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Related Concept Videos

Design Example: Sustainability in Concrete Building01:26

Design Example: Sustainability in Concrete Building

229
As the construction industry moves towards more eco-friendly practices, concrete's adaptability and its ability to incorporate sustainable features make it a key material in the drive towards greener building solutions.
There are multiple approaches to achieve sustainability in a commercial concrete building. For instance, construct a concrete parking area under the building, utilizing pervious concrete paver blocks in open areas to facilitate rainwater collection through an underground...
229
Design Example: Joints in Concrete Pavements01:28

Design Example: Joints in Concrete Pavements

270
Concrete pavement joints are essential for maintaining the structural integrity and longevity of pavement by controlling where and how the pavement cracks. These joints can be categorized based on their functions, such as contraction or control joints, construction joints, isolation joints, and expansion joints.
Contraction joints are typically formed by sawing a groove into the concrete shortly after it has hardened. This creates a weakened vertical plane, deliberately encouraging cracking at...
270
Masonry Paving01:21

Masonry Paving

297
The construction of masonry paving involves using materials such as bricks, stones, and concrete masonry units. These materials are chosen for their shape, color, strength, and resistance to abrasion and weathering. Masonry units can be installed dry on a thin layer of sand and a gravel base, or they can be embedded in mortar or asphalt on a concrete slab. For areas subjected to heavy vehicular loads, a rigid base layer of reinforced or unreinforced concrete is recommended. In contrast,...
297
Design Example: Managing Concrete Workability01:14

Design Example: Managing Concrete Workability

123
This example deals with managing the workability of concrete for a raft foundation project under hot weather conditions. Workability is crucial for ensuring the concrete is easy to place, compact, and finish. In this scenario, a slump test — a common method to measure the workability of fresh concrete — initially indicated low workability. This was attributed to the rapid water loss from the concrete mix, exacerbated by the high temperatures causing the course aggregates to heat up.
123
Design Example: Aggregate Gradation01:24

Design Example: Aggregate Gradation

151
The right type and quality of aggregates are crucial for concrete as they significantly influence its properties, mix proportions, and cost-effectiveness. If different sources are available for sand, the commonly used fine aggregate in concrete, the selection of sand is primarily based on its gradation.
The grading, or particle-size distribution, of sand is determined using sieve analysis, with standard sizes ranging from 150 μm to 10 mm (ASTM No. 100 sieve to 3⁄8 in. sieve). Sand is...
151
Fatigue Strength of Concrete01:22

Fatigue Strength of Concrete

289
Fatigue, in the context of materials science and engineering, refers to the weakening or failure of a material caused by repeatedly applied loads, even if these loads are below the strength limit of the material. Fatigue strength in concrete is a critical property that influences its durability and longevity. Concrete can fail in two ways due to fatigue. Static fatigue or creep rupture occurs under a constant load or one that increases slowly. The other failure mode is due to cyclical or...
289

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Sustainable Pavement Materials: Design, Application, and Performance Evaluation.

Jiaqi Chen1

  • 1Department of Civil Engineering, Central South University, Changsha 410075, China.

Materials (Basel, Switzerland)
|June 27, 2025
PubMed
Summary
This summary is machine-generated.

Pavement sustainability balances environmental, economic, and social factors throughout a pavement's life. Material choice is crucial for durability, resource efficiency, safety, and maintenance.

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Area of Science:

  • Pavement engineering
  • Sustainable infrastructure development
  • Civil engineering

Background:

  • Pavement sustainability encompasses environmental, economic, and social aspects across the entire pavement lifecycle.
  • Material selection significantly impacts pavement durability, resource efficiency, safety, and maintenance requirements.

Discussion:

  • Integrating sustainability principles into pavement design and construction is essential for long-term infrastructure viability.
  • Life cycle assessment (LCA) provides a framework for evaluating the overall sustainability of pavement materials and strategies.

Key Insights:

  • Optimizing material selection enhances pavement durability and reduces the need for frequent maintenance.
  • Prioritizing resource efficiency in material sourcing and use minimizes environmental impact.
  • Considering social factors, such as safety and community impact, is integral to sustainable pavement development.

Outlook:

  • Future research should focus on innovative, sustainable materials and construction techniques.
  • Developing standardized methods for assessing pavement sustainability will facilitate wider adoption.
  • Policy and regulatory frameworks need to support the implementation of sustainable pavement practices.