Environmental life cycle assessment of recycling technologies for
Life Cycle Assessment (LCA) is a systemic tool for evaluating the environmental impact related to goods and services. It includes technical surveys of all product life cycle
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Life Cycle Assessment (LCA) is a systemic tool for evaluating the environmental impact related to goods and services. It includes technical surveys of all product life cycle
The main results show that: (1) China''s titanium ore is large in volume but low in grade, ore reserves are closely related with the primary origins, while the secondary origins are
select article Urbanization-led land cover change impacts terrestrial carbon storage capacity: A high-resolution remote sensing-based nation-wide assessment in Pakistan (1990–2020)
The economic finding revealed that titanium oxide coated surface could save approximately 4178.175 USD/MW/year, whereas environmental benefit evaluation illustrated
Electric mobility has proven to be essential for the carbon neutrality of the transport sector. However, several studies have demonstrated the environmental costs linked to the supply of
assessment of the environmental impact due to flow battery pro-duction has been undertaken (L''Abbate et al., 2019; Weber et al., 2018). Thus, environmental benefit associated with only
Life cycle assessment is a widely used tool to quantify the potential environmental effects of battery production, usage, and disposal/recycling. This framework for
Gibson compared the environmental performance of components made of carbon fiber-thermoplastic composites, synthetic graphite, titanium and graphite-coated
Erratum: Life cycle environmental assessment of lithium-ion and nickel metal hydride batteries for plug-in hybrid and battery electric vehicles (Environmental Science &
Towards environmentally sustainable battery anode materials: Life cycle assessment of mixed niobium oxide (XNO™) and lithium‑titanium-oxide (LTO)
A Ca-metal battery with lithium titanate cathode delivered an initial capacity of about 170 mAh g −1 at 35 mA g −1, of which 80% was retained after 200 cycles. Ca 0.4 MnO 2
A life cycle assessment aims to assess the quantifiable environmental impacts of a battery, from the mining of its constituent materials required to the treatment of these
This study quantified the full life cycle environmental performance of LABs (lead-antimony-cadmium, Pb–Sb–Cd, and lead-tin-calcium, Pb–Sn–Ca) and LIBs (lithium-nickel-cobalt-manganese, NCM
The production of titanium dioxide in China generates substantial waste acid and ferrous sulfate, which are repurposed into polyferric sulfate for industrial wastewater
Demand for batteries is expected to surpass 3.2 TWh over the next decade with the potential surge in electric vehicle (EV) batteries .To accommodate this growth, cost
In contrast, the titanium present within LTO cannot be recovered by the recycling process. Nevertheless, the life cycle assessment (LCA) of the process demonstrated clear benefits of
This study presents a comprehensive life cycle assessment (LCA) of calcium-based polymer electrolytes, aiming to advance sustainable solid-state post-lithium battery technologies.
Similarly, Todorut et al., (2020) revealed that the emission of CO2 of electric buses (109465 Q electric CO2) was 2.605 times lower than that of diesel buses (285235 Q
Solid-state lithium metal batteries show substantial promise for overcoming theoretical limitations of Li-ion batteries to enable gravimetric and volumetric energy densities
When it comes to the future of solar energy cells, say farewell to silicon, and hello to calcium titanium oxide – the compound mineral better known as perovskite. Perovskite
Calcium (Ca) metal batteries, due to the high crustal abundance and potential for dendrite-free cycling of Ca, are promising alternatives to current lithium batteries. Ca
Semantic Scholar extracted view of "Environmental assessment and conductivity performance of calcium-based polymer electrolytes for the next generation of solid-state
Solid-state batteries (SSBs) have emerged as a promising alternative to conventional lithium-ion batteries, with notable advantages in safety, energy density, and
TDMA recently completed its third Life Cycle Assessment (LCA). From 2012 to 2021 TDMA Members achieved improvement in site emissions to both air and water and an estimated 19% decrease in “climate change impact,” a metric
Nonetheless, life cycle assessment (LCA) is a powerful tool to inform the development of better-performing batteries with reduced environmental burden. This review
Currently, the large-scale implementation of advanced battery technologies is in its early stages, with most related research focusing only on material and battery performance
Life cycle assessment (LCA) is a mature and well-recognized tool to evaluate the environmental burden as well as the benefits of a product (Klöpffer, 1997) or a process
A total of 11 mid-point environmental impact assessment categories was calculated by the CML-IA baseline V3.09/EU25 method, and six environmental impact
For relatively mature battery technologies, such as lead-acid, nickel-metal hydride, and certain variations of lithium-ion batteries, a robust life cycle assessment (LCA)
Battery mineral production causes impacts on the environment and human health, which may increase the probability of supply restrictions imposed by exporting countries. As
The NaNMMT battery contains components of nickel, the element that especially leads to a higher increment in carbon emissions, manganese, and titanium.
In 2012, Graedel and colleagues introduced a framework for criticality assessment (Graedel et al., 2012), which encompassed supply risk, environmental implications, and
lithium-ion and sodium-sulphur, show favourable performance for use in PV-battery systems, resulting in higher energy return factors and higher overall battery efficiencies than for
Life cycle inventory of Li-ion battery (Ecoinvent 3.0: Battery, Li-ion, rechargeable, prismatic {GLO}| production). * shows which system is further expanded for the life cycle inventory-these
The results showed that the use of recycled materials in battery manufacturing would reduce environmental damage (Dai et al., 2019). calculated the total energy use,
This paper investigates, into a comprehensive exploration, the environmental implications of solid-state calcium electrolytes based on a cross-linked polymer and three
This study evaluates the environmental impact of high-efficiency lithium-oxygen batteries cathodes, including titanium oxide composites, graphene-based composites and
Battery cycle life was found to be a major factor in comparing sodium-ion battery environmental impacts versus lithium-ion batteries: a drop to a cycle life of 1000 caused
Nonetheless, life cycle assessment (LCA) is a powerful tool to inform the development of better-performing batteries with reduced environmental burden. This review explores common practices in lithium-ion battery LCAs and makes recommendations for how future studies can be more interpretable, representative, and impactful.
As the largest battery producer, assessing the environmental impacts of China's battery-related minerals and technologies is crucial. However, studies that address the integrated issues of supply risks, vulnerability, and environmental impacts are relatively scarce for China.
Battery mineral production causes impacts on the environment and human health, which may increase the probability of supply restrictions imposed by exporting countries. As the largest battery producer, assessing the environmental impacts of China's battery-related minerals and technologies is crucial.
In the context of batteries, LCA results can be used to inform battery research and development (R&D) efforts aimed at reducing adverse environmental impacts, [28 – 30] compare competing battery technology options for a particular use case, [31 – 39] or estimate the environmental implications of large-scale adoption in grid or vehicle applications.
Fig. 1. Lithium production and prices. Life cycle assessment (LCA) is a standardized method and a powerful tool for quantifying a product's or service's total environmental impacts from “cradle to grave” (Kahn et al., 2022).
Abstract Rechargeable batteries are necessary for the decarbonization of the energy systems, but life-cycle environmental impact assessments have not achieved consensus on the environmental impacts...