通過將光學顯微鏡與流變學測試相結合可直接觀察剪下變形下的材料結構。這可提供有助於瞭解、預測和調整在加工、儲存或最終使用條件下的材料回應的關鍵資訊。
流变显微镜:连接流变学、显微结构与动力学的桥梁
将光学显微镜与流变试验相结合,能够直接观测剪切变形下的材料结构。这一手段可提供重要信息,有助于了解、预测和调整加工、储存或最终使用条件下的材料响应。
Rheo-Microscopy: Bridging Rheology, Microstructure & Dynamics
광학 현미경 관찰법과 유변물성 분석법을 조합함으로써 전단 변형에서 재료 구조를 직접 관찰할 수 있습니다. 이를 통해 가공, 보관, 최종 사용 조건 하에서의 재료 반응에 대해 이해하고 예측하며 조정하도록 도움을 줄 수 있는 중요한 정보를 얻을 수 있습니다.
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レオマイクロスコープ:レオロジー、微細構造、動力学の統合
光学顕微鏡をレオロジー試験と組み合わせることで、剪断変形時に材料構造を直接観察できます。これにより、処理、保管、または最終使用条件における材料の反応を理解、予想、調整する上で役立つ情報を入手できます。
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Rhéo-microscopie : Faire le lien entre la rhéologie, les microstructures et la dynamique
L’association de la microscopie optique et des essais rhéologiques permet d’observer directement la structure des matériaux soumis à des déformations de cisaillement. Cela fournit des informations essentielles qui peuvent permettre de comprendre, prévoir et ajuster la réponse des matériaux en conditions de traitement, de stockage ou d’utilisation finale.
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Rheo-Microscopy: Bridging Rheology, Microstructure & Dynamics
Rheo-Microscopy: Bridging Rheology, Microstructure & Dynamics
The combination of optical microscopy with rheological tests enables direct observation of material structure under shear deformation. This provides critical information that can help understand, predict, and tune the material response under processing, storage, or end-use conditions.
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Rheo-Microscopy: Bridging Rheology, Microstructure & Dynamics
Rheo-Microscopy: Bridging Rheology, Microstructure & Dynamics
The combination of optical microscopy with rheological tests enables direct observation of material structure under shear deformation. This provides critical information that can help understand, predict, and tune the material response under processing, storage, or end-use conditions.
Other Links
Rheo-Microscopy: Bridging Rheology, Microstructure & Dynamics
Rheo-Microscopy: Bridging Rheology, Microstructure & Dynamics
The combination of optical microscopy with rheological tests enables direct observation of material structure under shear deformation. This provides critical information that can help understand, predict, and tune the material response under processing, storage, or end-use conditions.