Carbon Intensity and Sustainable Development Analysis of the Transportation Infrastructure Industry in China: An MLP Network Approach

Carbon Intensity and Sustainable Development Analysis of the Transportation Infrastructure Industry in China: An MLP Network Approach

Transportation infrastructure systems sit at the nexus of urban economic development and emission mitigation. The primary objective is to identify and quantify the key factors influencing CI, with a focus on both the conventional and emerging indicators through an innovative MLP neural network devel...

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Bibliographic Details
Main Authors: Guandong Liu, Haicheng Xu
Format: Article
Language:English
Published: MDPI AG 2025-06-01
Series:Urban Science
Subjects:
sustainable development
infrastructure decarbonization
MLP neural networks
urban policy integration
carbon intensity forecasting
Online Access:https://www.mdpi.com/2413-8851/9/6/205
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Summary:Transportation infrastructure systems sit at the nexus of urban economic development and emission mitigation. The primary objective is to identify and quantify the key factors influencing CI, with a focus on both the conventional and emerging indicators through an innovative MLP neural network developed using the data of 20 Chinese transportation enterprises that have a business focus on the construction and operation sector from 2018 to 2022. The hypothesis is that integrating unconventional indicators—such as business model entropy and green revenue share—alongside traditional metrics can significantly enhance the predictive accuracy for CI. The results show that business model entropy explains 42.6% of carbon intensity (Cl) variability through green revenue diversification pathways, while emissions trading system (ETS) exposure accounts for 51.83% of decarbonization outcomes via price-signaling effects. The analysis reveals that a critical operational threshold–renewable energy capacity below 75% fails to significantly reduce Cl, and capex/revenue ratios exceeding 73.58% indicate carbon lock-in risks. These findings enable policymakers to prioritize industries with sub-75% renewable adoption while targeting capex-intensive sectors for circular economy interventions. The novelty of this work lies in the application of advanced machine-learning techniques to a comprehensive, multi-source dataset, enabling a nuanced analysis of CI drivers and offering actionable insights for policymakers and industry stakeholders aiming to decarbonize transport infrastructure.
ISSN:2413-8851

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