Crystallization or crystallisation is the (natural or artificial) process by which a solid forms, where the atoms or molecules are highly organized into a structure known as a crystal. Some of the ways by which crystals form are precipitating from a solution, freezing, or more rarely deposition directly from a gas. Attributes of the resulting crystal depend largely on factors such as temperature, air pressure, and in the case of liquid crystals, time of fluid evaporation.
Crystallization occurs in two major steps. The first is nucleation, the appearance of a crystalline phase from either a supercooled liquid or a supersaturated solvent. The second step is known as crystal growth, which is the increase in the size of particles and leads to a crystal state. An important feature of this step is that loose particles form layers at the crystal's surface lodge themselves into open inconsistencies such as pores, cracks, etc.
The majority of minerals and organic molecules crystallize easily, and the resulting crystals are generally of good quality, i.e. without visible defects. However, larger biochemical particles, like proteins, are often difficult to crystallize. The ease with which molecules will crystallize strongly depends on the intensity of either atomic forces (in the case of mineral substances), intermolecular forces (organic and biochemical substances) or intramolecular forces (biochemical substances).
Crystallization is also a chemical solid–liquid separation technique, in which mass transfer of a solute from the liquid solution to a pure solid crystalline phase occurs. In chemical engineering, crystallization occurs in a crystallizer. Crystallization is therefore related to precipitation, although the result is not amorphous or disordered, but a crystal.
Process
The crystallization process consists of two major events, nucleation and crystal growth which are driven by thermodynamic properties as well as chemical properties.
In crystallization Nucleation is the step where the solute molecules or atoms dispersed in the solvent
start to gather into clusters, on the microscopic scale (elevating
solute concentration in a small region), that become stable under the
current operating conditions. These stable clusters constitute the
nuclei. Therefore, the clusters need to reach a critical size in order
to become stable nuclei. Such critical size is dictated by many
different factors (temperature, supersaturation, etc.). It is at the stage of nucleation that the atoms or molecules arrange in a defined and periodic manner that defines the crystal structure
— note that "crystal structure" is a special term that refers to the
relative arrangement of the atoms or molecules, not the macroscopic
properties of the crystal (size and shape), although those are a result
of the internal crystal structure.
The crystal growth is the subsequent size increase of the
nuclei that succeed in achieving the critical cluster size. Crystal
growth is a dynamic process occurring in equilibrium where solute
molecules or atoms precipitate out of solution, and dissolve back into
solution. Supersaturation is one of the driving forces of
crystallization, as the solubility of a species is an equilibrium
process quantified by Ksp. Depending upon the conditions, either nucleation or growth may be predominant over the other, dictating crystal size.
Many compounds have the ability to crystallize with some having different crystal structures, a phenomenon called polymorphism. Certain polymorphs may be metastable,
meaning that although it is not in thermodynamic equilibrium, it is
kinetically stable and requires some input of energy to initiate a
transformation to the equilibrium phase. Each polymorph is in fact a
different thermodynamic solid state and crystal polymorphs of the same
compound exhibit different physical properties, such as dissolution
rate, shape (angles between facets and facet growth rates), melting
point, etc. For this reason, polymorphism is of major importance in
industrial manufacture of crystalline products. Additionally, crystal
phases can sometimes be interconverted by varying factors such as
temperature, such as in the transformation of anatase to rutile phases of titanium dioxide.
In nature
There are many examples of natural process that involve crystallization.
Geological time scale process examples include:
- Natural (mineral) crystal formation (see also gemstone);
- Stalactite/stalagmite, rings formation.
Human time scale process examples include:
- Snow flakes formation;
- Honey crystallization (nearly all types of honey crystallize).
Methods
Crystal
formation can be divided into two types, where the first type of
crystals are composed of a cation and anion, also known as a salt, such
as sodium acetate. The second type of crystals are composed of uncharged species, for example menthol.
Crystal formation can be achieved by various methods, such as:
cooling, evaporation, addition of a second solvent to reduce the
solubility of the solute (technique known as antisolvent or drown-out), solvent layering, sublimation, changing the cation or anion, as well as other methods.
The formation of a supersaturated solution does not guarantee
crystal formation, and often a seed crystal or scratching the glass is
required to form nucleation sites.
A typical laboratory technique for crystal formation is to dissolve the solid in a solution in which it is partially soluble, usually at high temperatures to obtain supersaturation. The hot mixture is then filtered to remove any insoluble impurities. The filtrate is allowed to slowly cool. Crystals that form are then filtered and washed with a solvent in which they are not soluble, but is miscible with the mother liquor. The process is then repeated to increase the purity in a technique known as recrystallization.
