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1. Carbon footprint of Li-Oxygen batteries and the impact of material and structure selection

   https://doi.org/10.1016/j.est.2023.106684  

   Chen-Glasser, Melodie; Landis, Amy E.; DeCaluwe, Steven C. (April 2023, Journal of Energy Storage)

   High energy density lithium-O2 batteries have potential to increase electric vehicle driving range, but commercialization is prevented by technical challenges. Researchers have proposed electrolytes, catalysts, and binders to improve the battery capacity and reduce capacity fade. Novel battery design, however, is not always consistent with reduction in greenhouse gas (GHG) emissions. Optimizing battery design using solely electrochemical metrics ignores variations in the environmental impacts of different materials. The lack of uniform reporting practices further complicates such efforts. This paper presents commonly used lithium-O2 battery materials along with their GHG emissions. We use LCA methodology to estimate GHG emissions for five proposed lithium-O2 battery designs: (i) without catalyst, (ii) with catalyst, (iii) carbon-less and binder-less, (iv) anode protection, and (v) carbon-less, binder-less with gold catalyst. This work highlights knowledge gaps in lithium-O2 battery LCA, provides a benchmark to quantify battery composition impacts, and demonstrates the GHG emissions associated with certain materials and designs for laboratory-scale batteries. Predicted GHG emissions range from 10–70 kg of CO2 equivalent (kg CO2𝑒) kg−1 of battery, 60–1200 kg CO2𝑒 kWh−1, and 0.15–21 kg CO2𝑒 per km of vehicle travel, if battery replacement is considered. 

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2. Applying life cycle analysis for materials selection in Li-O2 batteries

   https://doi.org/10.1557/s43580-023-00610-5  

   Chen-Glasser, Melodie; Landis, Amy E.; DeCaluwe, Steven C. (July 2023, MRS Advances)

   AbstractGreenhouse gas emission reduction is often cited as a reason for high energy density, next-generation battery development. As lithium-O₂battery research has progressed, researchers have examined the potential of many novel materials in the drive to reduce parasitic reactions and increase capacity. While the field has made great strides towards producing more reliable batteries, there has been little verification that lithium-O₂batteries will reduce net environmental impacts. This paper examines how material selection ultimately impacts lithium-O₂battery environmental impacts. Given that researchers should not wait until lithium-O₂batteries reach commercialization to assess their environmental impact, this paper describes how to incorporate LCA as an integral part of the battery design process. Furthermore, it provides impact factors of many relevant materials to increase the ease of LCA for the field. <bold>Graphic abstract</bold> 

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3. Recent Progress of Anode Protection in Li–S Batteries

   https://doi.org/10.1002/ente.202200944  

   Al Khazraji, Mohammed Radha; Wang, Jianda; Wei, Shuya (November 2022, Energy Technology)

   Lithium‐ion batteries have gradually reached their theoretical limits. To meet the growing demand for higher energy storage technology, finding alternative battery chemistries has become the major concern. Fortunately, lithium–sulfur batteries are considered the most promising next‐generation energy storage technology due to being cost‐effective and having high theoretical energy density. However, the further commercialization of lithium–sulfur batteries is hindered due to the growth of lithium dendrites and the shuttle effect of soluble lithium polysulfides. This review provides an overview of the challenges facing lithium–sulfur batteries. Furthermore, a comprehensive overview of lithium metal protection strategies is provided including electrolyte optimization, construction of artificial solid electrolyte layers, utilization of hosting materials, and design of separators, as well as a theoretical understanding and analysis of the underlying methods. This review puts forward general conclusions and prospects for the practical application of lithium–sulfur batteries in the future and the promotion of technology development of lithium metal batteries. 

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4. Extending Battery Life via Load SExtending Battery Life via Load Sharing in Electric Aircraft

   https://doi.org/10.2514/6.2024-2154  

   Anthony, George; Peskar, Jarrett; Downey, Austin R.J.; Booth, Kristen (January 2024, AIAA SCITECH 2024 Forum)

   Electric Aircraft have the potential to revolutionize short-distance air travel with lower operating costs and simplified maintenance. However, due to the long lead-time associated with procuring batteries and the maintenance challenges of replacing and repairing batteries in electric aircraft, there are still unanswered questions related to the true long-term operating costs of electric aircraft. This research examines using a load-sharing system in electric aircraft to optimally tune battery degradation in a multi-battery system such that the battery life of a single battery is extended. The active optimization of energy drawn from multiple battery packs means that each battery pack reaches its optimal replacement point at the same time; thereby simplifying the maintenance procedure and reducing cost. This work uses lithium iron phosphate batteries experimentally characterized and simulated in OpenModelica for a flight load profile. Adaptive agents control the load on the battery according to factors such as state of charge, and state of health, to respond to potential faults. The findings in this work show the potential for adaptive agents to selectively draw more power from a healthy battery to extend the lifespan of a degraded battery such that the remaining useful life of both batteries reaches zero at the same time. Simulations show that dual battery replacement can be facilitated using the proposed method when the in-service battery has a remaining useful life of greater than 0.5; assuming that the replacement battery it is paired with has a remaining useful life of 1.0. Limitations of the proposed method are discussed within this work. 

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5. 3D Printing‐Enabled Design and Manufacturing Strategies for Batteries: A Review

   https://doi.org/10.1002/smll.202302718  

   Fonseca, Nathan; Thummalapalli, Sri Vaishnavi; Jambhulkar, Sayli; Ravichandran, Dharneedar; Zhu, Yuxiang; Patil, Dhanush; Thippanna, Varunkumar; Ramanathan, Arunachalam; Xu, Weiheng; Guo, Shenghan; et al (December 2023, Small)

   Abstract Lithium‐ion batteries (LIBs) have significantly impacted the daily lives, finding broad applications in various industries such as consumer electronics, electric vehicles, medical devices, aerospace, and power tools. However, they still face issues (i.e., safety due to dendrite propagation, manufacturing cost, random porosities, and basic & planar geometries) that hinder their widespread applications as the demand for LIBs rapidly increases in all sectors due to their high energy and power density values compared to other batteries. Additive manufacturing (AM) is a promising technique for creating precise and programmable structures in energy storage devices. This review first summarizes light, filament, powder, and jetting‐based 3D printing methods with the status on current trends and limitations for each AM technology. The paper also delves into 3D printing‐enabled electrodes (both anodes and cathodes) and solid‐state electrolytes for LIBs, emphasizing the current state‐of‐the‐art materials, manufacturing methods, and properties/performance. Additionally, the current challenges in the AM for electrochemical energy storage (EES) applications, including limited materials, low processing precision, codesign/comanufacturing concepts for complete battery printing, machine learning (ML)/artificial intelligence (AI) for processing optimization and data analysis, environmental risks, and the potential of 4D printing in advanced battery applications, are also presented. 

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