Your search keyword '"Jian-ping Gong"' showing total 8 results

1. Unique stick-slip crack dynamics of double-network hydrogels under pure-shear loading.

Author

Yong Zheng, Yiru Wang, Fucheng Tian, Tasuku Nakajima, Chung-Yuen Hui, and Jian Ping Gong

Subjects

ENERGY dissipation, HYDROGELS, OSCILLATIONS, GEOMETRY

Abstract

In this work, we have found that a prenotched double-network (DN) hydrogel, when subjected to tensile loading in a pure-shear geometry, exhibits intriguing stick--slip crack dynamics. These dynamics synchronize with the oscillation of the damage (yielding) zone at the crack tip. Through manipulation of the loading rate and the predamage level of the brittle network in DN gels, we have clarified that this phenomenon stems from the significant amount of energy dissipation required to form the damage zone at the crack tip, as well as a kinetic contrast between the rapid crack extension through the yielding zone (slip process) and the slow formation of a new yielding zone controlled by the external loading rate (stick process). [ABSTRACT FROM AUTHOR]

Published

2024

2. Hydrogel morphogenesis induced by force-controlled growth.

Author

Zhi Jian Wang, Ji Lin, Tasuku Nakajima, and Jian Ping Gong

Subjects

HYDROGELS, MORPHOGENESIS, CHEMICAL reactions, BIOMEDICAL materials, RADICALS (Chemistry)

Abstract

Morphogenesis is one of the most marvelous natural phenomena. The morphological characteristics of biological organs develop through growth, which is often triggered by mechanical force. In this study, we propose a bioinspired strategy for hydrogel morphogenesis through force-controlled chemical reaction and growth under isothermal conditions. We adopted a double network (DN) hydrogel with sacrificial bonds. Applying mechanical force to the gel caused deformation and sacrificial bond rupture. By supplying monomers to the gel, the radicals generated by the bond rupture triggered the formation of a new network inside the deformed gel. This new network conferred plasticity to the elastic gel, allowing it to maintain its deformed shape, along with increased volume and strength. We demonstrated that sheet-shaped DN hydrogels rapidly adopted various three-dimensional shapes at ambient temperature when subjected to forces such as drawing and blowing. This mechanism enables morphogenesis of elastic hydrogels and will promote the application of these materials in biomedical fields and soft machines. [ABSTRACT FROM AUTHOR]

Published

2024

3. Gluing blood into gel by electrostatic interaction using a water-soluble polymer as an embolic agent

Author

Zhiping Jin, Hailong Fan, Toshiya Osanai, Takayuki Nonoyama, Takayuki Kurokawa, Hideki Hyodoh, Kotaro Matoba, Akiko Takeuchi, Jian Ping Gong, and Miki Fujimura

Subjects

adjacent sequence, Multidisciplinary, electrostatic interaction, Polymers, liquid embolic agent, Static Electricity, Solvents, Animals, Water, Embolization, Therapeutic, Rats

Abstract

Liquid embolic agents are widely used for the endovascular embolization of vascular conditions. However, embolization based on phase transition is limited by the adhesion of the microcatheter to the embolic agent, use of an organic solvent, unintentional catheter retention, and other complications. By mimicking thrombus formation, a water-soluble polymer that rapidly glues blood into a gel without triggering coagulation was developed. The polymer, which consists of cationic and aromatic residues with adjacent sequences, shows electrostatic adhesion with negatively charged blood substances in a physiological environment, while common polycations cannot. Aqueous polymer solutions are injectable through clinical microcatheters and needles. The formed blood gel neither adhered to the catheter nor blocked the port. Postoperative computed tomography imaging showed that the polymer can block the rat femoral artery in vivo and remain at the injection site without nontarget embolization. This study provides an alternative for the development of waterborne embolic agents.

Published

2022

4. Role of dynamic bonds on fatigue threshold of tough hydrogels

Author

Xueyu Li and Jian Ping Gong

Subjects

Multidisciplinary, time–salt superposition, Fatigue threshold, dynamic bond, rate dependence, viscoelasticity

Abstract

Fatigue threshold (G0) is the energy release rate below which no fatigue crack advances. Understanding the relationship between the static/dynamic structures and G0 of viscoelastic hydrogels is crucial for designing materials exposed to cyclic loading. In this study, we elaborate the role of dynamic bonds in the G0 of tough hydrogels. Using polyampholyte hydrogels possessing abundant ionic dynamic bonds, we can adopt time–salt superposition principle to access a wide range of time scales that are difficult to access in fatigue test. G0 was found rate-independent in the elastic regime at a low cyclic strain rate, whereas weak power-law relations between G0 and strain rate were firstly observed in viscoelastic regimes. The former agrees with molecular explanation of Lake-Thomas model, and the latter is related to the self-healing property of dynamic bonds in viscoelastic regime that protects the permanent bonds from breaking. This work modifies the previous consideration that the dynamic bonds only contribute to the fracture toughness and crack resistance but not to the G0.

