PEER-REVIEWED PUBLICATION

2026

Harnessing Chain Mobility via Protonation for Tough and Isotropic Hydrogel

Shi P, Si M, et al.

Advanced Materials

University of California – Los Angeles, Pennsylvania State University, Argonne National Laboratory

RESEARCH SUMMARY
This study reports a scalable processing strategy to create ultra-tough, mechanically isotropic poly(vinyl alcohol) (PVA) hydrogels by sequentially modulating polymer chain mobility and physical crosslinking through (i) acidification, (ii) freeze–thaw gelation, and (iii) salting-out. Acidification protonates PVA hydroxyl groups, suppressing premature interchain hydrogen bonding and aggregation to homogenize the precursor network. A freeze–thaw step introduces minimal physical crosslinks to retain macroscopic gel integrity, followed by salting-out (e.g., sodium citrate) that deprotonates hydroxyls and drives controlled crystallite formation and dense hydrogen-bonded domains acting as strong, reversible physical crosslinks. By tuning acid concentration/species and PVA concentration, the authors achieved isotropic hydrogels with exceptional mechanical performance, including tensile strength up to 29.5 MPa, stretchability ≈2683–2684%, and record-high toughness of 424 MJ m−3 among isotropic hydrogels. Mechanistic validation combined porosity/microstructure (SEM, mercury intrusion porosimetry, optical transparency/UV–vis), crystallinity and crystal spacing (DSC, SAXS), crystalline-region mapping (FLIM), and reactive MD/DFT-supported analysis of protonation effects on hydrogen bonding and chain conformation. The hydrogel also demonstrated strong energy dissipation and fatigue resistance (fatigue threshold ~4.46 kJ m−2), and the approach was shown to be generalizable (e.g., gelatin) and compatible with additive manufacturing via DLP printing of a methacrylated PVA derivative (PVAMA) followed by the same toughening sequence.

CELLSCALE INSTRUMENT USED

UniVert

CellScale UniVert mechanical testing was used to generate the core tensile, cyclic, and fatigue-performance datasets for the toughened hydrogels. For monotonic tensile testing, hydrogels were cut into dog-bone specimens (gauge width ~1.5 mm), specimen thickness and width were measured by caliper, and stress–strain curves were collected at a strain rate of 7.5% s−1 to determine ultimate tensile strength, stretchability, and toughness across formulations (varying acid concentration/species and PVA wt.%). For cyclic tensile characterization and hysteresis/energy-dissipation assessment, rectangular specimens (gauge width ~1.5 mm; dimensions measured by caliper) were loaded/unloaded at 7.5% s−1; tests were performed while the sample was immersed in a salt-solution bath to maintain the salting-out environment during cycling. UniVert was also used for fatigue resistance characterization using the single-notch method under cyclic loading in a 1.5 M sodium citrate bath; crack-growth behavior under repeated cycling was used to determine the fatigue threshold (energy release rate), and additional long-cycle validation (thousands of cycles) demonstrated minimal crack propagation at sub-threshold conditions. Collectively, UniVert measurements provided the quantitative basis for comparing isotropy-preserving toughening outcomes (strength–stretch–toughness tradeoffs), evaluating reversible physical crosslinking under cyclic strain, and establishing fatigue durability of the protonation + salting-out engineered network.
AUTHORS

Pengju Shi, Muqing Si, Zishang Lin, Qian Mao, Sidi Duan, Zixiao Liu, Wen Hong, Mason Possinger, Yichen Yan, Chi Chen, Ping He, Xiaobing Zuo, Hua Zhou, Adri van Duin, Ximin He.

PUBLICATION DETAILS
JOURNAL

Advanced Materials

YEAR

2026

INSTITUTIONS

University of California – Los Angeles, Pennsylvania State University, Argonne National Laboratory

COUNTRIES

United States

INSTRUMENT USED

UniVert

TESTING METHODS

Fatigue TestingHydrated and Temperature Controlled TestingTensile Testing

RESEARCH APPLICATIONS

Hydrogel Mechanical TestingPolymers and Elastomers TestingSoft Robotics Materials

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