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Aurora Solar Teams Up with EagleView to Enhance Solar Design Accuracy and Efficiency

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Aurora Solar Teams Up with EagleView to Enhance Solar Design Accuracy and Efficiency


Aurora Solar Teams Up with EagleView to Enhance Solar Design Accuracy and Efficiency

by Clarence Oxford

Los Angeles CA (SPX) Mar 07, 2024






In a move set to redefine the standards of solar project planning and execution, Aurora Solar, a leader in solar sales and design software, has announced a strategic partnership with EagleView, a pioneer in aerial imagery and geospatial analytics. This collaboration leverages three decades of engineering prowess from both entities to craft unparalleled solar solutions, aiming to streamline the workflow of solar professionals significantly.

EagleView’s cutting-edge aerial imagery and analytics are poised to integrate seamlessly with Aurora’s platform, offering an unmatched level of detail and accuracy in project planning. This synergy is expected to empower solar professionals to prospect, plan, and validate projects with an unprecedented degree of precision, all while eliminating the need for physical site visits.



Key Benefits of the Aurora-EagleView Partnership

Aurora customers stand to gain a myriad of advantages from this partnership, including access to superior high-resolution imagery. With aerial photography offering sub-one inch resolution, the combined Aurora and EagleView solution covers over 94 percent of the U.S. population, providing seventy times more detail than traditional satellite imagery. This level of detail ensures that solar designs are as accurate and reliable as possible, fostering trust between solar professionals and homeowners.



Moreover, the integration brings high precision 3D roof models to Aurora’s toolkit. This addition enhances remote solar design outcomes, leading to an increase in installable projects, reduced costs, and minimized delays that often arise from redesigns and renegotiations. The comprehensive property data and imagery from EagleView are instrumental in creating more accurate and trusted proposals, ultimately enhancing the overall homeowner experience.



A Commitment to Advancing Solar Design Accuracy

Carina Brockl, CRO at Aurora Solar, emphasized the company’s dedication to investing in the industry’s most trusted platform. “As solar continues its unprecedented global growth, we’re delighted that our groundbreaking partnership with EagleView will deliver new benefits to our customers as we double down on our commitment to design accuracy,” Brockl stated.



Echoing this sentiment, Peter Cleveland, VP of Solar at EagleView, highlighted the significance of combining Aurora’s and EagleView’s capabilities. “Joining Aurora’s industry-leading solar capabilities with EagleView’s powerful property intelligence and analytics provides solar installers with an all-encompassing design and sales solution that drives results,” said Cleveland. He further stressed the timely need for such advanced tools in the industry, underscoring the potential to enhance the experience for both solar professionals and homeowners.



A Leap Forward for the Solar Industry

The partnership between Aurora Solar and EagleView represents a significant leap forward for the solar industry. By harnessing the power of advanced aerial imagery and precise analytics, solar professionals can now approach project planning and execution with a new level of confidence and efficiency.



This collaboration not only promises to improve the accuracy of solar designs but also to streamline the sales process, making solar installations more accessible and appealing to a broader audience. As the solar industry continues to grow, such innovations will be crucial in maintaining momentum and ensuring the successful adoption of solar technology across the United States.


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‘Capture the oxygen’ strategy boosts lithium-ion battery lifespan

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‘Capture the oxygen’ strategy boosts lithium-ion battery lifespan


‘Capture the oxygen’ strategy boosts lithium-ion battery lifespan

by Riko Seibo

Tokyo, Japan (SPX) Dec 27, 2024






A team of researchers from POSTECH, led by Professor Jihyun Hong of the Department of Battery Engineering and Dr. Gukhyun Lim, has unveiled a key method to extend the durability of lithium-rich layered oxide (LLO) material, a promising cathode for next-generation lithium-ion batteries (LIBs). Their findings, published in Energy and Environmental Science, represent a major step forward in the development of high-energy-density, sustainable battery technologies.

LLO materials provide a 20% increase in energy density over traditional nickel-based cathodes by substituting nickel and cobalt with lithium and manganese. This makes them a cost-effective and eco-friendly alternative for electric vehicles and energy storage systems (ESS). However, widespread adoption has been hindered by capacity fading and voltage decay during repeated charge-discharge cycles.



Addressing these challenges, the POSTECH researchers focused on the destabilizing effect of oxygen release during battery operation. By improving the chemical stability of the cathode-electrolyte interface, they minimized oxygen release, a primary cause of structural instability. Enhancing the electrolyte composition, they achieved an 84.3% energy retention rate after 700 cycles, compared to just 37.1% retention after 300 cycles with conventional electrolytes.



The team also identified structural surface changes in LLO as critical to stability and lifespan. By targeting these changes, they reduced detrimental reactions such as electrolyte decomposition, further improving battery performance.



“Using synchrotron radiation, we analyzed chemical and structural differences between the cathode surface and its interior,” said Professor Jihyun Hong. “We discovered that surface stability is essential for maintaining the material’s structural integrity and performance. This work opens new pathways for developing advanced cathode materials.”



The research highlights the critical importance of optimizing both electrolyte composition and cathode surface structure to overcome the limitations of LLO materials, paving the way for longer-lasting, high-performance lithium-ion batteries.



Research Report:Decoupling capacity fade and voltage decay of Li-rich Mn-rich cathodes by tailoring surface reconstruction pathways


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Breakthrough new material brings affordable, sustainable future within grasp

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Breakthrough new material brings affordable, sustainable future within grasp


Breakthrough new material brings affordable, sustainable future within grasp

by Rashda Khan for Canepa News

Houston TX (SPX) Dec 23, 2024






While lithium-ion batteries have been the go-to technology for everything from smartphones and laptops to electric cars, there are growing concerns about the future because lithium is relatively scarce, expensive and difficult to source, and may soon be at risk due to geopolitical considerations. Scientists around the world are working to create viable alternatives.