For biological molecules in which the solvent channels continue to be present to retain the three dimensional structure intact, microbatch crystallization under oil and vapor diffusion methods have been the common methods.
Typical equipment
Equipment for the main industrial processes for crystallization.
- Tank crystallizers. Tank crystallization is an old method still used in some specialized cases. Saturated solutions, in tank crystallization, are allowed to cool in open tanks. After a period of time the mother liquor is drained and the crystals removed. Nucleation and size of crystals are difficult to control. Typically, labor costs are very high.
Thermodynamic view
The crystallization process appears to violate the second principle of thermodynamics.
Whereas most processes that yield more orderly results are achieved by
applying heat, crystals usually form at lower temperatures—especially by
supercooling.
However, due to the release of the heat of fusion during
crystallization, the entropy of the universe increases, thus this
principle remains unaltered.
The molecules within a pure, perfect crystal, when heated
by an external source, will become liquid. This occurs at a sharply
defined temperature (different for each type of crystal). As it
liquifies, the complicated architecture of the crystal collapses.
Melting occurs because the entropy (S) gain in the system by spatial randomization of the molecules has overcome the enthalpy (H) loss due to breaking the crystal packing forces:
Regarding crystals, there are no exceptions to this rule. Similarly,
when the molten crystal is cooled, the molecules will return to their
crystalline form once the temperature falls beyond the turning point.
This is because the thermal randomization of the surroundings
compensates for the loss of entropy that results from the reordering of
molecules within the system. Such liquids that crystallize on cooling
are the exception rather than the rule.
The nature of a crystallization process is governed by both
thermodynamic and kinetic factors, which can make it highly variable and
difficult to control. Factors such as impurity level, mixing regime,
vessel design, and cooling profile can have a major impact on the size,
number, and shape of crystals produced.
Dynamics
As
mentioned above, a crystal is formed following a well-defined pattern,
or structure, dictated by forces acting at the molecular level. As a
consequence, during its formation process the crystal is in an environment where the solute concentration reaches a certain critical value, before changing status. Solid formation, impossible below the solubility threshold at the given temperature and pressure
conditions, may then take place at a concentration higher than the
theoretical solubility level. The difference between the actual value of
the solute concentration at the crystallization limit and the
theoretical (static) solubility threshold is called supersaturation and is a fundamental factor in crystallization.
Nucleation
Nucleation is the initiation of a phase change in a small region,
such as the formation of a solid crystal from a liquid solution. It is a
consequence of rapid local fluctuations on a molecular scale in a
homogeneous phase that is in a state of metastable equilibrium. Total
nucleation is the sum effect of two categories of nucleation – primary
and secondary.
Primary nucleation
Primary
nucleation is the initial formation of a crystal where there are no
other crystals present or where, if there are crystals present in the
system, they do not have any influence on the process. This can occur in
two conditions. The first is homogeneous nucleation, which is
nucleation that is not influenced in any way by solids. These solids
include the walls of the crystallizer vessel and particles of any
foreign substance. The second category, then, is heterogeneous
nucleation. This occurs when solid particles of foreign substances cause
an increase in the rate of nucleation that would otherwise not be seen
without the existence of these foreign particles. Homogeneous nucleation
rarely occurs in practice due to the high energy necessary to begin
nucleation without a solid surface to catalyse the nucleation.
Primary nucleation (both homogeneous and heterogeneous) has been modelled with the following:
where
- B is the number of nuclei formed per unit volume per unit time,
- N is the number of nuclei per unit volume,
- kn is a rate constant,
- c is the instantaneous solute concentration,
- c* is the solute concentration at saturation,
- (c − c*) is also known as supersaturation,
- n is an empirical exponent that can be as large as 10, but generally ranges between 3 and 4.
Secondary nucleation
Secondary nucleation is the formation of nuclei attributable to the influence of the existing microscopic crystals in the magma. Simply put, secondary nucleation is when crystal growth is initiated with contact of other existing crystals or "seeds".
The first type of known secondary crystallization is attributable to
fluid shear, the other due to collisions between already existing
crystals with either a solid surface of the crystallizer or with other
crystals themselves. Fluid-shear nucleation occurs when liquid travels
across a crystal at a high speed, sweeping away nuclei that would
otherwise be incorporated into a crystal, causing the swept-away nuclei
to become new crystals. Contact nucleation has been found to be the most
effective and common method for nucleation. The benefits include the
following:
- Low kinetic order and rate-proportional to supersaturation, allowing easy control without unstable operation.
