June 24, 2009

Salt block unexpectedly stretches in new experiments

Salt block unexpectedly stretches in new experiments
Sandia-developed interfacial force microscope tip unexpectedly creates a tendril from a block of salt as the tip retreats from the salt surface. The picture was taken by a transmission electron microscope at the Sandia/Los Alamos Center for Integrated Nanotechnologies. Credit: Jianyu Huang

To stretch a supply of salt generally means using it sparingly.

But researchers from Sandia National Laboratories and the University of Pittsburgh were startled when they found they had made the solid actually physically stretch.

"It's not supposed to do that," said Sandia principal investigator Jack Houston. "Unlike, say, gold, which is ductile and deforms under pressure, salt is brittle. Hit it with a hammer, it shatters like glass."

That a block of salt can stretch rather than remain inert might affect world desalination efforts, which involve choosing particular sizes of nanometer-diameter pores to strain salts from brackish water. Understanding unexpected salt also may lead to better understanding of sea salt aerosols, implicated in problems as broad as cloud nucleation, smog formation, ozone destruction and asthma triggers, the researchers write in their paper published in the May Nanoletters.

Salt block unexpectedly stretches in new experiments
Sandia researchers Jack Houston (left) and Nathan Moore examine a tiny salt block while the screen behinds them shows the magnified tip of the Sandia-developed interfacial force microscope (device in the foreground) performing another materials interrogation. The device was developed by Houston. Credit: Sandia National Laboratories

The serendipitous discovery came about as researchers were examining the of salt in the absence of water. They found unexpectedly that the brittle substance appeared malleable enough to distort over surprisingly long distances by clinging to a special microscope's nanometer-sized tip as it left the surface of the salt.

More intense examination showed that surface salt molecules formed a kind of bubble — a ductile meniscus — with the exploratory tip as it withdrew from penetrating the cube. In this, it resembled the behavior of the surface of water when an object is withdrawn from it. But unlike water, the salt meniscus didn't break from its own weight as the tip was withdrawn. Instead it followed the tip along, slip-sliding away (so to speak) as it thinned and elongated from 580 (nm) to 2,191 nm in shapes that resembled nanowires.

A possible explanation for salt molecules peeling off the salt block, said Houston, is that "surface molecules don't have buddies." That is, because there's no atomic lattice above them, they're more mobile than the internal body of salt molecules forming the salt block.

Salt showing signs of surface mobility at room temperatures was "totally surprising," said Houston, who had initially intended to study more conventionally interesting characteristics of the one-fourth-inch square, one-eighth-inch-long block.

Source: Sandia National Laboratories (news : web)

Citation: Salt block unexpectedly stretches in new experiments (2009, June 24) retrieved 20 April 2024 from https://phys.org/news/2009-06-salt-block-unexpectedly.html
This document is subject to copyright. Apart from any fair dealing for the purpose of private study or research, no part may be reproduced without the written permission. The content is provided for information purposes only.

Explore further

Salt production started in ancient China
0 shares

Feedback to editors

Relevant PhysicsForums posts

Inductive Heating of a Non-Conductive Reactor's Contents

Apr 18, 2024

System curve and centrifugal pump suitability

Apr 3, 2024

Maximum mass flow in a shell & tube heat exchanger

Apr 3, 2024

Air-to-fuel ratio of ethanol

Mar 27, 2024

Isotopic exchange and SIMS diffusion profile measurement

Mar 20, 2024

Stainless Steel corrosion issue

Mar 5, 2024

More from Materials and Chemical Engineering

Load comments (4)