Growing Crystals That Will Make Your Crystallographer Happy

Paul D. Boyle
ver 12/91

     Practically every chemist knows the necessity of recrystallization as
a method of purification.  What is less well known, however, is methods by which
"X-ray quality" crystals may be obtained.  The purpose of this monograph is to
briefly and informally outline some of the methods which can be used to obtain
single crystals suitable for X-ray diffraction studies.  This monograph is
meant neither to be rigorous nor exhaustive, but rather, a sort of practical
"how to" cookbook.

The Goal
     The goal in growing crystals for a single crystal X-ray diffraction
experiment is to grow single crystals (obviously) of suitable size.  The optimum
size for a crystal is one which has dimensions of 0.2 - 0.4 mm in at least two
of the three dimensions.  Most potential structure determinations are
thwarted by a lack of suitable crystals.

General Considerations
     The factors during crystal growth which affect the size of the crystals
are, solubility of compound in the solvent chosen for recrystallization, the
number of nucleation sites, mechanical agitation to the system, and time.
     Solvent.  Choose a solvent in which your compound is moderately soluble. 
If the solute is too soluble, this will result in small crystal size.  Avoid
solvents in which your compound forms supersaturated solutions.
supersatuated solutions tend to give crystals which are too small in size.
     Nucleation.  The fewer sites at which crystals begin to grow will result
in fewer crystals each of larger size.  This is desirable.  Conversely, many
nucleation sites results in a smaller average crystal size, and is not
desirable.  In many recrystallizations ambient dust in the laboratory provide
sites of nucleation.  It is important to minimize dust or other extraneous
particulate matter in the crystal growing vessel.
     Mechanics.  Mechanical disturbance of the crystal growing vessel
results in smaller crystals.  Let the crystals grow with a minimum of
disturbance.  This means:  Don't try to grow crystals next to your vacuum
pump, and don't  pick up the vessel everyday to check on how your crystals are
growing.  Set up the crystal growing attempt, in a quiet, out of the way place
and forget about it (if possible!) for a week.
     Time.  This is related to mechanics.  Crystals fully recognize that
patience is a virtue and will reward those who practice it.