- Occurs at low supersaturation, where growth rate is optimal for good quality.
- Low necessary energy at which crystals strike avoids the breaking of existing crystals into new crystals.
- The quantitative fundamentals have already been isolated and are being incorporated into practice.
The following model, although somewhat simplified, is often used to model secondary nucleation:
where
- k1 is a rate constant,
- MT is the suspension density,
- j is an empirical exponent that can range up to 1.5, but is generally 1,
- b is an empirical exponent that can range up to 5, but is generally 2.
Growth
Once the first small crystal, the nucleus, forms it acts as a convergence point (if unstable due to supersaturation) for molecules
of solute touching – or adjacent to – the crystal so that it increases
its own dimension in successive layers. The pattern of growth resembles
the rings of an onion, as shown in the picture, where each colour
indicates the same mass of solute; this mass creates increasingly thin
layers due to the increasing surface area of the growing crystal. The
supersaturated solute mass the original nucleus may capture in a time unit is called the growth rate expressed in kg/(m2*h), and is a constant specific to the process. Growth rate is influenced by several physical factors, such as surface tension of solution, pressure, temperature, relative crystal velocity in the solution, Reynolds number, and so forth.
The main values to control are therefore:
- Supersaturation value, as an index of the quantity of solute available for the growth of the crystal;
- Total crystal surface in unit fluid mass, as an index of the capability of the solute to fix onto the crystal;
- Retention time, as an index of the probability of a molecule of solute to come into contact with an existing crystal;
- Flow pattern, again as an index of the probability of a molecule of solute to come into contact with an existing crystal (higher in laminar flow, lower in turbulent flow, but the reverse applies to the probability of contact).
The first value is a consequence of the physical characteristics of
the solution, while the others define a difference between a well- and
poorly designed crystallizer.
Size distribution
The
appearance and size range of a crystalline product is extremely
important in crystallization. If further processing of the crystals is
desired, large crystals with uniform size are important for washing,
filtering, transportation, and storage, because large crystals are
easier to filter out of a solution than small crystals. Also, larger
crystals have a smaller surface area to volume ratio, leading to a
higher purity. This higher purity is due to less retention of mother liquor
which contains impurities, and a smaller loss of yield when the
crystals are washed to remove the mother liquor. In special cases, for
example during drug manufacturing in the pharmaceutical industry, small
crystal sizes are often desired to improve drug dissolution rate and
bio-availability. The theoretical crystal size distribution can be
estimated as a function of operating conditions with a fairly
complicated mathematical process called population balance theory (using
population balance equations).
Main crystallization processes
Some of the important factors influencing solubility are:
- Concentration
- Temperature
- Solvent mixture composition
- Polarity
- Ionic strength
So one may identify two main families of crystallization processes:
- Cooling crystallization
- Evaporative crystallization
This division is not really clear-cut, since hybrid systems exist, where cooling is performed through evaporation, thus obtaining at the same time a concentration of the solution.
A crystallization process often referred to in chemical engineering is the fractional crystallization. This is not a different process, rather a special application of one (or both) of the above.
Cooling crystallization
Application
Most chemical compounds, dissolved in most solvents, show the so-called direct solubility that is, the solubility threshold increases with temperature.
So, whenever the conditions are favorable, crystal formation results from simply cooling the solution. Here cooling is a relative term: austenite crystals in a steel form well above 1000 °C. An example of this crystallization process is the production of Glauber's salt, a crystalline form of sodium sulfate. In the diagram, where equilibrium temperature is on the x-axis and equilibrium concentration (as mass percent of solute in saturated solution) in y-axis, it is clear that sulfate solubility quickly decreases below 32.5 °C. Assuming a saturated solution at 30 °C, by cooling it to 0 °C (note that this is possible thanks to the freezing-point depression), the precipitation of a mass of sulfate occurs corresponding to the change in solubility from 29% (equilibrium value at 30 °C) to approximately 4.5% (at 0 °C) – actually a larger crystal mass is precipitated, since sulfate entrains hydration water, and this has the side effect of increasing the final concentration.
There are limitations in the use of cooling crystallization:
- Many solutes precipitate in hydrate form at low temperatures: in the previous example this is acceptable, and even useful, but it may be detrimental when, for example, the mass of water of hydration to reach a stable hydrate crystallization form is more than the available water: a single block of hydrate solute will be formed – this occurs in the case of calcium chloride);
- Maximum supersaturation will take place in the coldest points. These may be the heat exchanger tubes which are sensitive to scaling, and heat exchange may be greatly reduced or discontinued;
- A decrease in temperature usually implies an increase of the viscosity of a solution. Too high a viscosity may give hydraulic problems, and the laminar flow thus created may affect the crystallization dynamics.
