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Network Covalent Solids02:18

Network Covalent Solids

Network covalent solids contain a three-dimensional network of covalently bonded atoms as found in the crystal structures of nonmetals like diamond, graphite, silicon, and some covalent compounds, such as silicon dioxide (sand) and silicon carbide (carborundum, the abrasive on sandpaper). Many minerals have networks of covalent bonds.
To break or to melt a covalent network solid, covalent bonds must be broken. Because covalent bonds are relatively strong, covalent network solids are typically...
Ferromagnetism01:31

Ferromagnetism

Materials like iron, nickel, and cobalt consist of magnetic domains, within which the magnetic dipoles are arranged parallel to each other. The magnetic dipoles are rigidly aligned in the same direction within a domain by quantum mechanical coupling among the atoms. This coupling is so strong that even thermal agitation at room temperature cannot break it. The result is that each domain has a net dipole moment. However, some materials have weaker coupling, and are ferromagnetic at lower...
Work01:14

Work

Work is a fundamental concept of mechanical engineering and has many applications. Understanding how work is calculated and the different types of work can help us better understand physical processes and provide insights into complex problems.
Work is defined as the result of a force acting on an object, causing it to move along the line of action of force. It is also defined as the process of transferring energy through the application of force on an object, resulting in its displacement.
Softwoods and Hardwoods01:28

Softwoods and Hardwoods

Softwoods and hardwoods, derived from different types of trees, are distinguished by their leaf structures and cellular compositions, each serving unique purposes in construction and manufacturing. Softwoods come from cone-bearing trees with needle-like leaves and are predominantly composed of longitudinal cells called tracheids and a smaller proportion of radial cells known as rays. Due to their cellular structure, softwoods are commonly used in construction for structural frames, sheathing,...
Toughness and Hardness of Aggregate01:22

Toughness and Hardness of Aggregate

Toughness and hardness are critical properties of aggregate materials used in concrete, particularly on pavement surfaces and industrial flooring subjected to heavy loads. Toughness is defined as the aggregate's resistance to failure by impact and is measured by the aggregate impact value (AIV). For this, the aggregate impact value test is performed, wherein the impact is delivered by a standard hammer, which falls freely under its own weight onto the aggregates. The aggregates fragment in the...
Mechanical Characteristics of Steel01:18

Mechanical Characteristics of Steel

The mechanical characteristics of steel are assessed through various tests that evaluate its strength, toughness, and flexibility. These tests include tension, torsion, impact, bending, and hardness assessments, each providing crucial information about steel's suitability for specific applications.
The tension test is fundamental for determining tensile strength. In this test, a steel specimen is stretched using a gripping device until it breaks. The data collected during this test are used to...

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Updated: Jul 7, 2026

Quantitative Hardness Measurement by Instrumented AFM-indentation
08:21

Quantitative Hardness Measurement by Instrumented AFM-indentation

Published on: November 22, 2016

なぜシリコンは硬いのか

J J Gilman

    Science (New York, N.Y.)
    |September 10, 1993
    PubMed
    まとめ
    この要約は機械生成です。

    シリコンのような共性固体は,限られた変位運動のために脆いです. この脆さは,化学的置換に類似する原子プロセスによって説明され,これらの材料が変形に抵抗する理由が明らかになります.

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    Last Updated: Jul 7, 2026

    Quantitative Hardness Measurement by Instrumented AFM-indentation
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    科学分野:

    • マテリアルサイエンス 材料科学
    • 固体物理 固体物理学
    • 化学物理 化学物理

    背景:

    • シリコンなどの共性固体は,金属やイオン塩とは異なり,硬さや脆さを示します.
    • 配合固体における脱位運動は制限されており,高温でのみ発生する.
    • この現象の明確な説明は,材料力学におけるその重要性にもかかわらず,捉え難いものでした.

    研究 の 目的:

    • 協和固体の脆さについて満足のいく説明を提供すること.
    • これらの材料における脱位運動を制御する原子レベルのメカニズムを解明する.
    • 協和固体の機械的性質を,その結合特性と結びつけるために.

    主な方法:

    • 変位運動と化学置換反応の類似性.
    • 原子プロセスの分析のために相関図を用いる.
    • 物質変形における原子結合対称性の役割を調査する.

    主要な成果:

    • 脆さの決定的な原子プロセスは,化学的置換反応に類似しています.
    • 分析では,高抵抗性ストレスと高活性化エネルギーが変位運動のために存在することを示しています.
    • 脱位キック運動は原子結合の対称性を破壊し,エネルギー的に不利なプロセスである.

    結論:

    • 結合固体の観察された脆さは,原子置換のようなプロセスと根本的に結びついている.
    • 高い抵抗性ストレスと活性化エネルギーは,このプロセスの直接的な結果です.
    • 脱位運動中の原子結合対称性の破裂は,物質の変形に対する耐性を説明する.