Environmental Impact Analysis of Acidification and Eutrophication Due to Emissions from the Production of Concrete

Kim, Tae Hyoung; Chae, Chang-U

doi:10.3390/su8060578

Cited by 69 publications

(33 citation statements)

References 15 publications

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“…Lastly, eutrophication is excessive nutrient enrichment, that can cause undesirable shifts in aquatic ecosystem. Production of building materials, such as concrete is one cause of eutrophication [20,21]. Table 1 summaries a broad range of data from published studies, categorized in terms of the building type, carbon emission, and energy attributed to LCECI and LCEEI (the functional unit is floor area).…”

Section: Embodied Environmental Impactmentioning

confidence: 99%

A Building Life-Cycle Embodied Performance Index—The Relationship between Embodied Energy, Embodied Carbon and Environmental Impact

2020

Energies

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Knowledge and research tying the environmental impact and embodied energy together is a largely unexplored area in the building industry. The aim of this study is to investigate the practicality of using the ratio between embodied energy and embodied carbon to measure the building’s impact. This study is based on life-cycle assessment and proposes a new measure: life-cycle embodied performance (LCEP), in order to evaluate building performance. In this project, eight buildings located in the same climate zone with similar construction types are studied to test the proposed method. For each case, the embodied energy intensities and embodied carbon coefficients are calculated, and four environmental impact categories are quantified. The following observations can be drawn from the findings: (a) the ozone depletion potential could be used as an indicator to predict the value of LCEP; (b) the use of embodied energy and embodied carbon independently from each other could lead to incomplete assessments; and (c) the exterior wall system is a common significant factor influencing embodied energy and embodied carbon. The results lead to several conclusions: firstly, the proposed LCEP ratio, between embodied energy and embodied carbon, can serve as a genuine indicator of embodied performance. Secondly, environmental impact categories are not dependent on embodied energy, nor embodied carbon. Rather, they are proportional to LCEP. Lastly, among the different building materials studied, metal and concrete express the highest contribution towards embodied energy and embodied carbon.

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Section: Embodied Environmental Impactmentioning

confidence: 99%

A Building Life-Cycle Embodied Performance Index—The Relationship between Embodied Energy, Embodied Carbon and Environmental Impact

2020

Energies

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“…This modelling framework assesses the environmental pressures and related potential environmental impacts associated with all the stages of a product's life cycle from cradle to grave. Environmental impact categories include climate change with global warming potential as the corresponding characterisation factor (Plevin et al 2013;Nakano 2015), acidification (Huijbregts et al 2000;Kim and Chae 2016), human toxicity (Hertwich et al 2001;Juraske et al 2009), water depletion (Pfister et al 2009;Finkbeiner et al 2010), resource depletion (Klinglmair et al 2014) etc.…”

Section: Introductionmentioning

confidence: 99%

Evaluation and selection of functional diversity metrics with recommendations for their use in life cycle assessments

Ahmed

Bodegom

Tukker

2018

Int J Life Cycle Assess

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Purpose In life cycle assessments (LCAs), the focus of modelling the impact of human-induced pressures on biodiversity has been mainly on taxonomic diversity measures such as species richness. More recently, increasing availability of trait data and the understanding that functional diversity is more directly related to human-induced pressures suggests functional diversity as a promising metric. One major challenge relates to the selection process of the correct metric. Our purpose is to categorise and identify appropriate metrics of functional diversity for LCA model developers based on a justified choice of its structural properties and its links to human-induced pressures. Methods We conducted a meta-analysis of literature to identify those functional diversity metrics that are frequently applied (not necessarily within LCA studies) and that possess a strong link to ecosystem functioning and human-induced pressures. Also, we provide a compilation of metrics that conform to important and desirable structural properties stipulated from literature. By reconciling these highlighted key properties with the strength of metric link, we make propositions for functional diversity use in LCA. Results and discussion To capture impacts on functional diversity, the combination of functional richness, evenness and divergence needs to be considered. The mean strength of functional diversity metrics was highest for temperature rise and CO 2 elevation, as related to climate change, and less to eutrophication and land use change. Studies on impacts of water use change and other important human-induced pressures on functional diversity seem not available. When combined with desired structural properties such as independence and scale invariance, a combination of functional dendrogram (FR D ), functional evenness (FE m ) and functional logarithmic variance (FD var ) is preferred to comprehensively determine human impacts on biodiversity in LCAs. However, if a set of multi-dimensional components is sought, then the best option is functional volume (FR V ), functional evenness (FE m ) and functional divergence (FD m ). Conclusions Through this reconciliation of usage, mean strength and key properties, the LCA model developer is able to apply consistent and useful metrics in LCA studies.

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“…Acidification exceeds 8% in scenarios that consider the use of gas. This is an environmental problem caused by acidified rivers/streams and soil due to anthropogenic air pollutants such as SO 2 , NH 3 , and NO x [49][50][51]. Therefore, the decrease in the impact of acidification reduces the mobilization and leaching behavior of heavy metals in soil and exerts adverse impacts on aquatic and terrestrial animals and plants by disturbing the food web.…”

Section: Resultsmentioning

confidence: 99%

Environmental Assessment of Energy Scenarios for a Low-Carbon Electrical Network in Chile

2019

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Nowadays, establishing clean energy sources is an undeniable need for all territories to reconcile energy and competitiveness objectives with those of security and sustainability. This article shows the main advantages of implementing clean energy sources in the long-term Chilean electrical network. The clean energy considered in this work is based on Renewable Energy (Conventional and Non-Conventional) with the backup of gas or nuclear. Thus, four scenarios are proposed and were simulated for the year 2050, the year assumed for the decommissioning of all coal plants in the country. These scenarios contemplate a high or low penetration of Renewable Energy. Additionally, a reference and realistic scenario for the year 2018 has also been considered to compare to the clean scenarios proposed. The results obtained coincide with the goals of reducing environmental impacts such as global warming emissions and fossil fuel dependence. However, the backup that was chosen for supporting the intermittence of renewable energy may have an important role in the main system considering the expected growth of energy demands in the near future.

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Environmental Impact Analysis of Acidification and Eutrophication Due to Emissions from the Production of Concrete

Cited by 69 publications

References 15 publications

A Building Life-Cycle Embodied Performance Index—The Relationship between Embodied Energy, Embodied Carbon and Environmental Impact

A Building Life-Cycle Embodied Performance Index—The Relationship between Embodied Energy, Embodied Carbon and Environmental Impact

Evaluation and selection of functional diversity metrics with recommendations for their use in life cycle assessments

Environmental Assessment of Energy Scenarios for a Low-Carbon Electrical Network in Chile

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