MD simulation: The silver balls are solid particles and the blue balls are the fluid (liquid and vapour) particles. There is a liquid film sitting on a solid substrate, and there are waves at the surface. Credit: Jingbang Liu, University of Warwick
Scientists have adapted the principles of large, unexpected oceanic rogue waves to a nanoscaleThe nanoscale refers to a length scale that is extremely small, typically on the order of nanometers (nm), which is one billionth of a meter. At this scale, materials and systems exhibit unique properties and behaviors that are different from those observed at larger length scales. The prefix "nano-" is derived from the Greek word "nanos," which means "dwarf" or "very small." Nanoscale phenomena are relevant to many fields, including materials science, chemistry, biology, and physics.” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]”>nanoscale, revealing potential applications in nano-manufacturing and medical insights, supported by mathematical models inspired by quantum physics.
Researchers have shown how the principles of rogue waves – huge 30-meter waves that arise unexpectedly in the ocean – can be applied on a nanoscale, with dozens of applications from medicine to manufacturing.
Long considered to be a myth, rogue waves strike from comparably calm surroundings, smashing oil rigs and ships in their path. Unlike tsunamis, rogue waves form by the chance combination of smaller waves in the ocean, creating an event that is very rare.
Nanoscale Application of Rogue Wave Principles
There has been a lot of research into rogue waves in recent years but now, for the first time, scientists are showing how this can be applied on a much smaller scale – nanometrically. A nanometer is a million times smaller than the thickness of the page of a book. This is a completely new approach to the behavior of liquids on a nanometric scale, published as a Letter in Physical Review Fluids.
The holes and bumps caused by rogue waves can be manipulated to spontaneously produce patterns and structures for use in nano-manufacturing (manufacturing on a scale one-billionth of a meter). For example, patterns formed that rupture liquid films can be used to build microelectronic circuits, which could be used in the production of low-cost components of solar cells. Furthermore, the behavior of thin liquid layers could help to explain why millions of people worldwide suffer from dry eye. This occurs when the tear film covering the eye ruptures.
Uncovering the Behavior of Nanoscopic Liquid Layers
Through direct simulations of molecules and new mathematical models, the study led by the University of WarwickFounded in 1965 as part of a government initiative to expand higher education, the University of Warwick is a public research university with 29 academic departments and over 50 research centers and institutes. It is located on the outskirts of Coventry between the West Midlands and Warwickshire, England. It is known for its strong research and teaching in a wide range of academic disciplines, including the humanities, social sciences, natural sciences, engineering, and business. The University of Warwick has a number of research centers and institutes focused on various fields, including economics, mathematics, and sustainability.” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]”>University of Warwick’s Mathematics Institute discovered how nanoscopic layers of liquid behave in counterintuitive ways. While a layer of spilled coffee on a table may sit apparently motionless, at the nanoscale the chaotic motion of molecules creates random waves on a liquid’s surface. A rare event occurs when these waves conspire to create a large ‘rogue nanowave’ that bursts through the layer and creates a hole. The new theory explains both how and when this hole is formed, giving new insight into a previously unpredictable effect, by taking their large oceanic cousins as a mathematical blueprint.
The team of researchers is excited about the potential of this research in different industries; the applications are far-reaching.
Professor James Sprittles, Mathematics Institute, University of Warwick, said: “We were excited to discover that mathematical models originally developed for quantum physics and recently applied to predict rogue ocean waves are crucial for predicting the stability of nanoscopic layers of liquid.
“In the future, we hope that the theory can be exploited to enable an array of nano-technologies, where manipulating when and how layers rupture is crucial. There might also be applications in related areas, such as the behavior of emulsions, e.g. in foods or paints, where the stability of thin liquid films dictates their shelf-life.”
Reference: “Rogue nanowaves: A route to film rupture” by James E. Sprittles, Jingbang Liu, Duncan A. Lockerby and Tobias Grafke, 11 September 2023, Physical Review Fluids.
DOI: 10.1103/PhysRevFluids.8.L092001
Source: SciTechDaily
