ShearView: A compact stress- and strain-controlled linear rheometer for integrated rheomicroscopy

Abstract

We present ShearView, a compact, cost-effective, and open-source linear rheometer, that enables both strain- and stress-controlled shear experiments, while being fully compatible with high-resolution optical microscopy. Designed for transparency and modularity, the device integrates mechanical simplicity, dual feedback control, and real-time synchronization of rheological and optical data, thereby enabling a simultaneous investigation of macroscopic mechanical response and microscopic structural dynamics across a wide range of soft matter systems. ShearView is primarily constructed from off-the-shelf components and operated via custom LabVIEW software. Calibration procedures and feedback algorithms allow for the accurate application of arbitrary stress or strain waveforms in both linear and nonlinear regimes. We validate the instrument against a commercial rotational rheometer (Anton Paar MCR 702e), demonstrating excellent agreement in frequency sweeps performed in the linear viscoelastic regime and large-amplitude oscillatory shear for the materials and frequency ranges tested here. In addition, we implement nonstandard rheological protocols, such as chirped oscillations and recovery rheology. We further illustrate the system capabilities through synchronized imaging during echo and shear-cessation protocols, highlighting its potential to link bulk rheological response with underlying microscopic dynamics. All hardware designs, control software, and example datasets are freely available to facilitate reuse, customization, and educational deployment.

Nikolaos Kalafatakis

PhD Student

My research interests include Rheometry, Instrumentation and Soft Matter Physics.

Roberto Cerbino

Professor of Experimental Soft Matter Physics

My research interests include Soft matter physics, living matter, cell biophysics and quantitative microscopy.