Post on 31-Dec-2015
description
Why Don't Alcohol and Water Mix Very Well?
“The molecular structure of Alcohol-water mixtures”
J.-H. GuoAdvanced Light Source, Lawrence Berkeley National Laboratory
Collaborators
Y. Luo, S. Kashtanov, & Hans Ågren (Theoretical Chemistry, Royal Institute of Technology)
A. Augustsson, J.-E. Rubensson, & J. Nordgren (Department of Physics, Uppsala University)
D. K. Shuh (Chemical Sciences Division, Lawrence Berkeley National Laboratory)
Molecules in gas and liquid phases
Small molecules can be studied in great detail in the gaseous phase, where molecular interactions can be neglected, and consequently both their geometric structure and electronic structure are often well known.
When the molecules interact in the liquid phase, our knowledge about these fundamental properties is very limited. The arrangement of the molecules change on a fast time scale: the geometry and the electronic structure of the molecules themselves vary, i.e., the properties of the individual molecules are constantly changing. Thus, from this perspective it is not surprising that there is still much to learn about common and simple liquids.
540535530525520515510Energy (eV)
1g-1
1u-1
3u-1
4g-1
CO2O-K emission
resonant O1s - * 535.0 eV
-1.0 eV
-1.5 eV
-1.75 eV
-2.0 eV
-2.3 eV
non-resonant551 eV
Skytt et al., Phys. Rev. Lett. 77, 5035 (1996).
Microscopic Mixing of Liquids
Solvation in aqueous solution has been a most intensive studied problem in chemical physics. The observed entropy increase upon mixing alcohol and water is much smaller than expected for an ideal solution.
The anomalously small entropy increase upon solution of alcohols in water is traditionally explained in terms of a hydrophobic interaction with the apolar alcohol headgroups, which induces an ice-like structure in the surrounding water [Frank et al., J. Chem. Phys. 13, 507 (1945).]
Early neutron diffraction data provides structure information of water cages around hydrophobic headgroups in solution [Soper et al., Phys. Rev. Lett. 71, 4346 (1993); Tsai et al., J. Chem. Phys. 104, 9417 (1996); Dixit et al., J. Phys. Condens. Matter 12, L323 (1999); Wakisaka et al., J. Mol. Liq. 90, 175–184 (2001).]
New neutron diffraction data demonstrated that incomplete mixing at the molecular level is essential to explain the negative excess entropy observed when methanol dissolves in water [Dixit et al., Nature 416, 829 (2002).]
We examine the influence of the intermolecular interaction on the local electronic structure of liquid methanol, water, and their solutions. Our study determines the molecular structure of both liquid methanol and water-methanol solutions in unprecedented detail, thus, forms the final leg of the "iceberg, cluster, molecular structure" story pertaining to alcohol-water solutions.
Methanol crystal: infinite hydrogen-bonded chains; liquid methanol: non consensus after decades of studies
The early hypothesis of cyclic structures by Pauling [L. Pauling, The Nature of the Chemical Bond , Cornell Univ. Press, 1960] has both been supported and contested by neutron diffraction analysis; the competing interpretation being that the majority of liquid molecules are ordered in chains with up to 10 members or linear trimer/tetramer chains
Based on neutron diffraction data, it was found experimentally:
chains up to ten molecules with average of six molecules in liquid methanol [Yamaguchi, K. Hidaka, and A.K. Soper, Molecular Physics 96, 1159 (1999)]; Haughney et al., J. Phys. Chem. 91, 4934 (1987); Svishchev et al., J. Chem. Phys. 100, 5165 (1994) claimed the same findings based on MD calculation;
Sarkar, S. & Joarder, R. N., J. Chem. Phys. 99, 2032 (1993) revealed a different picture of cyclic hexamers (six-rings);
Using the same diffraction data, Tanaka found linear trimer and tetramer chains [Bull. Chem. Soc. Jpn. 58, 270 (1985)]
Molecular structure in liquid methanol
Molecular structures in liquid methanolMolecular structures in liquid methanol
3 87654 9
3
87
654
9 10
chainschains
ringsrings
Soft-x-ray spectroscopy
.
h
h'
UnoccupiedMOs
OccupiedMOs
O 1s
Inte
nsit
y (a
.u)
540535530525520515Energy (eV)
XASXES4a1
2b2
3a1
1b2
1b1
Primer excitation: 10-18 sDe-excitation: 10-15 s
Wet samples in vacuum conditions
100nm Si3N4, ~4 µl liquid volume, 66% transmission @O1s, vacuum pressure < 1 x 10-9 Torr
grating
detector
slit
O-ring
Si3N
4
liquid
SR
PHIOCA: photon-in and photon-out chemical analysis
100
80
60
40
20
0
Tra
nsm
issi
on (
%)
1000800600400200Energy (eV)
O 1s (66%)
Fe 2p (82%)
C 1s (46%)
C_100nm; SiC_100nm Si_100nm; SiN_100nm Al_100nm
Inte
nsity
(a.
u.)
