Dynamic, hollow nanotubular networks with superadjustable pH-responsive and temperature resistant rheological characteristics

“…68,69 The operation principles behind these are based on the physicochemical property changes associated with physiological stimuli such as temperature, sweat, and stress. Responsiveness towards external stimuli including pH, 70 temperature, 71 light, 72 redox reactions, 73 electric field, 74 and magnetic field 75 has been demonstrated for various SMAs. Supramolecular assemblies (SMA) are suitable for satisfying some of these demands owing to the existence of dynamic bonds constructing them.…”

pH- and temperature-responsive supramolecular assemblies with highly adjustable viscoelasticity: a multi-stimuli binary system

“…68,69 The operation principles behind these are based on the physicochemical property changes associated with physiological stimuli such as temperature, sweat, and stress. Responsiveness towards external stimuli including pH, 70 temperature, 71 light, 72 redox reactions, 73 electric field, 74 and magnetic field 75 has been demonstrated for various SMAs. Supramolecular assemblies (SMA) are suitable for satisfying some of these demands owing to the existence of dynamic bonds constructing them.…”

pH- and temperature-responsive supramolecular assemblies with highly adjustable viscoelasticity: a multi-stimuli binary system

Stochastic optimal control of mesostructure of supramolecular assemblies using dissipative particle dynamics and dynamic programming with experimental validation

Stimuli-responsive viscosity modifiers