Material Consumption and Carbon Emissions Associated with the Infrastructure Construction of 34 Cities in Northeast China

Wang, Heming; Wang, Yao; Fan, Cong; Wang, Xinzhe; Wei, Yuan; Zhang, Zhihe; Wang, Jiashi; Ma, Fengmei; Yue, Qiang

doi:10.1155/2020/4364912

Cited by 4 publications

(5 citation statements)

References 67 publications

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“…Promoting sustainable materials, eco‐friendly construction methods, and efficient land use can help decouple urban growth from environmental harm. For instance, using low energy‐intensive construction materials such as “green steel” could help significantly reduce buildings’ emissions (Muslemani et al., 2021; Wang et al., 2020).…”

Section: Discussionmentioning

confidence: 99%

“…Recent studies have categorized methodologies for analyzing material stocks and flows in buildings and infrastructures -see reviews by Augiseau and Barles (2017), Lanau et al (2019), Müller et al (2014), Tanikawa et al (2015), and Wang et al (2020). This study adopted the methodological classification introduced by Lanau et al (2019), which in addition to top-down and bottom-up approaches, includes a remote-sensing-based method and a hybrid approach.…”

Section: Building Materials Stock Modelingmentioning

confidence: 99%

“…(2015), and Wang et al. (2020). This study adopted the methodological classification introduced by Lanau et al.…”

Section: Introductionmentioning

confidence: 97%

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City‐scale assessment of the material and environmental footprint of buildings using an advanced building information model: A case study from Canberra, Australia

Soonsawad,

Marcos‐Martinez,

Schandl

2024

J of Industrial Ecology

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As cities grow, demand for urban materials is set to rise. Meeting sustainability targets will require transformative changes to how cities are constructed. Yet, accurate information on embodied building materials and their environmental impacts at the city scale is still lacking. We use Light Detection and Ranging data, building archetype information, and statistical models to estimate the embodied materials in buildings in Canberra, Australia, and their energy, carbon, and water footprint. In 2015, 57 million tonnes (Mt) of materials were embodied in 140,805 buildings. By weight, concrete was the most used material (44%), followed by sand and stone (32%), and ceramics (11%). Current population growth and building construction trends indicate a need for 2.4 times the building materials stock of 2015 by 2060. Producing such materials would require 1.6 thousand TJ of energy and 793 thousand megaliters of water and emit 48 Mt of CO2e—an environmental footprint 1.6 times the one in 2015. If the additional population were to live only in new single houses, material demand would be 4% higher than under current trends and the environmental footprint 5% higher. Housing new residents in low‐rise apartments would reduce from current trends the material demand by 5% and the environmental footprint by 12%. Using only apartments of four or more stories would reduce material demand by 28% and the environmental footprint by 14%. This research can inform circular economy efforts to improve building materials management by helping estimate the implications of alternative configurations of the urban built environment.

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Section: Discussionmentioning

confidence: 99%

Section: Building Materials Stock Modelingmentioning

confidence: 99%

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City‐scale assessment of the material and environmental footprint of buildings using an advanced building information model: A case study from Canberra, Australia

Soonsawad,

Marcos‐Martinez,

Schandl

2024

J of Industrial Ecology

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show abstract

“…(Huang et al 2019) revealed the relationship with economic growth through decoupling analysis by quantifying the embodied greenhouse gas emissions of building materials. (Wang et al 2020) calculates the material consumption and corresponding carbon emissions of infrastructure to explores the decoupling relationship. Even though few studies have analyzed the relationship between the two, the driving factors behind the relationship have not been discussed in depth.…”

Section: Introductionmentioning

confidence: 99%

Embodied carbon emission of building materials in Southwest China: Analysis based on Tapio decoupling and LMDI decomposition

Wang

Cheng

et al. 2022

Preprint

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With the rapid development of urbanization, many housing constructions are being built in southwest China, which resulted in tremendous use of building materials, posing a potential threat to the environment. In order to formulate policies for low-carbon, green and sustainable development of buildings, it is necessary to explore the driving factors behind it. Taking the bottom-up material flow analysis as a framework, this research calculates the embodied carbon emissions of buildings on the basis of quantifying the stock of building materials in Southwest China from 2001 to 2020 and adopts the Logarithmic mean Divisia Index (LMDI) decomposition analysis method to investigate the contribution of factors such as technological level, economic structure, per capita GDP and population density to the embodied carbon emissions of buildings. The research shows that: (1) The total embodied carbon emissions of building materials in Southwest China increased by 218.62%, of steel and cement contributed the most of carbon emissions. (2) In the past 20 years, the degree of decoupling in Southwest China has fluctuated greatly. During the "13th Five-Year Plan" period, the provinces and cities in southwest China have an enormous degree of decoupling: Yunnan (-0.141) > Guizhou (-0.013) > Chongqing (0.047) > Tibet (0.120) > Sichuan (0.256). (3) The technological level is the first leading factor in the reduction of the embodied carbon emissions of buildings in southwest China, and the per capita GDP is the key factor to promote the growth of embodied carbon emissions. These findings could serve as a foundation for Southwest China's government to develop low-carbon building policies.

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“…e outcome was that total infrastructure building delivery in the selected towns was not leveled. us, infrastructure building supply remained steady along with economic growth [22]. Cao et al carried out an experiment and numerical study on snowdrift on a typical large-span retractable roof utilizing the Euler-Euler technique.…”

Section: Introductionmentioning

confidence: 99%

Numerical Simulation and Computational Flow Characterization Analyses of Centrifugal Pump Operating as Turbine

Chang

Adu

et al. 2021

Complexity

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Using a pump in reverse mode as a hydraulic turbine remains an alternative for hydropower generation in meeting energy needs, especially for the provision of electricity to remote and rural settlements. The primary challenge with small hydroelectric systems is attributed to the high price of smaller size hydraulic turbines. A specific commercial pump model, with a flow rate of 12.5 m3/h, head 32 m, pressure side diameter of 50 mm, impeller out, and inlet diameters of 160 mm and 6 mm, respectively, was chosen for this research. This research aimed to investigate a pump’s flow characteristics as a turbine to help select a suitable pump to be used as a turbine for micro- or small hydropower construction. Numerical methodologies have been adopted to contribute to the thoughtful knowledge of pressure and velocity distribution in the pump turbine performance. In this study, the unsteady flow relations amongst the rotating impeller and stationary volute of the centrifugal pump made up four blades and four splitters. Intermittent simulation results of pressure and velocity flow characteristics were studied considering diverse impeller suction angles. The study was conducted by considering a wide range of rotational speeds starting from 750 rpm to 3250 rpm. From the results, it was found that PAT operation was improved when operated at low speeds compared to high-speed operation. Thus, speeds between 1500 rpm and 2000 rpm were suitable for PAT performance. This research helps to realize the unsteady flow physiognomies, which provide information for future research on PAT. This study makes useful facts available which could be helpful for the pump turbine development. Future studies should focus on cost analysis and emission generation in energy generation.

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Material Consumption and Carbon Emissions Associated with the Infrastructure Construction of 34 Cities in Northeast China

Cited by 4 publications

References 67 publications

City‐scale assessment of the material and environmental footprint of buildings using an advanced building information model: A case study from Canberra, Australia

City‐scale assessment of the material and environmental footprint of buildings using an advanced building information model: A case study from Canberra, Australia

Embodied carbon emission of building materials in Southwest China: Analysis based on Tapio decoupling and LMDI decomposition

Numerical Simulation and Computational Flow Characterization Analyses of Centrifugal Pump Operating as Turbine

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