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Tuesday, January 30, 2018

COFFEE-RING PATTERNS AND TAP WATER QUALITY - By looking at the pattern of residues left behind after a drop of water evaporates, scientists in the US say it may be possible to develop a simple, low-cost way to investigate the quality of tap water. Their method exploits the coffee-ring effect, where water evaporates from around the edge of a droplet, pulling water outwards from the middle and leaving a characteristic mark around the edge.

Tap Water Quality

Evaporated droplets of hard water (left) and soft water (right)
leave behind distinctive coffee-ring patterns

Coffee-ring patterns offer clues to tap water quality

Unique pattern of an evaporating droplet can be used as a fingerprint for water samples.
By looking at the pattern of residues left behind after a drop of water evaporates, scientists in the US say it may be possible to develop a simple, low-cost way to investigate the quality of tap water.
Their method exploits the coffee-ring effect, where water evaporates from around the edge of a droplet, pulling water outwards from the middle and leaving a characteristic mark around the edge.
Rebecca Lahr from Michigan State University explains that the effect can be observed by taking a 2µl droplet of water, letting it dry on a smooth surface and then looking at the residue left behind using a jeweller’s loupe – essentially a powerful magnifying glass – and a smartphone camera.
“When we do that we find that the residue pattern from each tap water is unique, so we get a fingerprint of that tap water,” says Lahr, who was presenting the work at the 254th American Chemical Society National Meeting and Exposition in Washington, DC.
“The patterns are intricate, it’s quite interesting to see how different they can be.”
By examining images of the residue patterns, Lahr and her colleagues hope to develop ways to identify different components and characteristics of a water samples.
“We can quantify how many particles there are using software,” says Lahr.
“Then we can look for correlations between particle count and concentration, we can look for correlation between the general coverage and concentration. It really depends on the solution – if you put in different concentrations of something like iron chloride you’ll get a different result to if you put in something like copper chloride.”
Fingerprint database
The eventual aim is to build up a library of patterns, and potentially a computational tool that will allow people to analyse samples of their own water at home.
“We’re trying to develop a low-cost way that anyone anywhere in the world can look at what’s in their tap water,” says Lahr.
“In order to use existing tools like [test strips] you have to know what you’re looking for. If we can have more methods that can fingerprint a sample then in theory we can find problems faster.”
The idea of using the coffee-ring effect in this way came from previous work in which the group explored it as a way to concentrate contaminants such as cyanotoxins around the edge of droplet-sized water samples so they can be quantified.
“I was doing that work with all sorts of different solutions […] you see intricate patterns all the time, and I always wondered exactly what is causing all of that,” Lahr says.
“The more I looked at tap water samples the more I realised it’s controlled by water chemistry, so we might be able to harness that.”
Lahr admits there is a limit to the extent water content can be analysed using this technique.
While there are definitely definable differences between the patterns left by hard and soft water, for example, it is not yet possible to analyse complex mixtures of solutes or individual contaminants.
“We’re still working on many of the details of this method,” she says.
“We’re really trying to harness this phenomenon, but we’ve got a long way to go with the research.”

 

Emma Stoye
As Chemistry World's senior science correspondent, I spend most of my time reading, writing and talking about cutting-edge research as well as the bigger issues affecting scientists such as funding or peer review. 
My scientific background is rather mixed. Before becoming a chemistry journalist I studied biological sciences at the University of Oxford, where my main subjects were plant, animal and environmental biology. But a few weeks into my degree I realised that lab work wasn’t for me. After graduating I got my first real taste of science journalism working as an intern for the Naked Scientists podcast, and was instantly hooked. In the years since I’ve been lucky enough to interview dozens of leading scientists and write about their research.
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Monday, January 29, 2018

SOAP - Soap is an Emulsifier - Soap is an excellent cleanser because of its ability to act as an emulsifying agent. An emulsifier is capable of dispersing one liquid into another immiscible liquid. This means that while oil (which attracts dirt) doesn't naturally mix with water, soap can suspend oil/dirt in such a way that it can be removed.

A soap micelle has a hydrophilic head and hydrophobic tails
Soap
How Does Soap Work?
Soap is an Emulsifier
By Anne Marie Helmenstine, Ph.D.
Soaps are sodium or potassium fatty acids salts, produced from the hydrolysis of fats in a chemical reaction called saponification.
Each soap molecule has a long hydrocarbon chain, sometimes called its 'tail,' with a carboxylate 'head'.
In water, the sodium or potassium ions float free, leaving a negatively-charged head.
Soap is an excellent cleanser because of its ability to act as an emulsifying agent.
An emulsifier is capable of dispersing one liquid into another immiscible liquid.
This means that while oil (which attracts dirt) doesn't naturally mix with water, soap can suspend oil/dirt in such a way that it can be removed.
The organic part of a natural soap is a negatively-charged, polar molecule.
Its hydrophilic (water-loving) carboxylate group (-CO2) interacts with water molecules via ion-dipole interactions and hydrogen bonding.
The hydrophobic (water-fearing) part of a soap molecule, its long, nonpolar hydrocarbon chain, does not interact with water molecules.
The hydrocarbon chains are attracted to each other by dispersion forces and cluster together, forming structures called micelles.
In these micelles, the carboxylate groups form a negatively-charged spherical surface, with the hydrocarbon chains inside the sphere.
Because they are negatively charged, soap micelles repel each other and remain dispersed in water.
Grease and oil are nonpolar and insoluble in water.
When soap and soiling oils are mixed, the nonpolar hydrocarbon portion of the micelles break up the nonpolar oil molecules.
A different type of micelle then forms, with nonpolar soiling molecules in the center.
Thus, grease and oil and the 'dirt' attached to them are caught inside the micelle and can be rinsed away.
Although soaps are excellent cleansers, they do have disadvantages.
As salts of weak acids, they are converted by mineral acids into free fatty acids:
CH3(CH2)16CO2-Na+ + HCl CH3(CH2)16CO2H + Na+ + Cl-
These fatty acids are less soluble than the sodium or potassium salts and form a precipitate or soap scum.
Because of this, soaps are ineffective in acidic water.
Also, soaps form insoluble salts in hard water, such as water containing magnesium, calcium, or iron.
2 CH3(CH2)16CO2-Na+ + Mg2+  [CH3(CH2)16CO2-]2Mg2+ + 2 Na+
The insoluble salts form bathtub rings, leave films that reduce hair luster, and gray/roughen textiles after repeated washings.
Synthetic detergents, however, may be soluble in both acidic and alkaline solutions and don't form insoluble precipitates in hard water.
But that is a different story... 


