Spatial change and scale dependence of built-up land expansion and landscape pattern evolution—Case study of affected area of the lower Yellow River

•Infilling is the current dominant mode of built-up land expansion.•Built-up land expansion will increase the fragmentation and complexity of landscape pattern.•Homogeneity and heterogeneity in the relationships between built-up land expansion and landscape patterns were subject to the coupled influ...

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Published inEcological indicators Vol. 141; p. 109123
Main Authors Yang, Dan, Zhang, Pengyan, Jiang, Ling, Zhang, Ying, Liu, Zhenyue, Rong, Tianqi
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.08.2022
Elsevier
Subjects
Built-up land expansion
habitat fragmentation
land use change
Landscape pattern evolution
landscapes
Multiscale Geographically Weighted Regression (MGWR)
rivers
social welfare
Spatial change
sustainable development
The affected area of the Lower Yellow River
urban development
Yellow River
Yellow River
Landscape pattern evolution
Spatial change
Built-up land expansion
The affected area of the Lower Yellow River
Multiscale Geographically Weighted Regression (MGWR)
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Abstract •Infilling is the current dominant mode of built-up land expansion.•Built-up land expansion will increase the fragmentation and complexity of landscape pattern.•Homogeneity and heterogeneity in the relationships between built-up land expansion and landscape patterns were subject to the coupled influences of the three scale effects.•Development differentiated policies at different scales contributes to the stability of landscape patterns in the basin. Land use change are essential for sustaining human wellbeing, but empirical studies have shown that the urban development requires built-up land, yet, the disorderly expansion of built-up land poses a threat to sustaining the stability of landscape patterns. Reconciling these seemingly conflicting results requires better understanding how the built-up land expansion and the landscape patterns change relationship varies with space and scales. Here we systematically analyzed the landscape pattern and expansion mode of built-up land in the affected area of the Lower Yellow River on three spatial scales (i.e., 5 km, 10 km, 15 km), using landscape pattern analysis, the landscape expansion index and the Multiscale Geographically Weighted Regression (MGWR) model. Our results indicated that: (1) infilling has been the dominant mode of built-up land expansion, and the spreading tendency become more obvious with a decrease in scale; (2) Rapid expansion of built-up land had led to the significant spatial differences in landscape fragmentation and agglomeration at different scales and the complexity of the landscape shape gradually increased; (3) the MGWR model can explain the relationship between the built-up land expansion and landscape pattern more than the Ordinary Least Squares model (OLS), and shows that the dependence of the two is increasing with the increase of scale, Further, the effect of control variables on the landscape pattern evolution differed. This study provides a valuable reference for sustainable development in other large river basins experiencing similar ecological landscape pattern changes (landscape elements, spatial locations and connections that are critical to the health and security of ecological processes).
AbstractList •Infilling is the current dominant mode of built-up land expansion.•Built-up land expansion will increase the fragmentation and complexity of landscape pattern.•Homogeneity and heterogeneity in the relationships between built-up land expansion and landscape patterns were subject to the coupled influences of the three scale effects.•Development differentiated policies at different scales contributes to the stability of landscape patterns in the basin. Land use change are essential for sustaining human wellbeing, but empirical studies have shown that the urban development requires built-up land, yet, the disorderly expansion of built-up land poses a threat to sustaining the stability of landscape patterns. Reconciling these seemingly conflicting results requires better understanding how the built-up land expansion and the landscape patterns change relationship varies with space and scales. Here we systematically analyzed the landscape pattern and expansion mode of built-up land in the affected area of the Lower Yellow River on three spatial scales (i.e., 5 km, 10 km, 15 km), using landscape pattern analysis, the landscape expansion index and the Multiscale Geographically Weighted Regression (MGWR) model. Our results indicated that: (1) infilling has been the dominant mode of built-up land expansion, and the spreading tendency become more obvious with a decrease in scale; (2) Rapid expansion of built-up land had led to the significant spatial differences in landscape fragmentation and agglomeration at different scales and the complexity of the landscape shape gradually increased; (3) the MGWR model can explain the relationship between the built-up land expansion and landscape pattern more than the Ordinary Least Squares model (OLS), and shows that the dependence of the two is increasing with the increase of scale, Further, the effect of control variables on the landscape pattern evolution differed. This study provides a valuable reference for sustainable development in other large river basins experiencing similar ecological landscape pattern changes (landscape elements, spatial locations and connections that are critical to the health and security of ecological processes).
