How Spatial Analysis Can Help Enhance Material Stocks and Flows Analysis?

Liu, Yupeng; Chen, Weiqiang; Lin, Tao; Gao, Lijie

doi:10.3390/resources8010046

Cited by 8 publications

(3 citation statements)

References 42 publications

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“…Specifically, information on the in-use material stock of wind turbines could provide valuable insights into resource utilization efficiency 15 , encompassing material extraction 16 , usage 17 , and offer projections for future scenarios of wind turbine growth and endof-life management 18 . Furthermore, high-resolution and up-to-date monitoring of material stocks embedded within offshore wind turbines carries significant implications for route planning 19 and recycling potential evaluation 20 during the decommissioning phase of the wind turbine. Yet traditional approaches for assessing offshore wind turbines' in-use stocks are generally time-consuming and incomplete, which results in a low spatial resolution and may be outdated due to the rapid growth of offshore wind turbines 21 .…”

Section: Introductionmentioning

confidence: 99%

Weighing China's Fast Deployment of Offshore Wind Turbines through Satellite Images

Wang,

Li,

et al. 2024

Preprint

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Offshore wind turbines are being deployed at an unprecedented scale, mainly driven by China, to combat the global climate crisis. However, these wind turbines are highly material-intensive, which has aroused wide concerns on potential supply risks and end-of-life material decommissioning and management. Here, we develop an integrated Energy Infrastructure-Material Stock monitoring approach of offshore wind turbines (EIMS_owt) using satellite images to quantify the in-use stock of components (rotor, nacelle, tower, and cable) and materials (bulk metals, rare earth, and others) for each turbine unit in China. We captured the installment and operational data of nearly all existing offshore wind turbines and witnessed a 22-fold increase from 267 turbines in 2015 to 5921 turbines by 2022. Meanwhile, we find that over two-thirds of those turbines, associated with 4.5 million tons (Mt) of critical components such as rotors and nacelles in 2022, are located at offshore distance exceeding 20 kilometers, posing large challenges for their operation and waste management. It is estimated that around 3.5 Mt of steel, 157 kilotons (kt) of copper, 41 kt of aluminum, and 2.3 kt of rare earth are contained in those components, highlighting the prospective value of their future recycling. Accordingly, our approach provides a high-resolution and up-to-date monitoring solution to help both China and other countries in improving sustainable performance of their wind energy infrastructure.

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Section: Introductionmentioning

confidence: 99%

Weighing China's Fast Deployment of Offshore Wind Turbines through Satellite Images

Wang,

Li,

et al. 2024

Preprint

Self Cite

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“…Indeed, recognizing the importance of these interlinkages between resources, externalities, and the territory with the economic process, it is advisable to use the conceptual water-energy-food (WEF) nexus to address inter-related issues at different scales and dimensions in order to perform a quantitative analysis of sustainability with a different approach [6][7][8]. In this sense, natural infrastructure (soil, aquatic, and terrestrial ecosystems, atmosphere as ecological resources) or ecological funds (EFs) have been recognized as key components for achieving the 2030 Sustainable Development Goals (SDGs).…”

Section: Introductionmentioning

confidence: 99%

“…For instance, Dai et al [29] reported 70 tools and methods that can be used to assess the water-energy (WE) nexus at multiple levels, which includes the performance of a life cycle assessment (LCA) through their standards-ISO-14040, 2006 and ISO-14044, 2006-and other emerging approaches like the multi-scale integrated assessment of society and ecosystem metabolism (MuSIASEM) [8,11,30].…”

Section: Introductionmentioning

confidence: 99%

An Integrated Approach to Determining the Capacity of Ecosystems to Supply Ecosystem Services into Life Cycle Assessment for a Carbon Capture System

Morales-Mora¹,

Bravo²,

Baril³

et al. 2020

Applied Sciences

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In the life cycle assessment (LCA) method, it is not possible to carry out an integrated sustainability analysis because the quantification of the biophysical capacity of the ecosystems to supply ecosystem services is not taken into account. This paper considers a methodological proposal connecting the flow demand of a process or system product from the technosphere and the feasibility of the ecosystem to supply based on the sink capacity. The ecosystem metabolism as an analytical framework and data from a case study of an LCA of combined heat and power (CHP) plant with and without post-combustion carbon capture (PCC) technology in Mexico were applied. Three scenarios, including water and energy depletion and climate change impact, are presented to show the types of results obtained when the process effect of operation is scaled to one year. The impact of the water–energy–carbon nexus over the natural infrastructure or ecological fund in LCA is analyzed. Further, the feasibility of the biomass energy with carbon capture and storage (BECCS) from this result for Mexico is discussed. On the supply side, in the three different scenarios, the CHP plant requires between 323.4 and 516 ha to supply the required oil as stock flow and 46–134 ha to supply the required freshwater. On the sink side, 52–5,096,511 ha is necessary to sequester the total CO2 emissions. Overall, the CHP plant generates 1.9–28.8 MW/ha of electricity to fulfill its function. The CHP with PCC is the option with fewer ecosystem services required.

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How robust is the circular economy in Europe? An ascendency analysis with Eurostat data between 2010 and 2018

Zisopoulos

Schraven

Jong

2022

Resources, Conservation and Recycling

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How Spatial Analysis Can Help Enhance Material Stocks and Flows Analysis?

Cited by 8 publications

References 42 publications

Weighing China's Fast Deployment of Offshore Wind Turbines through Satellite Images

Weighing China's Fast Deployment of Offshore Wind Turbines through Satellite Images

An Integrated Approach to Determining the Capacity of Ecosystems to Supply Ecosystem Services into Life Cycle Assessment for a Carbon Capture System

How robust is the circular economy in Europe? An ascendency analysis with Eurostat data between 2010 and 2018

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