Published

2022

5. How chain dynamics affects crack initiation in double-network gels.

Author

Yong Zheng, Takahiro Matsuda, Tasuku Nakajima, Wei Cui, Ye Zhang, Chung-Yuen Hui, Takayuki Kurokawa, and Jian Ping Gong

Subjects

FRACTURE mechanics, STRENGTH of materials, CRACK propagation (Fracture mechanics), FRACTURE toughness, VISCOSITY

Abstract

Double-network gels are a class of tough soft materials comprising two elastic networks with contrasting structures. The formation of a large internal damage zone ahead of the crack tip by the rupturing of the brittle network accounts for the large crack resistance of the materials. Understanding what determines the damage zone is the central question of the fracture mechanics of doublenetwork gels. In this work, we found that at the onset of crack propagation, the size of necking zone, in which the brittle network breaks into fragments and the stretchable network is highly stretched, distinctly decreases with the increase of the solvent viscosity, resulting in a reduction in the fracture toughness of the material. This is in sharp contrast to the tensile behavior of the material that does not change with the solvent viscosity. This result suggests that the dynamics of stretchable network strands, triggered by the rupture of the brittle network, plays a role. To account for this solvent viscosity effect on the crack initiation, a delayed blunting mechanism regarding the polymer dynamics effect is proposed. The discovery on the role of the polymer dynamic adds an important missing piece to the fracture mechanism of this unique material. [ABSTRACT FROM AUTHOR]

Published

2021

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

Author

Ya Nan Ye, Kunpeng Cui, Wei Hong, Xueyu Li, Chengtao Yu, Hourdet, Dominique, Tasuku Nakajima, Takayuki Kurokawa, and Jian Ping Gong

Subjects

DEFORMATIONS (Mechanics), LINEAR polymers, STRESS concentration, POLYMER networks, GLUE

Abstract

Tough soft materials usually show strain softening and inelastic deformation. Here, we study the molecular mechanism of abnormally large nonsoftening, quasi-linear but inelastic deformation in tough hydrogels made of hyperconnective physical network and linear polymers as molecular glues to the network. The interplay of hyperconnectivity of network and effective load transfer by molecular glues prevents stress concentration, which is revealed by an affine deformation of the network to the bulk deformation up to sample failure. The suppression of local stress concentration and strain amplification plays a key role in avoiding necking or strain softening and endows the gels with a unique large nonsoftening, quasi-linear but inelastic deformation. [ABSTRACT FROM AUTHOR]

Published

2021

7. Hydrogels as dynamic memory with forgetting ability.

Author

Chengtao Yu, Honglei Guo, Kunpeng Cui, Xueyu Li, Ya Nan Ye, Takayuki Kurokawa, and Jian Ping Gong

Subjects

HYDROGELS, RECOMMENDER systems, HARD materials, MEMORY, RECOLLECTION (Psychology)

Abstract

The memory of our brain, stored in soft matter, is dynamic, and it forgets spontaneously to filter unimportant information. By contrast, the existing man made memory, made from hard materials, is static, and it does not forget without external stimuli. Here we propose a principle for developing dynamic memory from soft hydrogels with temperature-sensitive dynamic bonds. The memorizing–forgetting behavior is achieved based on fast water uptake and slow water release upon thermal stimulus, as well as thermal history-dependent transparency change of these gels. The forgetting time is proportional to the thermal learning time, in analogy to the behavior of brain. The memory is stable against temperature fluctuation and large stretching; moreover, the for-getting process is programmable. This principle may inspire future research on dynamic memory based on the nonequilibrium process of soft matter. [ABSTRACT FROM AUTHOR]

Published

2020

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

Author

Xueyu Li, Kunpeng Cui, Tao Lin Sun, Lingpu Meng, Chengtao Yu, Liangbin Li, Costantino Creton, ,Takayuki Kurokawa, and Jian Ping Gong

Subjects

SMALL-angle X-ray scattering, POLYMER networks, IONIC bonds, MORPHOLOGY

Abstract

Load-bearing biological tissues, such as muscles, are highly fatigue-resistant, but how the exquisite hierarchical structures of biological tissues contribute to their excellent fatigue resistance is not well understood. In this work, we study antifatigue properties of soft materials with hierarchical structures using polyampholyte hydrogels (PA gels) as a simple model system. PA gels are tough and self-healing, consisting of reversible ionic bonds at the 1-nm scale, across-linked polymer network at the 10-nm scale, and bicontinuous hard/soft phase networks at the 100-nm scale. We find that the polymer network at the 10-nm scale determines the threshold of energy release rate G0 above which the crack grows, while the bicontinuous phase networks at the 100-nm scale significantly decelerate the crack advance until a transition Gtran far above G0.In situ small-angle X-ray scattering analysis reveals that the hard phase network suppresses the crack advance to show decelerated fatigue fracture, and Gtran corresponds to the rupture of the hard phase network. [ABSTRACT FROM AUTHOR]

Published

2020