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Microcracking in Concrete01:20

Microcracking in Concrete

Microcracking in concrete refers to the tiny cracks that can form within the material even before any external load is applied. These microcracks typically occur at the interface between the coarse aggregate and the hydrated cement paste, often as a result of differential volume changes prompted by variations in stress-strain behavior, as well as thermal and moisture movement. Initially, these microcracks remain stable and do not grow substantially until the concrete is stressed to about 30...
Types of Non-structural Cracks in Concrete01:28

Types of Non-structural Cracks in Concrete

Non-structural cracks are primarily of three types: plastic, early-age thermal, and drying shrinkage cracks. Plastic cracks are further classified into plastic shrinkage cracks and plastic settlement cracks.
Plastic shrinkage cracks typically form within hours after the concrete is poured. The concrete's surface dries faster than the bottom, creating tensile stress that the still-plastic concrete cannot withstand, leading to diagonal or randomly patterned cracks on the concrete surface.
Plastic...
Behavior of Concrete Under Compressive Load01:23

Behavior of Concrete Under Compressive Load

Concrete exhibits specific behaviors under different compressive loads. Understanding this is crucial for understanding its structural integrity. When concrete undergoes uniaxial compression, it tends to develop cracks that run parallel to the direction of the force. These parallel cracks stem from localized tensile stresses that occur perpendicular to the compression direction. Additionally, angled cracks may appear due to the formation of shear planes.
As the concrete specimen fractures under...
Mass Concreting01:22

Mass Concreting

Mass concreting refers to the process of placing large volumes of concrete, such as in gravity dams. The heat generated during the cement hydration process and differential cooling rates within the concrete mass can lead to a temperature gradient, which can result in thermal cracks in the concrete mass.
To reduce the risk of such cracking, the concrete mix may incorporate low-heat cement and pozzolans to reduce the temperature rise. Pre-cooled angular aggregates and water-reducing admixtures...
Creep in Concrete01:22

Creep in Concrete

Creep refers to the time-dependent increase in strain under a sustained load, excluding other time-dependent deformations associated with shrinkage, swelling, and thermal expansion in concrete. The primary mechanism behind creep involves the loss of physically adsorbed water from the calcium silicate hydrate within the hydrated cement paste. This process is further exacerbated by concrete's non-linear stress-strain relationship, microcrack development in the interfacial transition zone, and...
Design Example: Joints in Concrete Pavements01:28

Design Example: Joints in Concrete Pavements

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...

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Updated: May 22, 2026

Control of Cell Geometry through Infrared Laser Assisted Micropatterning
11:04

Control of Cell Geometry through Infrared Laser Assisted Micropatterning

Published on: July 10, 2021

El patrón se crea mediante el agrietamiento controlado.

Koo Hyun Nam1, Il H Park, Seung Hwan Ko

  • 1Research Center of MEMS Space Telescope, Department of Physics, Ewha Womans University, Daehyun-dong 11-1, Seodaemun-gu, Seoul 120-750, South Korea. koonam@namk.org

Nature
|May 12, 2012
PubMed
Resumen
Este resumen es generado por máquina.

Los investigadores controlaron los patrones de grietas en las películas de nitruro de silicio en sustratos de silicio. Esta técnica permite la nanofabricación precisa de morfologías de grietas intrincadas y ordenadas para aplicaciones de materiales avanzados.

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Área de la Ciencia:

  • Ciencia de los materiales Ciencia de los materiales.
  • Nanotecnología La nanotecnología es la nanotecnología.
  • Mecánica de las fracturas Mecánica de las fracturas

Sus antecedentes:

  • La formación de grietas generalmente conduce a la falla del material.
  • Sin embargo, el agrietamiento puede producir patrones complejos como espirales, oscilaciones y geometrías fractales.

Objetivo del estudio:

  • Para demostrar la iniciación controlada, la propagación y la terminación de los patrones de grietas canalizadas.
  • Para explorar la creación de distintas morfologías de grietas en un sistema de película / sustrato.

Principales métodos:

  • Utilizó una película delgada de nitruro de silicio sobre un sustrato de silicio.
  • Empleado micro-muescas en el sustrato para concentrar la tensión para el inicio de grietas.
  • Condiciones de procesamiento controladas para lograr patrones específicos de grietas.

Principales resultados:

  • Creó con éxito tres morfologías reproducibles de grietas: rectas, oscilatorias y bifurcadas ordenadamente (similares a puntadas).
  • Control demostrado sobre los cambios en la dirección de las grietas mediante la alteración de los parámetros del sistema.
  • Se logró la terminación de la propagación de las grietas utilizando paradas de grietas de varios pasos preformadas.

Conclusiones:

  • La técnica de patronización desarrollada ofrece nuevas oportunidades en la nanofabricación.
  • Proporciona una base para la formación de patrones a escala atómica, superando los métodos actuales de vanguardia.