530525520515Energy (eV)
(a)
(b)
(c)
(d)
(e)
H2O molecule and liquid water
535530525520515Energy (eV)
water molecule liquid water
Theory
Experiment
1b1
3a1
1b2
1a1
1b1
3a1
1b2
2a1
Molecular orbitals
Hatree-Fock level with Sadlej basis set using the DALTON program on 32 nodes of the T3E computers at the NSC in Linköping
Guo et al., Phys. Rev. Lett. 89, 137402 (2002)
Finding: an electron sharing takes place between water molecules. Such a sharing mainly involves the so-called 3a1 orbital, which is a mixing of oxygen 2p and hydrogen 2s atomic orbitals.
Inte
nsit
y (a
.u.)
530525520515Energy (eV)
Resonant Non-resonant
SYM
A-ASYM
D-ASYM
Experiment540536532
O 1s gas water
2b24a1
liquid water
Hydrogen bonding structure in liquid water
4-HB
3-HB-O
3-HB-H
The X-ray emission spectra reveal the influence of hydrogen bonding on the local electronic structure of liquid water
Molecular structure in liquid methanol
Finding: The structure of liquid methanol at room temperature is a combination of rings and chains each made up of either 6 or 8 methanol molecules
Guo et al., Phys. Rev. Lett. 91, 157401 (10 Oct. 2003)
Inte
nsit
y (a
.u.)
528526524522520Energy (eV)
Calculated O K-emission of methanol chains
3
4
5
6
7
8
9
10
Inte
nsit
y (a
.u.)
532528524520516Energy (eV)
8-ring
6-ring
8-chain
6-chain
Theory
Experiment
O K-emission
B
C
A
560550540530
O 1s absorptionA
BC
530525520515Energy (eV)
IM + IW Methanol Water mixture
B
C
Oxygen K-emission
3a1
E1'
E2
E4
E1
1b1
1b2
E3
Incomplete mixing in alcohol-water solution
X-ray emission spectra of an equimolar mixture of methanol and water are compared to the spectra from the pure liquids. We find that a 1-to-1 combination of the pure liquid spectra reproduces the solution spectra to considerable detail. The spectra are very sensitive to the changes in the local electronic structure and this observation indicates incomplete mixing at the microscopic level.
However, there is a significant discrepancy (indicated by arrow) when the excitation energy is selected to emphasize the chain structures (spectrum B). The solution spectrum shows a relative intensity decrease in the E1' region, indicating a depletion of methanol chains in the solution.
difference
535530525520Energy (eV)
Oxygen RIXS
530.6 eV
532.5 eV
531.5 eV
533.5 eV
534.5 eV elastic peaks
544540536532528
A' CH3OH mixture H2O
O 1s A
B
RIXS of alcohol-water mixture
The narrow spectral feature shown in the resonant emission spectra holds the key for identifying the structures. Based on the simulations of resonant emission spectra of water and methanol in both gas and pure liquid phases, this narrow spectral feature can only be generated from the emission of a water molecule that is "isolated" from the rest of the water network. We also know that there must be an interaction between water and methanol chains because there is a depletion of methanol chains in the solution. This results in a significant reduction of the number or possible trial structures. The new structures in alcohol-water mixture must be responsible for the spectral profiles.
RIXS of liquid methanol and water
550540530520510500Energy (eV)
Prepeak
-1 eV
-1.5 eV
-2.5 eV
-3 eV
-4 eV
-5 eV
-7 eV
+3 eV
Normal
Water
Inte
nsit
y (a
.u.)
535530525520515Energy (eV)
O K-emissionMethanol
560.0 eV
537.0 eV
535.5 eV
534.5 eV
533.5 eV
532.5 eV
The RIXS spectra of liquid methanol and water under detuning conditions are different to their mixture
532530528526524522520Energy (eV)
Resonantly excited O K-emission
8-chain + 3-water
A'--
A'-
A'
E1
E3 E2
8-chain + 1-water 8-chain + 2-water
6-chain + 2-water 6-chain + 3-water 6-chain + 4-water
6-chain + 2-water
6-chain + 4-water
6-chain + 3-water
8-chain + 1-water
8-chain + 3-water
8-chain + 2-water
Molecular structure in alcohol-water mixture
Theoretical spectra of a methanol molecule in various methanol-water local structures are computed. The structures presented above must be responsible for the spectral profiles.
Summary
In liquid water: A strong involvement of a1-symmetry valence states in
the hydrogen bonding indicates there is electron sharing between water molecules
In liquid methanol: The molecules in the pure methanol liquid predominantly persist as hydrogen-bonded chains with 6 and/or 8 molecules, and as 6- and/or 8-molecule rings.
For an equimolar water-methanol mixture, water and methanol molecules are incomplete mixing at the microscopic level.
In addition, our results indicate a new mechanism for increasing order in the solution: water molecules bridge methanol chains to form rings with 6 and 8 methanol molecules.
Many vital chemical and biological processes take place in aqueous solutions. We believe that the techniques have great general potential to provide new and valuable information in the quest for the microscopic origin of the properties of liquids and solutions; in particular the RIXS, will open new research opportunities in physical chemistry, nanotechnology, as well as in biochemistry and biology.