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Characterization, Applications and New Technologies of Civil Engineering Materials and Structures
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With the continuous development of large-scale maintenance of infrastructure, accurate, reasonable, and efficient mechanical behavior evaluation and performance prediction of civil materials and structures have become the keys to improving service durability and intelligent maintenance management for infrastructure. The multi-component composition, multi-scale characteristics, and multi-field dependence of civil materials lead to extremely complex mechanical behaviors. The phenomenological method based on empirical tests is an important means to understand and evaluate civil materials, but its low efficiency and high consumption cannot meet the design and application requirements of civil materials. Numerical simulation has gradually become an important tool to study and understand the mechanical behavior of civil materials and structures, including the finite element method, discrete element method, molecular dynamics simulation, etc. In addition, the rapid development of numerical simulations has greatly promoted the modeling and simulation of civil materials. Considering the above, the aim of this Special Issue is to bring together cutting-edge research and application. To share, present, and discuss innovative materials, structures, and characterization methods may help us further develop the technology used in civil engineering.
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Keywords
- alkali-activated binder
- applications
- asphalt mixture
- asphalt–aggregate interface
- basalt fiber
- bitumen binder
- closure temperature
- compressive performance improvement
- compressive strength
- controlled low-strength materials (CLSM)
- crumb rubber
- digital image correlation
- discharge flow
- drainage piles
- dry–wet cycles
- dynamic modulus
- epoxidized soybean oil
- excess pore pressure
- failure mechanism
- failure morphology
- fatigue properties
- fiber content
- fiber dosage
- finite element simulation
- flexural performance
- flocculent lignin fiber
- flowability
- foam stability
- foamed lightweight soil
- foamed lightweight soils
- fracture energy
- geotextiles
- goaf treatment
- granular lignin fiber
- grey correlation analysis
- grouting material
- grouting steel-pipe
- healing potential of asphalt mixture
- hydrated lime
- hydration heat effect
- industrial solid waste
- infinitesimal mechanism
- initial prestress forces
- instability region
- liquefiable soils
- literature review
- Low temperature
- magnesium potassium phosphate cement (MKPC)
- Materials design
- mechanical performance
- Mechanical properties
- modification mechanism
- moisture and aging
- moisture content
- monotonic tensile tests
- n/a
- numerical modeling
- parametric resonance
- Performance
- Performance Evaluation
- polyester fiber
- polyphosphoric acid
- pore structure
- pretreatment method
- recycled aggregate
- recycled asphalt
- regression model
- reinforcement mechanism
- response surface methodology
- rheological properties
- self-healing level
- self-healing performance
- SEM
- shake table tests
- shear strength
- silty mudstone
- steel box arch bridge
- steel slag powder
- storage stability
- strain-controlled direct tensile fatigue tests
- strength change
- styrene butadiene rubber-modified asphalt
- sulfate attack
- sunshine temperature effect
- tensegrity structures
- tensile and puncture properties
- tensile strength
- tensile–compression ratio
- thermal aging
- trench backfilling
- tunnel grouting materials
- ultra-high-performance concrete
- ultrasonic pulse velocity
- ultrasonic testing technology
- ultraviolet aging
- unloading path
- volume stability
- water pipe cooling
- water–solid ratio
Links
DOI: 10.3390/books978-3-7258-1101-4Editions