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The '''Maier-Saupe model''' is widely used as a model of the [[nematic phase]].<br />
The Maier-Saupe model is based on long-range dispersion forces, and has the form<br />
:<math>U (\cos \theta) = \overline u_2 \overline P_2 P_2 (\cos \theta)</math><br />
where <math>\theta</math> is the angle between the molecular symmetry axis and the [[director]]. <math>\overline P_2</math><br />
is the [[Order parameters | uniaxial order parameter]].<br />
Maier and Saupe Theory<br />
Aim is to calculate S as function of T.<br />
Maier and Saupe (1960) anisotropic attraction<br />
Onsager (1949) anisotropic repulsion<br />
We will look at MS theory and then consider its strengths and weaknesses.<br />
(i)<br />
Simplest attractive interaction between two polarizable rods. Instantaneous dipole interacts with induced dipole.<br />
⎟⎠⎞⎜⎝⎛−=21cos23)(),(12212121212ββrurU<br />
β12<br />
2<br />
1<br />
r12<br />
(ii)<br />
Too difficult to consider interaction of every molecule with every other molecule so we construct an average potential energy function that one molecule feels due to immersion in a sea of other similar molecules. Mean field approximation. )(cos)(21cos23)(1)()(21cos23)(222222iiiiiiiiPVASUVASUVUSUUββββββββ−=⎟⎠⎞⎜⎝⎛−−=∝∝⎟⎠⎞⎜⎝⎛−−∝<br />
i.e. potential proportional to cos squared of angle<br />
and order parameter<br />
and density squared<br />
n<br />
βi<br />
A defines strength of potential. Ignores fluctuations and SRO<br />
(iv)<br />
Now calculate orientational distribution function: angle. azimuthal theis and director theand axis longmolecular ebetween th anglepolar theis wheresin where1)(020)()(αβαβββππββddeZeZfiiTkUTkUiBiiBii∫∫−−==<br />
(v)<br />
The order parameter can now be calculated using the method outlined in lecture 2. The order parameter is just the average value of )(cos2β<br />
P. That is)cos(2βPS=.<br />
In more detail… αβββαββββαββββππππππddTkVASPddPTkVASPddPfSBBsin)(cosexpsin)(cos)(cosexpsin)(cos)(020220220220220∫∫∫∫∫∫⎟⎟⎠⎞⎜⎜⎝⎛⎟⎟⎠⎞⎜⎜⎝⎛==<br />
This is just an equation with S on both sides. It is tricky to solve because S appears within an integral but solutions can be found using the following method. ()()ATkmVSTkVASmdxmxdxxmxSdxTkVxASPdxxPTkVxASPSdxTkVxASPdxxPTkVxASPSBBBBBB221022102102221022112221122or where21expexp23)(exp)()(exp)(exp)()(exp==−=∴⎟⎟⎠⎞⎜⎜⎝⎛⎟⎟⎠⎞⎜⎜⎝⎛=⎟⎟⎠⎞⎜⎜⎝⎛⎟⎟⎠⎞⎜⎜⎝⎛=∫∫∫∫∫∫−−<br />
(vi)<br />
Two simultaneous equations in S and m. Integral may be done numerically and equations solved “graphically”. Slope of straight line is proportional to T.<br />
The results are:<br />
Tmax<br />
0<br />
T<br />
S<br />
m<br />
low T<br />
high T<br />
1<br />
-0.5<br />
S<br />
)/(22284.02maxBkVAT×=<br />
At high T (ie T > Tmax) there is only 1 solution, S = 0<br />
At low T (ie T < Tmax) there are 3 self consistent solutions. S=0, S>0 and S<0<br />
(vii)<br />
Which one has lowest free energy? The one with lowest free energy! Use : Helmholtz free energy = energy – T × entropy Σ<br />
−=TU<br />
Recall from Statistical Mechanics:<br />
Probability of the system being in a state with energy Er : 1 and ==Σ−rrTkErPZePBr mean energy of system, UrrrEPΣ= entropy of system, rrrBPPklnΣ−=Σ<br />
(viii)<br />
Average energy of a molecule : )(cosS using and function,on distributi over the averagean represent where)(cos)(cos)(2222222ββββPVASPVASPVASUUii=−=−=−== Energy of phase of N molecules: 2221VASNU−= (Note the half)<br />
(ix)<br />
Entropy of a molecule is –kB times average of ln(distribution): ZkTUfkBiiBiln)(ln+=−=Σβ from (iv) Entropy of N average molecules: ⎟⎟⎠⎞⎜⎜⎝⎛−=−=Σ−=+−=+=Σ=ΣZTkVASNZTNkVASNTUFZNkTVASNZNkTUNNBBBBiiln21ln21lnln222222 Unfortunately, this too must be evaluated numerically: For each value of S find m then calculate Z<br />
ddmPZβββππsin))(cosexp( where0202∫∫−= Iit turns out that for BkVAT222019.0< the positive S solution has the lowest free energy. Hence BNIT22019.0=<br />
1<br />
-0.5<br />
T<br />
0.43<br />
0<br />
Tmax<br />
S<br />
S decreases steadily as T is increased until it suddenly drops to zero at TNI .<br />
(x)<br />
TNI is less than TMAX so have first order transition.<br />
43.0)(22019.02==NIBNITSkVATA reasonable value compared with experiment.<br />
1-K Joules 5.3Joules 5.3=ΔΣ×=ΔNININITU Much weaker than crystal to liquid transition<br />
Strong angle dependant attraction (large A) increases TNI.<br />
Dilution (increasing V) decreases TNI.<br />
Why does it work? We have neglected the shape completely but it seems to give reasonable values.<br />
<br />
<br />
==References==<br />
#W. Maier and A. Saupe "EINE EINFACHE MOLEKULARE THEORIE DES NEMATISCHEN KRISTALLINFLUSSIGEN ZUSTANDES", Zeitschrift für Naturforschung A '''13''' pp. 564- (1958)<br />
#W. Maier and A. Saupe "EINE EINFACHE MOLEKULAR-STATISTISCHE THEORIE DER NEMATISCHEN KRISTALLINFLUSSIGEN PHASE .1", Zeitschrift für Naturforschung A '''14''' pp. 882- (1959)<br />
#W. Maier and A. Saupe "EINE EINFACHE MOLEKULAR-STATISTISCHE THEORIE DER NEMATISCHEN KRISTALLINFLUSSIGEN PHASE .2", Zeitschrift für Naturforschung A '''15''' pp. 287- (1960)<br />
#[http://dx.doi.org/10.1088/0022-3719/6/20/005 P A Vuillermot and M V Romerio "Exact solution of the Maier-Saupe model for a nematic liquid crystal on a one-dimensional lattice", Journal of Physics C: Solid State Physics '''6''' pp. 2922-2930 (1973)]<br />
#[http://dx.doi.org/10.1038/267412b0 G. R. LUCKHURST and C. ZANNONI "Why is the Maier−Saupe theory of nematic liquid crystals so successful?", Nature '''267''' pp. 412 - 414 (1977)]<br />
[[category: models]]<br />
[[category:liquid crystals]]</div>86.160.170.7