Low-Carbon Design Strategies for Science & Technology Industrial Parks Using Solar Energy and Heat Island Analysis

 

1. Introduction

This research introduces a comprehensive low-carbon design framework for block-scale science and technology industrial parks by integrating solar energy utilization potential with urban heat island effect analysis. The study highlights the growing need for climate-responsive industrial development as urbanization accelerates and carbon reduction targets become more stringent. By focusing on renewable energy integration and thermal environment optimization, the research establishes a scientific foundation for sustainable industrial park planning and contributes to the advancement of low-carbon urban research.

2. Solar Energy Utilization Potential in Industrial Park Design

This topic examines the assessment of solar radiation, rooftop availability, and spatial configuration to maximize photovoltaic integration within industrial parks. The research demonstrates how solar energy potential mapping supports low-carbon energy planning, reduces dependency on fossil fuels, and enhances on-site renewable power generation. It provides valuable insights for researchers exploring renewable energy-driven industrial infrastructure.

3. Urban Heat Island Effects at the Block Scale

This section analyzes the formation and intensity of urban heat islands within science and technology industrial parks, focusing on building density, surface materials, and land-use patterns. The research highlights the importance of microclimate analysis in reducing thermal stress, improving outdoor comfort, and lowering cooling energy demand through evidence-based urban design strategies.

4. Low-Carbon Spatial Planning and Building Configuration

This topic explores how block-scale layout optimization, building orientation, and functional zoning contribute to reduced carbon emissions. The research emphasizes passive design strategies that enhance natural ventilation, daylight access, and energy efficiency, offering a replicable model for sustainable industrial park development.

5. Integration of Renewable Energy and Climate-Responsive Design

This section discusses the synergy between solar energy systems and heat island mitigation measures such as green roofs, reflective materials, and vegetation. The research demonstrates how integrated design approaches improve overall environmental performance while supporting long-term sustainability goals in science and technology industrial zones.

6. Policy Implications and Future Research Directions

The final topic outlines the policy relevance of low-carbon industrial park design and identifies future research opportunities in energy modeling, smart grid integration, and climate-adaptive urban systems. It underscores the importance of interdisciplinary research and data-driven planning to support global low-carbon transition strategies.

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