Dynamics of capillary effects in spin conversion of water isomers

TL;DR

This study investigates how hydrodynamic cavitation influences capillary effects and water isomer dynamics, revealing measurable changes in surface tension and water movement that could impact biological and technological applications.

Contribution

It introduces a novel experimental approach to detect spin-based phenomena affecting water's surface tension and viscosity, with potential applications in biosensing and plant water transport.

Findings

Surface tension differences of 6.7%-11.3% observed between control and experimental samples.

Experimental samples showed twice the movement length compared to controls.

Capillary effects can be used to detect spin-based phenomena affecting water properties.

Abstract

This work explores the dynamics of capillary effects in pure H2O excited by hydrodynamic cavitation, which has been reported to introduce a non-equilibrium state of para- and ortho- isomers of water. Differential measurements are conducted with 0.3mm and 0.5mm capillary tubes and precision digital vernier height gauges. Water samples are degassed at -0.09 MPa, their temperature is equalized. Since the non-equilibrium state of isomers is expected to exist in ice-like building blocks near the water interfaces, the immersion depth of capillary tubes was set to 10mm, 2mm and about 0.1mm below the surface. The measurement results show the difference in surface tension of 6.7%-11.3% with a maximum value of about 15.7% between control and experimental samples. These effects in near-surface layers are observed within 30-60 minutes after the excitation. Experimental samples taken from the surface demonstrate movement about 2 times longer than control ones; their values are largest in the whole series of experiments. Micro-manipulation tool recorded an interesting effect of stopping the liquid in capillary tubes, observed mostly in experimental samples, where the meniscus and surface tension oscillated at 0.05-0.1mm level. The described approach has two main applications. First, the measurement system can be used as the fast and cost effective detector of spin-based phenomena that affect viscosity and surface tension. Second, since the capillary effects plays an important role in aquaporin channels and plant water transportation system, these techniques can be applied in phytosensing, in particular, in sap flow measurements, and in a hydroponic production.