Water, Water...

X-Message-Number: 15114
From: "Jan Coetzee" <>
Subject: Water, Water...
Date: Wed, 13 Dec 2000 21:49:28 -0500

This is a multi-part message in MIME format.

------=_NextPart_000_00B0_01C0654E.91921BA0
Content-Type: text/plain;
	charset="iso-8859-1"


Maybe under pressure the water between the hydrophobic membrane layers will not 
crystalize.
=======================================================
Water, Water...

I always fancied the idea of polywater and what it might be able to do. But, 
then I also quite like the idea of using chemistry to convert lead into gold, a 
money tree and the magic porridge pot. While, polywater may have turned out to 
be a lost cause, chemists have for many years unearthed some quite bizarre 
properties from the liquid of life, writes David Bradley.




--------------------------------------------------------------------------------


The discoveries about this elemental material continue to this day with a 
collaborative team from Japan and the US publishing results in Nature recently 
(30 November 2000) that show that water becomes a two-dimensional glass and 
shrinks under extreme pressure when cooled and confined. 

 A simple yet marvellous material

To the ancients, water must have seemed such a simple yet marvellous material - 
primordial, straightforward, life-giving, ubiquitous and, to them, elemental. 
Indeed, until we began looking more closely at its physical properties and the 
underlying physical chemistry, the hydrogen bonds, polarity and such it remained
that way.


Water is indeed a simple-seeming substance - a couple of hydrogen atoms stuck on
an oxygen making a boomerang shape. Couldn't really have been any more 
uncomplicated, really, straight perhaps. But, water is not, as any high school 
science student would hopefully be able to tell you. Up to a point it expands 
when it is cooled below 4 Celsius. It expands just enough to make the perfect 
Scotch on the rocks and to have left the Titanic in the same predicament.


"Water is also rather unusual in that unlike most other materials it exists in 
all three standard states of matter - solid, liquid and gas." 

Water is also rather unusual in that unlike most other materials it exists in 
all three standard states of matter - solid, liquid and gas - at temperatures 
that are not at all outside our everyday experience. The likes of carbon 
dioxide, common salt and egg white, just don't have that ability to flip between
states within a 100 degree range. Add to that the fact that it is far more 
viscous than other similarly sized molecules, it can readily be converted into 
that increasingly familiar supercritical fluid state for which chemists are 
finding green applications at every turn.


The list goes on.unexpectedly high heat capacity, solubilising capacity, 
hydrating ability. 

Microstructure of water

Much of water's anomalous behaviour boils down to the formation of hydrogen 
bonds between those dangling hydrogens on the boomerang tips and the oxygens on 
neighbouring molecules and the tiny clusters of water molecules that exist 
fleetingly in the liquid state but lost in the gas and frozen in the solid. 


In 1992, I reported on work from Sydney Benson and Eleanor Siebert of the 
University of Southern California at Los Angeles for New Scientist (see New 
Scientist archives). They used experimental data for ice and for pairs of water 
molecules in the gas phase to construct a theoretical model of liquid water. 
They claimed that the microstructure of water could help explain many of "Water 
still holds plenty of surprises for those scientists who keenly take to it." 

water's unusual properties. Their model help them envisage transient cubes of 
water molecules held together briefly in groups of three or more - with their 
hydrogen bonds breaking and reforming some 500 billion times a second. 

Where are the clues?

Later work provided further solid theoretical clues about water's hidden 
properties. David Clary and John Gregory of the chemistry department at 
University College London used quantum Monte Carlo methods to simulate millions 
of possible random configurations of water molecules and came up with a hexamer 
that would be plausible under Schr dinger's equation. While such theorising may 
ultimately lead to a way to predict the properties of water from first 
principles, since it is this molecular behaviour that gives rise to the bulk 
effects, water still holds plenty of surprises for those scientists who keenly 
take to it.


Xiao Cheng Zeng, Associate Professor of Chemistry at the University of Nebraska,
Lincoln, working with Kenichiro Koga of Fukuoka University of Education and 
Hideki Tanaka of Okayama University in Japan have found that they can make water
form a glass rather than ice crystals at -10 Celsius by confining it in a tiny 
slit just 1 nm across.

 

Amorphous structure of the water. Yellow dotted lines represent hydrogen-bonds, 
white circles hydrogen, and red circles oxygen. Adapted from Nature courtesy of 
Xiao Cheng Zeng.  