Anne Marie Helmenstine, Ph.D. is an author and consultant with a broad scientific and medical background.
Experience
Anne has taught chemistry, biology, and physics at the high school, college, and graduate level. In her doctoral work, Anne developed ultra-sensitive chemical detection and medical diagnostic tests. She has worked abstracting/indexing diverse scientific literature for the Department of Energy. She presently works as a freelance writer and scientific consultant. She enjoys adapting lab-based science projects so that they can be performed safely at home.
Education
Dr. Helmenstine has bachelor of arts degrees in physics and mathematics with a minor in chemistry from Hastings College in Nebraska and a doctorate of philosophy in biomedical sciences from the University of Tennessee at Knoxville.
Anne Marie Helmenstine, Ph.D.
Chemistry is part of everyone's life, from cooking and cleaning to the latest computer chip technology and vaccine development. It doesn't have to be intimidating and it doesn't have to be hard to understand.
You can read more about Anne's current and past work on her Google Profile: Anne Helmenstine. Find Anne's printable periodic tables and science projects at Science Notes.

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PETROLEUM COMPOSITION - There are four main types of hydrocarbons found in crude oil: paraffins, naphthenes, aromatics and asphaltics. The hydrocarbons primarily are alkanes, cycloalkanes, and aromatic hydrocarbons. The most common metals are iron, nickel, copper, and vanadium. Most petroleum is dark brown or blackish in color, but it also occurs in green, red, or yellow.

Petroleum Composition
 Crude Oil can be brown or yellow in color
Chemical Composition of Petroleum
By Anne Marie Helmenstine, Ph.D. 
Petroleum or crude oil is a complex mixture of hydrocarbons and other chemicals.
The composition varies widely depending on where and how the petroleum was formed.
In fact, a chemical analysis can be used to fingerprint the source of the petroleum.
However, raw petroleum or crude oil has characteristic properties and composition.

Hydrocarbons in Crude Oil

There are four main types of hydrocarbons found in crude oil.
1.        paraffins (15-60%)
2.        naphthenes(30-60%)
3.        aromatics (3-30%)
4.        asphaltics (remainder)
The hydrocarbons primarily are alkanes, cycloalkanes, and aromatic hydrocarbons.

Elemental Composition of Petroleum

Although there is considerable variation between the ratios of organic molecules, the elemental composition of petroleum is well-defined:
1.        Carbon - 83 to 87%
2.        Hydrogen - 10 to 14%
3.        Nitrogen - 0.1 to 2%
4.        Oxygen - 0.05 to 1.5%
5.        Sulfur - 0.05 to 6.0%
6.        Metals - < 0.1%
The most common metals are iron, nickel, copper, and vanadium.

Petroleum Color and Viscosity

The color and viscosity of petroleum vary markedly from one place to another.
Most petroleum is dark brown or blackish in color, but it also occurs in green, red, or yellow. 


Anne Marie Helmenstine, Ph.D. is an author and consultant with a broad scientific and medical background.
Experience
Anne has taught chemistry, biology, and physics at the high school, college, and graduate level. In her doctoral work, Anne developed ultra-sensitive chemical detection and medical diagnostic tests. She has worked abstracting/indexing diverse scientific literature for the Department of Energy. She presently works as a freelance writer and scientific consultant. She enjoys adapting lab-based science projects so that they can be performed safely at home.
Education
Dr. Helmenstine has bachelor of arts degrees in physics and mathematics with a minor in chemistry from Hastings College in Nebraska and a doctorate of philosophy in biomedical sciences from the University of Tennessee at Knoxville.
Anne Marie Helmenstine, Ph.D.
Chemistry is part of everyone's life, from cooking and cleaning to the latest computer chip technology and vaccine development. It doesn't have to be intimidating and it doesn't have to be hard to understand.
You can read more about Anne's current and past work on her Google Profile: Anne Helmenstine. Find Anne's printable periodic tables and science projects at Science Notes.

Multi-Media Filter, Highly-Activated Carbon Filter,
Zeolite-Process Water Softener With Brine Tank,
Fiberglass Ballast-Type Pressure Tank
(fully automatic backwash & regeneration)
PURICARE 
INDUSTRIAL 
ENTERPRISES 
Water 
Treatment 
Systems
.
.
...
Aganan, Pavia, Iloilo, Philippines
...

CLICK HERE . . . to view company profile . . .