Land use change are essential for sustaining human wellbeing, but empirical studies have shown that the urban development requires built-up land, yet, the disorderly expansion of built-up land poses a threat to sustaining the stability of landscape patterns. Reconciling these seemingly conflicting results requires better understanding how the built-up land expansion and the landscape patterns change relationship varies with space and scales. Here we systematically analyzed the landscape pattern and expansion mode of built-up land in the affected area of the Lower Yellow River on three spatial scales (i.e., 5 km, 10 km, 15 km), using landscape pattern analysis, the landscape expansion index and the Multiscale Geographically Weighted Regression (MGWR) model. Our results indicated that: (1) infilling has been the dominant mode of built-up land expansion, and the spreading tendency become more obvious with a decrease in scale; (2) Rapid expansion of built-up land had led to the significant spatial differences in landscape fragmentation and agglomeration at different scales and the complexity of the landscape shape gradually increased; (3) the MGWR model can explain the relationship between the built-up land expansion and landscape pattern more than the Ordinary Least Squares model (OLS), and shows that the dependence of the two is increasing with the increase of scale, Further, the effect of control variables on the landscape pattern evolution differed. This study provides a valuable reference for sustainable development in other large river basins experiencing similar ecological landscape pattern changes (landscape elements, spatial locations and connections that are critical to the health and security of ecological processes).
Land use change are essential for sustaining human wellbeing, but empirical studies have shown that the urban development requires built-up land, yet, the disorderly expansion of built-up land poses a threat to sustaining the stability of landscape patterns. Reconciling these seemingly conflicting results requires better understanding how the built-up land expansion and the landscape patterns change relationship varies with space and scales. Here we systematically analyzed the landscape pattern and expansion mode of built-up land in the affected area of the Lower Yellow River on three spatial scales (i.e., 5 km, 10 km, 15 km), using landscape pattern analysis, the landscape expansion index and the Multiscale Geographically Weighted Regression (MGWR) model. Our results indicated that: (1) infilling has been the dominant mode of built-up land expansion, and the spreading tendency become more obvious with a decrease in scale; (2) Rapid expansion of built-up land had led to the significant spatial differences in landscape fragmentation and agglomeration at different scales and the complexity of the landscape shape gradually increased; (3) the MGWR model can explain the relationship between the built-up land expansion and landscape pattern more than the Ordinary Least Squares model (OLS), and shows that the dependence of the two is increasing with the increase of scale, Further, the effect of control variables on the landscape pattern evolution differed. This study provides a valuable reference for sustainable development in other large river basins experiencing similar ecological landscape pattern changes (landscape elements, spatial locations and connections that are critical to the health and security of ecological processes).
ArticleNumber 109123
Author Zhang, Ying
Liu, Zhenyue
Rong, Tianqi
Yang, Dan
Jiang, Ling
Zhang, Pengyan
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  givenname: Ling
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  givenname: Ying
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  organization: College of Geography and Environmental Science, Henan University, Kaifeng 475004, China
– sequence: 5
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  surname: Rong
  fullname: Rong, Tianqi
  organization: College of Geography and Environmental Science, Henan University, Kaifeng 475004, China
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Keywords Landscape pattern evolution
Spatial change
Built-up land expansion
The affected area of the Lower Yellow River
Multiscale Geographically Weighted Regression (MGWR)
Language English
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Snippet •Infilling is the current dominant mode of built-up land expansion.•Built-up land expansion will increase the fragmentation and complexity of landscape...
Land use change are essential for sustaining human wellbeing, but empirical studies have shown that the urban development requires built-up land, yet, the...
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SubjectTerms Built-up land expansion
habitat fragmentation
land use change
Landscape pattern evolution
landscapes
Multiscale Geographically Weighted Regression (MGWR)
rivers
social welfare
Spatial change
sustainable development
The affected area of the Lower Yellow River
urban development
Yellow River
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Title Spatial change and scale dependence of built-up land expansion and landscape pattern evolution—Case study of affected area of the lower Yellow River
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