An international team of interdisciplinary researchers, including the Canepa Research Laboratory at the University of Houston, has developed a new type of material for sodium-ion batteries that could make them more efficient and boost their energy performance – paving the way for a more sustainable and affordable energy future.



The new material, sodium vanadium phosphate with the chemical formula NaxV2(PO4)3, improves sodium-ion battery performance by increasing the energy density – the amount of energy stored per kilogram – by more than 15%. With a higher energy density of 458 watt-hours per kilogram (Wh/kg) compared to the 396 Wh/kg in older sodium-ion batteries, this material brings sodium technology closer to competing with lithium-ion batteries.



“Sodium is nearly 50 times cheaper than lithium and can even be harvested from seawater, making it a much more sustainable option for large-scale energy storage,” said Pieremanuele Canepa, Robert Welch assistant professor of electrical and computer engineering at UH and lead researcher of the Canepa Lab. “Sodium-ion batteries could be cheaper and easier to produce, helping reduce reliance on lithium and making battery technology more accessible worldwide.”

From Theory to Reality

The Canepa Lab, which uses theoretical expertise and computational methods to discover new materials and molecules to help advance clean energy technologies, collaborated with the research groups headed by French researchers Christian Masquelier and Laurence Croguennec from the Laboratoire de Rea’ctivite’ et de Chimie des Solides, which is a CNRS laboratory part of the Universite’ de Picardie Jules Verne, in Amiens France, and the Institut de Chimie de la Matie`re Condense’e de Bordeaux, Universite’ de Bordeaux, Bordeaux, France for the experimental work on the project. This allowed theoretical modelling to go through experimental validation.

The researchers created a battery prototype using the new material, NaxV2(PO4)3, demonstrating significant energy storage improvements. NaxV2(PO4)3, part of a group called “Na superionic conductors” or NaSICONs, is designed to let sodium ions move smoothly in and out of the battery during charging and discharging.



Unlike existing materials, it has a unique way of handling sodium, allowing it to work as a single-phase system. This means it remains stable as it releases or takes in sodium ions. This allows the NaSICON to remain stable during charging and discharging while delivering a continuous voltage of 3.7 volts versus sodium metal, higher than the 3.37 volts in existing materials.



While this difference may seem small, it significantly increases the battery’s energy density or how much energy it can store for its weight. The key to its efficiency is vanadium, which can exist in multiple stable states, allowing it to hold and release more energy.



“The continuous voltage change is a key feature,” said Canepa. “It means the battery can perform more efficiently without compromising the electrode stability. That’s a game-changer for sodium-ion technology.”

Possibilities for a Sustainable Future

The implications of this work extend beyond sodium-ion batteries. The synthesis method used to create NaxV2(PO4)3 could be applied to other materials with similar chemistries, opening new possibilities for advanced energy storage technologies. That could in turn, impact everything from more affordable, sustainable batteries to power our devices to help us transition to a cleaner energy economy.



“Our goal is to find clean, sustainable solutions for energy storage,” Canepa said. “This material shows that sodium-ion batteries can meet the high-energy demands of modern technology while being cost-effective and environmentally friendly.”



A paper based on this work was published in the journal Nature Materials. Ziliang Wang, Canepa’s former student and now a postdoctoral fellow at Northwestern University, and Sunkyu Park, a former student of the French researchers and now a staff engineer at Samsung SDI in South Korea, performed much of the work on this project.



Research Report:Obtaining V2(PO4)3 by sodium extraction from single-phase NaxV2(PO4)3 (1 < x < 3) positive electrode materials


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Pioneering advancements in solid-state battery technology for energy storage

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Pioneering advancements in solid-state battery technology for energy storage


Pioneering advancements in solid-state battery technology for energy storage

by Riko Seibo

Tokyo, Japan (SPX) Dec 23, 2024






Recent strides in solid-state battery technology are setting the stage for a transformative era in energy storage. These advancements hold promise for revolutionizing electric vehicles and renewable energy systems through improved performance and safety. A focus on electrolyte innovation has been key to this progress, enabling the development of high-performance all-solid-state batteries (ASSBs).

A new review paper provides a comprehensive summary of advancements in inorganic solid electrolytes (ISEs), materials that are central to ASSBs. Researchers examined the roles of oxides, sulfides, hydroborates, antiperovskites, and halides not only as electrolytes but also as catholytes and interface layers, which collectively enhance battery performance and safety.



“We highlighted the recent breakthroughs in synthesizing these materials, honing our attention on the innovative techniques that enable the precise tuning of their properties to meet the demanding requirements of ASSBs,” said Eric Jianfeng Cheng, associate professor at Tohoku University’s Advanced Institute for Materials Research (AIMR). “Precise tuning is crucial for developing batteries with higher energy densities, longer life cycles, and better safety profiles than conventional liquid-based batteries.”



The review also delves into the electrochemical properties of ISEs, including ionic conductivity, stability, and electrode compatibility. Researchers evaluated current ASSB models and suggested emerging strategies that could drive the next generation of energy storage solutions.



However, challenges persist in the development of ASSBs, notably the limited compatibility between ISEs and electrodes, which can trigger interfacial reactions. Addressing these compatibility issues is vital to improving battery efficiency and longevity. The review outlines these challenges and provides insights into efforts aimed at overcoming them.



“Our comprehensive review underscores the importance of continued research and development in the field of solid-state batteries. By developing new materials, improving synthesis methods, and overcoming compatibility issues, current efforts are driving innovation toward practical ASSBs that could transform how we store and use energy,” Cheng added.



Research Report:Inorganic solid electrolytes for all-solid-state lithium/sodium-ion batteries: recent developments and applications


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