- It is not applicable to compounds having reverse solubility, a term to indicate that solubility increases with temperature decrease (an example occurs with sodium sulfate where solubility is reversed above 32.5 °C).
Cooling crystallizers
The simplest cooling crystallizers are tanks provided with a mixer
for internal circulation, where temperature decrease is obtained by
heat exchange with an intermediate fluid circulating in a jacket. These
simple machines are used in batch processes, as in processing of pharmaceuticals and are prone to scaling. Batch processes normally provide a relatively variable quality of the product along with the batch.
The Swenson-Walker crystallizer is a model, specifically
conceived by Swenson Co. around 1920, having a semicylindric horizontal
hollow trough in which a hollow screw
conveyor or some hollow discs, in which a refrigerating fluid is
circulated, plunge during rotation on a longitudinal axis. The
refrigerating fluid is sometimes also circulated in a jacket around the
trough. Crystals precipitate on the cold surfaces of the screw/discs,
from which they are removed by scrapers and settle on the bottom of the
trough. The screw, if provided, pushes the slurry towards a discharge
port.
A common practice is to cool the solutions by flash evaporation: when a liquid at a given T0 temperature is transferred in a chamber at a pressure P1 such that the liquid saturation temperature T1 at P1 is lower than T0, the liquid will release heat according to the temperature difference and a quantity of solvent, whose total latent heat of vaporization equals the difference in enthalpy. In simple words, the liquid is cooled by evaporating a part of it.
In the sugar industry, vertical cooling crystallizers are used to exhaust the molasses in the last crystallization stage downstream of vacuum pans, prior to centrifugation. The massecuite enters the crystallizers at the top, and cooling water is pumped through pipes in counterflow.
Evaporative crystallization
Another
option is to obtain, at an approximately constant temperature, the
precipitation of the crystals by increasing the solute concentration
above the solubility threshold. To obtain this, the solute/solvent mass
ratio is increased using the technique of evaporation. This process is insensitive to change in temperature (as long as hydration state remains unchanged).
All considerations on control of crystallization parameters are the same as for the cooling models.
Evaporative crystallizers
Most industrial crystallizers are of the evaporative type, such as the very large sodium chloride and sucrose units, whose production accounts for more than 50% of the total world production of crystals. The most common type is the forced circulation (FC) model. A pumping device (a pump or an axial flow mixer) keeps the crystal slurry in homogeneous suspension throughout the tank, including the exchange surfaces; by controlling pump flow,
control of the contact time of the crystal mass with the supersaturated
solution is achieved, together with reasonable velocities at the
exchange surfaces. The Oslo, mentioned above, is a refining of the
evaporative forced circulation crystallizer, now equipped with a large
crystals settling zone to increase the retention time (usually low in
the FC) and to roughly separate heavy slurry zones from clear liquid.
Evaporative crystallizers tend to yield larger average crystal size and
narrows the crystal size distribution curve.
DTB crystallizer
Whichever the form of the crystallizer, to achieve an effective process control
it is important to control the retention time and the crystal mass, to
obtain the optimum conditions in terms of crystal specific surface and
the fastest possible growth. This is achieved by a separation – to put
it simply – of the crystals from the liquid mass, in order to manage the
two flows in a different way. The practical way is to perform a gravity
settling
to be able to extract (and possibly recycle separately) the (almost)
clear liquid, while managing the mass flow around the crystallizer to
obtain a precise slurry density elsewhere. A typical example is the DTB (Draft Tube and Baffle)
crystallizer, an idea of Richard Chisum Bennett (a Swenson engineer and
later President of Swenson) at the end of the 1950s. The DTB
crystallizer (see images) has an internal circulator, typically an axial
flow mixer – yellow – pushing upwards in a draft tube while outside the
crystallizer there is a settling area in an annulus; in it the exhaust
solution moves upwards at a very low velocity, so that large crystals
settle – and return to the main circulation – while only the fines,
below a given grain size are extracted and eventually destroyed by
increasing or decreasing temperature, thus creating additional
supersaturation. A quasi-perfect control of all parameters is achieved
as DTF crystallizers offer superior control over crystal size and
characteristics.
This crystallizer, and the derivative models (Krystal, CSC, etc.) could
be the ultimate solution if not for a major limitation in the
evaporative capacity, due to the limited diameter of the vapour head and
the relatively low external circulation not allowing large amounts of
energy to be supplied to the system.