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Работы, на которые ссылается эта работа

Работ: 64

Работа: Competing Effects of Amorphous and Crystalline Networks on the Mechanical Behavior of Poly(vinyl alcohol) Hydrogel

  1. Hydrogels Classification According to the Physical or Chemical Interactions and as Stimuli-Sensitive Materials

    Moisés Bustamante-Torres, David Romero-Fierro, Belén Arcentales-Vera +3

    Обзорная статья2021Цитирований: 5
    ABI

  2. The Polyrotaxane Gel: A Topological Gel by Figure-of-Eight Cross-links

    Yasushi Okumura, Kohzo Ito

    Статья2001Цитирований: 3
    ABI

  3. Nanocomposite Hydrogels: A Unique Organic–Inorganic Network Structure with Extraordinary Mechanical, Optical, and Swelling/De-swelling Properties

    Kazutoshi Haraguchi, Toru Takehisa

    Статья2002Цитирований: 3
    ABI

  4. Analysis of small angle neutron scattering spectra from polydisperse interacting colloids

    Michael Kotlarchyk, Sow‐Hsin Chen

    Статья1983Цитирований: 2
    ABI

  5. Small Angle Neutron Scattering Studies of the Structure and Interaction in Micellar and Microemulsion Systems

    S H Chen

    Статья1986Цитирований: 2
    ABI

  6. Programmable nanocomposites of cellulose nanocrystals and zwitterionic hydrogels for soft robotics

    Rasool Nasseri, Negin Bouzari, Junting Huang +6

    Статья2023Цитирований: 2
    ABI

  7. Oppositely Charged Polyelectrolytes Form Tough, Self‐Healing, and Rebuildable Hydrogels

    Feng Luo, Tao Lin Sun, Tasuku Nakajima +7

    Статья2015Цитирований: 2
    ABI

  8. Highly enhanced toughness of interpenetrating network hydrogel by incorporating poly(ethylene glycol) in first network

    Wang Luyi, Guorong Shan, Pengju Pan

    Статья2014Цитирований: 2
    ABI

  9. Moisture‐induced effects on the tensile mechanical properties and glass‐transition temperature of poly(vinyl alcohol) films

    M. V. Konidari, Kyriaki G. Papadokostaki, M. Sanopoulou

    Статья2011Цитирований: 2
    ABI

  10. Physical hydrogels composed of polyampholytes demonstrate high toughness and viscoelasticity

    Tao Lin Sun, Takayuki Kurokawa, Shinya Kuroda +6

    Статья2013Цитирований: 2
    ABI

  11. Structural Organization of Poly(vinyl alcohol) Hydrogels Obtained by Freezing and Thawing Techniques:  A SANS Study

    Rosa Ricciardi, Gaetano Mangiapia, Fabrizio Lo Celso +5

    Статья2005Цитирований: 2
    ABI

  12. Glass transition temperature regulation effect in a poly(vinyl alcohol)—water system

    J. Rault, Ruxandra Gref, Z. H. Ping +2

    Статья1995Цитирований: 2
    ABI

  13. Ultra-small-angle neutron scattering studies on phase separation of poly(vinyl alcohol) gels

    H. Takeshita, Toshiji Kanaya, Koji Nishida +3

    Статья2000Цитирований: 2
    ABI

  14. Fracture energy of gels

    Y. Tanaka, K. Fukao, Y. Miyamoto

    Статья2000Цитирований: 2
    ABI

  15. DESIGN AND CHARACTERIZATION OF A BIOCOMPATIBLE PHYSICAL HYDROGEL BASED ON SCLEROGLUCAN FOR TOPICAL DRUG DELIVERY

    Patrizia Paolicelli, Gabriele Varani, Settimio Pacelli +5

    Статья2017Цитирований: 2
    ABI

  16. Multiscale Energy Dissipation Mechanism in Tough and Self-Healing Hydrogels

    Kunpeng Cui, Tao Lin Sun, Xiaobin Liang +5

    Статья2018Цитирований: 2
    ABI

  17. Effect of Structure Heterogeneity on Mechanical Performance of Physical Polyampholytes Hydrogels

    Kunpeng Cui, Ya Nan Ye, Tao Lin Sun +6

    Статья2019Цитирований: 2
    ABI

  18. Biomimetic Color-Changing Hierarchical and Gradient Hydrogel Actuators Based on Salt-Induced Microphase Separation

    Yang Yang, Fei Tian, Xionglei Wang +4

    Статья2019Цитирований: 2
    ABI

  19. Mesoscale bicontinuous networks in self-healing hydrogels delay fatigue fracture

    Xueyu Li, Kunpeng Cui, Tao Lin Sun +6

    Статья2020Цитирований: 2
    ABI

  20. Stimuli-responsive conductive hydrogels: design, properties, and applications

    Zexing Deng, Rui Yu, Baolin Guo

    Статья2021Цитирований: 2
    ABI

  21. Molecular mechanism of abnormally large nonsoftening deformation in a tough hydrogel

    Ya Nan Ye, Kunpeng Cui, Wei Hong +6

    Статья2021Цитирований: 2
    ABI

  22. Effect of mesoscale phase contrast on fatigue-delaying behavior of self-healing hydrogels

    Xueyu Li, Kunpeng Cui, Takayuki Kurokawa +5

    Статья2021Цитирований: 2
    ABI

  23. Structural Heterogeneity and Its Influence on Nonlinear Deformation and the Fracture of Ultrasoft Hydrogels

    Yuanyuan Wei, Donghao Zhao, Costantino Creton +1

    Статья2023Цитирований: 2
    ABI

  24. Acid-Induced Gelation of Carboxymethylcellulose Solutions

    Gauthier Legrand, Guilhem P. Baeza, Matteo Peyla +4

    Статья2024Цитирований: 2
    ABI

  25. Без названия

    ДругоеЦитирований: 1
    ABI