Techniques
     Crystal growing is an art, and there are as many variations to the basic
crystal growing recipes as there are crystallographers.  The recipes given
below are ones which I have either tried or I have read about and sound
reasonable.  The techniques chosen will largely depend on the chemical
properties of the compound of interest:  Is the compound air sensitive,
moisture sensitive?  Is it hygroscopic? etc. etc.
     Slow Evaporation.  This is the simplest way to grow crystals and works
best for compounds which are not sensitive to ambient conditions in the
laboratory.  Prepare a solution of the compound in a suitable solvent.  The
solution should be saturated or nearly saturated.  Transfer the solution to
a CLEAN crystal growing dish and cover.  The covering for the container should
not be air tight.  Aluminium foil with some holes poked in it works well, or a
flat piece of glass with microscope slides used as a spacer also will do the
trick.  Place the container in a quiet out of the way place and let it
evaporate. This method works best where there is enough material to saturate
at least a few milliliters of solvent.
     Slow Cooling.  This is good for solute-solvent systems which are less
than moderately soluble and the solvent's boiling point is less than 100ø C. 
Prepare a saturated solution of the compound where is the solvent is heated
to just it's boiling point or a just below it.  Transfer the solution to a CLEAN
large test tube and stopper.  Transfer the test tube to a Dewar flask in which
hot water (heated to a temperature of a couple of degrees below the solvent
boiling point).  The water level should exceed the solvent level in the test
tube, but should not exceed the height of the test tube.  Stopper the Dewar
flask with a cork stopper and let the vessel sit for a week.  A more elaborate
version of this involves a thermostated oven rather than a Dewar flask.
     Variations on Slow Evaporation and Slow Cooling.  If the above two
techniques do yield suitable crystals from single solvent systems, one may
expand these techniques to binary or tertiary solvent systems.  The basic
rationale for this is by varying the solvent composition one  may inhibit
growth of certain crystal faces and promote the growth of other faces,
yielding crystals of suitable morphology and size. If you choose this route for
growing crystals, it absolutely necessary to record the solvent composition
you use!  If crystal growing is an art, growing crystals from binary or
tertiary solvent mixtures is that much more imprecise.  Remember
reproducibility is paramount in science.
     Vapour Diffusion. (excerpted and paraphrased from Stout and Jensen p.
65).  This method is good for milligram amounts of material.  A solution of the
substance is prepared using solvent S1 and placed in test tube T. A second
solvent, S2, is placed in a closed beaker, B. S2 is chosen such that when mixed
with S1 the solute will become less soluble.  The test tube containing S1 is
then placed in the beaker and the beaker is sealed.  Slow diffusion of S2 into
T and S1 out of T will cause crystals to form.  If S2 is more volatile than S1
the solvent level will increase and prevent microcrystalline crusts from
forming on the sides of T.
     Solvent Diffusion (Layering Technique).  This method also is good for
milligram amounts of materials which are sensitive to ambient laboratory
conditions (air, moisture).  Dissolve the solute in S1 and place in a test tube.
SLOWLY dribble S2 into the tube so that S1 and S2 form discreet layers.  This
will only be successful if 1) The density of S2<S1 and 2) Care is exercised in
creating the solvent layer.  I have found that a syringe is the best way to add
the second solvent.  The narrower the tube , the easier it is to build up the
layer. Five millimetre NMR tubes are excellent vessels to use for this crystal
growing technique.  CH2Cl2/Et2O is a good solvent combination to try this
method (if your compound is insoluble in ether).
     Reactant diffusion.  This similar to the other diffusion methods except
that solutions of the reactants are allowed to diffuse into one another.  If
the product of the reaction is insoluble, crystals of the product will form
where the reactants mix.  There is mention in the literature of this technique
being used with diffusion in silica gels (see Acta. Cryst. 19, 483, (1965)).
     Sublimation.  The most important factor here is rate of sublimation.  To
get good sized crystals, the sublimation should be done slowly.
     Convection. One may attempt to grow crystals by convection by creating
a thermal gradient in the crystal growing vessel.  The idea behind this method
is that the solution becomes more saturated in the warm part of the vessel
and is transferred to the cooler region where nucleation and crystal growth
occur.  To create the convection one may use either local heating or local
cooling.  The velocity of the convection current is proportional to the thermal
gradient across the vessel. Care must be taken to not make the gradient too
large, or the convection will be too rapid and inhibit crystal growth.
     To use local cooling, simply take a flat bottomed crystal growing dish
(similar to what one would use for slow evaporation) and place one side of it
against the heat sink.  Normally, simply placing the vessel against a cold
outside window will suffice.  Notice that the heat sink needs to be against the
side of the vessel.  Laying the vessel on a cool surface will not induce
convection.
     A Thiele tube with a resistive heater attached to it makes a good
apparatus to grow crystals by local heating convection. The solvent flow
should be in the bottom sidearm and out the top side arm.  If you need or want
to use this method, see me for the details.   
     Co-crystallants.  If you are not getting suitable crystals from other
crystallization methods, you can try to cocrystallize your compound with a
"crystallization aid".  In the literature (see J. Amer. Chem. Soc. 1988, 110, 639-
640) triphenylphosphine oxide (TPPO) has been used as a cocrystallant for
organic molecules which are proton donors.  Obviously, this method of
crystallization is not for all compounds, but for those it is, the results may
be rewarding.  Essentially  this method of crystal growing is the same as slow
evaporation except that an equimolar amount of TPPO is added to the solution. 
I suppose that the other crystallization methods outlined above would also
work with this method.
     Counterions.  If your compound is ionic, and is not giving suitable
crystals with a given counterion, perform a metathesis reaction to change the
counterion.  Very often the crystal quality will improve when a different
counterion used.  Ions of similar size tend to pack together better and
subsequently give better crystals.  In addition, you might also get more
desirable physical properties for your crystal.  For example, the sodium salt
of your compound might be hygroscopic, but the tetramethyl ammonium salt
might not be or at least, less so.  When selecting possible counterions, avoid
ions which contain large non-rigid groups (like tetrabutyl ammonium).  Use ions
which have very limited conformational flexibility.  A word of warning:  Make
sure that whatever ion use for your metathesis does not react with your ion
of interest.

I hope this compilation of crystal growing techniques proves to be useful.  It's
generally not possible to predict which method will work best for a given
compound; choose the method which sounds appealing to you and try it.  You will
save yourself a lot of time if you do purification recrystallizations before
attempting to grow single crystals of the material.  If you are sure your
compound is pure and a crystal growing technique is not giving suitable
crystals change the solvent or the method.  If one system does not yield
suitable crystal after a couple of tries it is not going to yield good crystals
after the tenth or hundredth time. Be intuitive, imaginative, but above all
else stick to the basics - no dust, disturbance and a lot of patience.
   
References
Stout and Jensen, X-ray Structure Determination A Practical Guide

Skoog and West, Fundamentals of Analytical Chemistry, 3rd. Ed.