Posted on 08/01/2022 10:47:25 AM PDT by Red Badger
The motion of single atoms through liquid has been caught on camera for the first time.
Using a sandwich of materials so thin they're effectively two-dimensional, scientists trapped and observed platinum atoms 'swimming' along a surface under different pressures.
The results will help us better understand how the presence of liquid alters the behavior of a solid with which it is in contact – which, in turn, has implications that could in the development of new substances and materials.
"Given the widespread industrial and scientific importance of such behavior it is truly surprising how much we still have to learn about the fundamentals of how atoms behave on surfaces in contact with liquids," explained materials scientist Sarah Haigh of the University of Manchester in the UK.
"One of the reasons information is missing is the absence of techniques able to yield experimental data for solid-liquid interfaces."
When a solid and a liquid are in contact with each other, the behaviors of both materials are modified where they meet. These interactions are important for understanding a wide range of processes and applications, such as the transport of materials inside our own bodies or the movement of ions inside batteries.
It is, as the researchers note, extremely difficult to view the world on the atomic scale. Transmission electron microscopy (TEM), which uses a beam of electrons to generate an image, is one of the few techniques available.
Even so, obtaining reliable data on the behavior of atoms this way has been tricky. Previous work in graphene liquid cells has been promising, but has yielded inconsistent results. In addition, TEM typically requires a high vacuum environment to run. This is a problem since many materials don't behave the same way under different pressure conditions.
Thankfully a form of TEM has been developed to operate in liquid and gaseous environments, which is what the team employed for their research.
The next step was to create a special set of microscope "slides" to contain the atoms. Graphene is the ideal material for these experiments, because it is two-dimensional, strong, inert and impermeable. Building on previous work, the team developed a double graphene liquid cell capable of working with existing TEM technology.
This cell was filled with a precisely-controlled salt water solution containing platinum atoms, which the team observed moving about on a solid surface of molybdenum disulfide.
The images revealed some fascinating insights. For example, the atoms moved faster in liquid than outside of it, and choose different places on the solid surface to rest.
In addition, the results inside and outside of a vacuum chamber were different, suggesting that variations in the environment's pressure can influence how atoms behave. What's more, results of experiments obtained in vacuum chambers won't necessarily be indicative of that behavior in the real world.
"In our work we show that misleading information is provided if the atomic behavior is studied in vacuum instead of using our liquid cells," said materials engineer Nick Clark of the University of Manchester.
"This is a milestone achievement and it is only the beginning – we are already looking to use this technique to support development of materials for sustainable chemical processing, needed to achieve the world's net zero ambitions."
The material the team studied is relevant to the production of green hydrogen, but both their techniques and the results they obtained have much broader implications, the researchers said.
The paper has been published in Nature.
Double graphene liquid cell. (Clark et al., The University of Manchester)
Graphene Ping!....................
I don’t want to end up in a Double graphene liquid cell. It sounds more severe than Double secret probation.
If the atoms are “swimming in liquid”, what’s the liquid made out of?
One method for cooling semiconductors is to drill holes in the substrate and run coolant through them. This might help in this area.
One method for cooling semiconductors is to drill holes in the substrate and run coolant through them. This might help in this area.
graphene liquid..................
Oh, never mind...I thought you said Adams.
Molecules.
Wouldn’t that be like a person swimming in Oldsmobiles?
Not to detract from this achievement in any way, but I have seen the very same thing during several of my boxing matches.
the article said salt solution. But you make an important point. An ionic liquid most likely will provide a different result than a non-ionic liquid. And in a liquid compared to on the surface or in a thick volume ( they used a thin cell) will also provide different results. Their results is a start but only a start.
Doing the breaststroke or Backstroke, it’s hard to tell.....................
Unobtanium
Which one is Marco?
the payoff comes when they are able to cheaply separate all the minerals and metals in seawater for a profit.
that will effectively double the size of planet earth.
Is this Brownian motion - or something else?
Why’s it so grainy?
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