Three years ago, Zeng and Koga who was at the time a postdoctoral fellow at UNL,
and 'ice expert Tanaka' were using computer modelling to look at the way water 
changes when it is put under extremes of pressure. The model showed that rather 
than expanding on freezing water it can contract if it is squeezed at 493 
atmospheres at -40 Celsius between two hydrophobic plates held a nanometre 
apart. The model showed that water was freezing into ice crystals with a 
hexagonal structure where every water molecule is hydrogen bonded to its four 
nearest neighbours but rather than being in a three-dimensional lattice the 
crystals were planar. Zeng confesses that he figured Koga's model was simply 
incorrect, they were looking for water glass, or ice glass, and had stumbled 
across a new two-dimensional crystalline form instead. "We ran many, many trials
for about six months," Zeng says, "but we found the water froze into crystals 
and shrank every time."


Koga, Zeng and Tanaka were actually hoping to find a mixture of pentagons, 
hexagons and heptagons in the molecular structures of the water and thought it 
would be fairly easy to reproduce in the laboratory. But, it has taken three 
more years to come up with the real thing. 

Frustration was the answer

The trick that finally did it was to introduce 'frustration' into the process. 
This simply involved holding the two hydrophobic plates immobile while the water
was compressed and frozen. The effect was to totally inhibit the formation of a
true crystal and force the water to form a glass instead. It worked.


Zeng says he has nicknamed the new form of ice 'Nebraska' ice from the Otoe word
for 'flat water'. But, aside from an interesting addition to the list of 
water's bizarre behaviour is there likely to be any immediate applications? Zeng
does not think so, his reward, he says, is the simple joy of discovery. "Water 
is such a fundamental substance that it deserves a lot of attention and we want 
to E-mail this Article to a Friend

Type e-mail address then hit return: 


 
 
 

understand it from every aspect, from its nanoscale behaviour, from its 
molecular properties, and all the way up," he explains.


Maybe what we have learned so far about water is just the tip of the iceberg. 
Now, pass me that Scotch, with a touch of water.of course. 


For subscribers to Nature the url to the full article is 
http://www.nature.com/cgi- 
taf/DynaPage.taf?file=/nature/journal/v408/n6812/full/408564a0_fs. html 



I always fancied the idea of polywater and what it might be able to do. But, 
then I also quite like the idea of using chemistry to convert lead into gold, a 
money tree and the magic porridge pot. While, polywater may have turned out to 
be a lost cause, chemists have for many years unearthed some quite bizarre 
properties from the liquid of life, writes David Bradley.




--------------------------------------------------------------------------------


The discoveries about this elemental material continue to this day with a 
collaborative team from Japan and the US publishing results in Nature recently 
(30 November 2000) that show that water becomes a two-dimensional glass and 
shrinks under extreme pressure when cooled and confined. 

 A simple yet marvellous material

To the ancients, water must have seemed such a simple yet marvellous material - 
primordial, straightforward, life-giving, ubiquitous and, to them, elemental. 
Indeed, until we began looking more closely at its physical properties and the 
underlying physical chemistry, the hydrogen bonds, polarity and such it remained
that way.


Water is indeed a simple-seeming substance - a couple of hydrogen atoms stuck on
an oxygen making a boomerang shape. Couldn't really have been any more 
uncomplicated, really, straight perhaps. But, water is not, as any high school 
science student would hopefully be able to tell you. Up to a point it expands 
when it is cooled below 4 Celsius. It expands just enough to make the perfect 
Scotch on the rocks and to have left the Titanic in the same predicament.


"Water is also rather unusual in that unlike most other materials it exists in 
all three standard states of matter - solid, liquid and gas." 

Water is also rather unusual in that unlike most other materials it exists in 
all three standard states of matter - solid, liquid and gas - at temperatures 
that are not at all outside our everyday experience. The likes of carbon 
dioxide, common salt and egg white, just don't have that ability to flip between
states within a 100 degree range. Add to that the fact that it is far more 
viscous than other similarly sized molecules, it can readily be converted into 
that increasingly familiar supercritical fluid state for which chemists are 
finding green applications at every turn.


The list goes on.unexpectedly high heat capacity, solubilising capacity, 
hydrating ability. 

