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Mass Spectrometry: Molecular Fragmentation Overview01:20

Mass Spectrometry: Molecular Fragmentation Overview

5.3K
The ionization of a molecule into a molecular ion inside the mass spectrometer causes instability in the molecule's structure due to the loss of an electron. This eventually leads to the fragmentation or breaking of some bonds in the molecule. The fragmentation occurs predominantly at specific bonds to yield relatively stable fragments.
One type of fragmentation pattern is the cleavage of a single bond in the molecular ion. The cleavage leads to a radical and a cation. The cleavage can occur at...
5.3K
Habitat Fragmentation02:31

Habitat Fragmentation

20.9K
Habitat fragmentation describes the division of a more extensive, continuous habitat into smaller, discontinuous areas. Human activities such as land conversion, as well as slower geological processes leading to changes in the physical environment, are the two leading causes of habitat fragmentation. The fragmentation process typically follows the same steps: perforation, dissection, fragmentation, shrinkage, and attrition.
20.9K
Mass Spectrometry: Carboxylic Acid, Ester, and Amide Fragmentation01:01

Mass Spectrometry: Carboxylic Acid, Ester, and Amide Fragmentation

2.4K
The fragmentation patterns observed for compounds such as carboxylic acids, esters, and amides in the mass spectra include ⍺-cleavage and McLafferty rearrangement. Fragmentation by ⍺-cleavage preferentially occurs at the carbon-carbon bond at the ⍺-position next to the carboxylic group to generate a neutral radical and a cation. Long chain compounds with hydrogen at their γ-carbon undergo McLafferty rearrangement to give a radical cation and a neutral alkene.
For example, the...
2.4K
Mass Spectrometry: Branched Alkane Fragmentation01:29

Mass Spectrometry: Branched Alkane Fragmentation

1.6K
This lesson delves into the mass spectrometry of branched alkane fragmentation. Branched alkanes possess secondary or tertiary carbon atoms, which generate relatively stable carbocations if the cleavage occurs at the branching point. The high stability of carbocations drives the instant fragmentation of branched alkanes. Accordingly, the branched alkane's molecular ion peak is very weak or invisible in the mass spectra, especially in comparison to a linear alkane.
1.6K
Mechanistic Models: Overview of Compartment Models01:21

Mechanistic Models: Overview of Compartment Models

333
Mechanistic models, a category encompassing both physiological and compartmental modeling, differ from empirical models' approaches to incorporating known factors about the systems being modeled. Empirical models describe data with minimal assumptions, while mechanistic models aim to provide a robust description of available data by specifying assumptions and integrating known factors about the system. Compartmental analysis is a key example of a mechanistic model in pharmacokinetics and...
333
Mechanisms of Membrane Domain Formation00:59

Mechanisms of Membrane Domain Formation

3.7K
Different physical properties of lipids and proteins allow them to localize and form distinct islands or domains in the membrane. Some membrane domains are formed due to protein-protein interactions, whereas others are formed due to the presence of specific lipids such as sphingolipids and sterols—for example, large proteins, such as bacteriorhodopsin, aggregate and create distinct domains.
Another mechanism for membrane domain formation involves membrane proteins interacting with...
3.7K

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Updated: Jan 8, 2026

Fragmenting Bulk Hydrogels and Processing into Granular Hydrogels for Biomedical Applications
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Fragmenting Bulk Hydrogels and Processing into Granular Hydrogels for Biomedical Applications

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破砕:原理対機構

Emmanuel Villermaux1

  • 1Institut Universitaire de France, IRPHE, Centrale Marseille, CNRS, Aix Marseille Université, UMR 7342, 13384 Marseille, France and , 75005 Paris, France.

Physical review letters
|December 12, 2025
PubMed
まとめ
この要約は機械生成です。

新しい保存則とランダム性の原理は、破壊オブジェクトの破片サイズ分布を予測します。この統一的アプローチは、固体から液体まで、多様な材料にわたるべき乗則分布を説明します。

キーワード:
破砕サイズ分布べき乗則次元性物理学材料科学破壊力学

さらに関連する動画

Fundamental Technical Elements of Freeze-fracture/Freeze-etch in Biological Electron Microscopy
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Fundamental Technical Elements of Freeze-fracture/Freeze-etch in Biological Electron Microscopy

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A Method for Studying the Temperature Dependence of Dynamic Fracture and Fragmentation
09:12

A Method for Studying the Temperature Dependence of Dynamic Fracture and Fragmentation

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関連する実験動画

Last Updated: Jan 8, 2026

Fragmenting Bulk Hydrogels and Processing into Granular Hydrogels for Biomedical Applications
10:18

Fragmenting Bulk Hydrogels and Processing into Granular Hydrogels for Biomedical Applications

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Fundamental Technical Elements of Freeze-fracture/Freeze-etch in Biological Electron Microscopy
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Fundamental Technical Elements of Freeze-fracture/Freeze-etch in Biological Electron Microscopy

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A Method for Studying the Temperature Dependence of Dynamic Fracture and Fragmentation
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A Method for Studying the Temperature Dependence of Dynamic Fracture and Fragmentation

Published on: June 28, 2015

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科学分野:

  • 物理学
  • 材料科学
  • 破壊力学

背景:

  • オブジェクトの破砕の理解には、詳細なメカニズムまたは破片サイズ分布の一般原理が含まれます。
  • 既存のモデルは、普遍的なアプローチではなく、特定の破壊モードに焦点を当てることがよくあります。

研究 の 目的:

  • 破壊オブジェクトの破片サイズ分布を予測するための統一的理論的枠組みを開発すること。
  • 保存則、ランダム性、およびべき乗則破砕との関連を確立すること。

主な方法:

  • 独自の保存則の適用。
  • 最大ランダム性原理の組み込み。
  • オブジェクトの次元性(D)に依存するべき乗則指数の導出。

主要な成果:

  • 破片サイズ分布の統一的理論的予測:p(d)∼d^{-β}。
  • 指数βは次元性の関数です:β=D+1-{π^{D/2}/[2^{D}(D/2)!]}。
  • この原理は、幅広い材料と現象に適用されます。

結論:

  • さまざまな破砕現象にわたる破片サイズ分布を説明する新しい一般的な原理。
  • 導出されたべき乗則指数は、次元性に基づいた定量的予測を提供します。
  • この研究は、破砕科学における詳細なメカニズムと一般原理を橋渡しします。