications for practical applications are far-reaching. Understanding electron transfer processes at this level could lead to breakthroughs in renewable energy technologies , molecular electronics and even the development of new materials for quantum computing. "This experiment is a promising first step to gain a deeper understanding of how quantum effects influence energy transport, particularly in biological systems like photosynthetic complexes," said Jose N. Onuchic, study co-author, the Harry C. and Olga K. Wiess Chair of Physics and professor of physics and astronomy, chemistry and biosciences. "The insights we gain in this type of experiment could inspire the design of more efficient light-harvesting materials." Discover the latest in science, tech, and space with over 100,000 subscribers who rely on Phys.org for daily insights. Sign up for our free newsletter and get updates on breakthroughs, innovations, and research that matter— daily or weekly . Peter G. Wolynes, study co-author, the D.R. Bullard-Welch Foundation Professor of Science and professor of chemistry, biosciences and physics and astronomy, emphasized the broader significance of the findings: "This research bridges the gap between theoretical predictions and experimental verification, offering an exquisitely tunable framework for exploring quantum processes in complex systems." The team plans to extend its simulations to include more complex molecular systems such as those involved in photosynthesis and DNA charge transport. The researchers also hope to investigate the role of quantum coherence and delocalization in energy transfer, leveraging the unique capabilities of their quantum platform. "This is just the beginning," said Han Pu, co-lead author of the study and professor of physics and astronomy. "We are excited to explore how this technology can help unravel the quantum mysteries of life and beyond." The study's other co-authors include graduate students Visal So, Midhuna Duraisamy Suganthi, Abhishek Menon, Mingjian Zhu and research scientist Roman Zhuravel. More information: Visal So et al, Trapped-ion quantum simulation of electron transfer models with tunable dissipation, Science Advances (2024). DOI: 10.1126/sciadv.ads8011 Journal information: Science Advances Provided by Rice University

The San Francisco 49ers are preparing for their Week 17 contest against the Detroit Lions on Monday at Levi's Stadium in Santa Clara, California. Several 49ers offensive linemen were absent from practice on Thursday. In addition to those already on injured reserve—tackles Trent Williams and Jaylon Moore—guards Aaron Banks and Spencer Burford, along with tackle Colton McKivitz, were also unavailable. Banks is out for the remainder of the season after suffering an MCL injury. Head coach Kyle Shanahan expressed hope that Burford, who was injured against the Miami Dolphins, might be ready to play on Monday night. However, it sounded like a long shot. McKivitz was limited during Wednesday's practice due to a knee injury, so missing Thursday's session raises additional concern. https://twitter.com/mattbarrows/status/1872755113250677031 Linebacker Dre Greenlaw also did not practice and is not expected to return this season. On a positive note, running back Isaac Guerendo (limited) and defensive end Nick Bosa (full) participated in practice, signaling that both should be ready for Monday night's matchup against the Lions. The 49ers will hold one more practice—on Saturday—before the game. Below are Friday's practice participation reports for both the 49ers and Lions, which were provided by the 49ers Communications staff. San Francisco 49ers Friday Practice Did Not Participate In Practice G Aaron Banks (knee), DE Robert Beal (ankle), G Spencer Burford (calf), LB Dre Greenlaw (calf), FB Kyle Juszczyk (illness), T Colton McKivitz (knee) Limited Participation in Practice S Ji'Ayir Brown (ankle), DE Leonard Floyd (shoulder), RB Isaac Guerendo (foot, hamstring) Full Participation in Practice LB Tatum Bethune (knee), DE Nick Bosa (hip, oblique), DT Jordan Elliott (knee), S Talanoa Hufanga (wrist), LB Dee Winters (chest) Detroit Lions Friday Practice Did Not Participate In Practice RB David Montgomery (knee) Limited Participation in Practice CB Terrion Arnold (illness) Full Participation in Practice G Graham Glasgow (knee), WR Kalif Raymond (foot), LB Jalen Reeves-Maybin (neck) This article first appeared on 49ers Webzone and was syndicated with permission.

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