Microstructure of water

Much of water's anomalous behaviour boils down to the formation of hydrogen 
bonds between those dangling hydrogens on the boomerang tips and the oxygens on 
neighbouring molecules and the tiny clusters of water molecules that exist 
fleetingly in the liquid state but lost in the gas and frozen in the solid. 


In 1992, I reported on work from Sydney Benson and Eleanor Siebert of the 
University of Southern California at Los Angeles for New Scientist (see New 
Scientist archives). They used experimental data for ice and for pairs of water 
molecules in the gas phase to construct a theoretical model of liquid water. 
They claimed that the microstructure of water could help explain many of "Water 
still holds plenty of surprises for those scientists who keenly take to it." 

water's unusual properties. Their model help them envisage transient cubes of 
water molecules held together briefly in groups of three or more - with their 
hydrogen bonds breaking and reforming some 500 billion times a second. 

Where are the clues?

Later work provided further solid theoretical clues about water's hidden 
properties. David Clary and John Gregory of the chemistry department at 
University College London used quantum Monte Carlo methods to simulate millions 
of possible random configurations of water molecules and came up with a hexamer 
that would be plausible under Schr dinger's equation. While such theorising may 
ultimately lead to a way to predict the properties of water from first 
principles, since it is this molecular behaviour that gives rise to the bulk 
effects, water still holds plenty of surprises for those scientists who keenly 
take to it.


Xiao Cheng Zeng, Associate Professor of Chemistry at the University of Nebraska,
Lincoln, working with Kenichiro Koga of Fukuoka University of Education and 
Hideki Tanaka of Okayama University in Japan have found that they can make water
form a glass rather than ice crystals at -10 Celsius by confining it in a tiny 
slit just 1 nm across.

 

Amorphous structure of the water. Yellow dotted lines represent hydrogen-bonds, 
white circles hydrogen, and red circles oxygen. Adapted from Nature courtesy of 
Xiao Cheng Zeng.  

Three years ago, Zeng and Koga who was at the time a postdoctoral fellow at UNL,
and 'ice expert Tanaka' were using computer modelling to look at the way water 
changes when it is put under extremes of pressure. The model showed that rather 
than expanding on freezing water it can contract if it is squeezed at 493 
atmospheres at -40 Celsius between two hydrophobic plates held a nanometre 
apart. The model showed that water was freezing into ice crystals with a 
hexagonal structure where every water molecule is hydrogen bonded to its four 
nearest neighbours but rather than being in a three-dimensional lattice the 
crystals were planar. Zeng confesses that he figured Koga's model was simply 
incorrect, they were looking for water glass, or ice glass, and had stumbled 
across a new two-dimensional crystalline form instead. "We ran many, many trials
for about six months," Zeng says, "but we found the water froze into crystals 
and shrank every time."


Koga, Zeng and Tanaka were actually hoping to find a mixture of pentagons, 
hexagons and heptagons in the molecular structures of the water and thought it 
would be fairly easy to reproduce in the laboratory. But, it has taken three 
more years to come up with the real thing. 

Frustration was the answer

The trick that finally did it was to introduce 'frustration' into the process. 
This simply involved holding the two hydrophobic plates immobile while the water
was compressed and frozen. The effect was to totally inhibit the formation of a
true crystal and force the water to form a glass instead. It worked.


Zeng says he has nicknamed the new form of ice 'Nebraska' ice from the Otoe word
for 'flat water'. But, aside from an interesting addition to the list of 
water's bizarre behaviour is there likely to be any immediate applications? Zeng
does not think so, his reward, he says, is the simple joy of discovery. "Water 
is such a fundamental substance that it deserves a lot of attention and we want 
to E-mail this Article to a Friend

Type e-mail address then hit return: 


 
 
 

understand it from every aspect, from its nanoscale behaviour, from its 
molecular properties, and all the way up," he explains.


Maybe what we have learned so far about water is just the tip of the iceberg. 
Now, pass me that Scotch, with a touch of water.of course. 


For subscribers to Nature the url to the full article is 
http://www.nature.com/cgi- 
taf/DynaPage.taf?file=/nature/journal/v408/n6812/full/408564a0_fs. html 



------=_NextPart_000_00B0_01C0654E.91921BA0

 Content-Type: text/html;

[ AUTOMATICALLY SKIPPING HTML ENCODING! ] 

Rate This Message: http://www.cryonet.org/cgi-bin/rate.cgi?msg=15114