Gravitational phenomena, including convection, sedimentation, and interactions of materials with their containers all affect the crystal growth process. If they are not taken into consideration they can have adverse effects on the quantity and quality of crystals produced. As a practical matter, convection, and sedimentation can be completely eliminated only under conditions of low gravity attained during orbital flight. There is, then, an advantage to effecting crystallization in space. In the absence of convection in a microgravity environment cooling proceeds by thermal diffusion from the walls to the center of the solution chamber. This renders control of nucleation difficult. Accordingly, there is a need for a new improved nucleation process in space. Crystals are nucleated by creating a small localized region of high relative supersaturation in a host solution at a lower degree of supersaturation

Kroes, Roger L.

Lehoczky, Sandor L.

Reiss, Donald A.

English

NASA Technical Reports Server

I11111 11ll1ll11 Il11 Il11 Il11 111l Il11 lllll Il11 11111 1111l111111l1111 
United States Patent 
- _ _  
US005 173087A 
1111 Patent Number: 5,173,087 
Kroes et al. [45] Date of Patent: Dec. 22, 1992 
CRYSTAL GROWTH IN A MICROGRAVI’IY 
ENVIRONMENT 
Inventors: Roger L. Kroes; Donald A. Reiss; 
Sandor L. Lehoczky, all of 
Huntsville, Ala. 
Assignee: The United States of America as 
represented by the Administrator of 
the National Aeronautics and Space 
Administration, Washington, D.C. 
Appl. NO.: 717,447 
Filed: Jun. 19,1991 
Int. c 1 . 5  ............................................... BOlD 9/02 
U.S. c1. .................................... 23/295 R 23/300, 
156DIG. 62 
Field of Search ............. 23/295 R, 300; 156/621, 
156DIG. 62: 422/245 
References Cited 
U.S. PATENT DOCUMENTS 
2,591,067 2/1952 Hermann ............................. 422/245 
3,941,648 3/1976 Blank ................................... 422/245 
4,917,707 4/1990 Claramonte et al. ....... 156DIG.  62 
4,919,900 4/1990 Martin et al. ............... 156DIG.  62 
OTHER PUBLICATIONS 
Kirk Othmer Encyclopedia of Chemical Technology, 3rd 
Ed., vol. 7, John Wiley & Sons, 1979 pp. 243-251. 
Primary Examiner-Gary P. Straub 
Assistant Examiner-Stephen G. Kalinchak 
Attorney, Agent, or Firm-Robert L. Broad, Jr.; Guy M. 
Miller; John R. Manning 
1571 ABSTRACT 
Gravitational phenomena, including convection, sedi- 
mentation, and interactions of materials with their con- 
tainers all affect the crystal growth process. If they are 
not taken into consideration they can have adverse 
effects on the quantity and quality of crystals produced. 
As a practical matter, convection and sedimentation can 
be completely eliminated only under conditions of low 
gravity attained during orbital flight. There is, then, an 
advantage to effecting crystallization in space. But in 
the absence of of convection in a microgravity environ- 
ment cooling proceeds by thermal diffusion from the 
walls to the center of the solution chamber. This ren- 
ders control of nucleation difficult. Accordingly there is 
a need for a new and improved nucleation process in 
space. Herein crystals are nucleated by creating a small 
localized region of high relative supersaturation in a 
host solution at a lower degree of supersaturation. 
3 Claims, 1 Drawing Sheet 
https://ntrs.nasa.gov/search.jsp?R=19930005518 2020-03-24T07:22:57+00:00Z
U.S. Patent 
76-12 
Dec. 22, 1992 
9 
5,173,087 
FIG. 1 .  
LL . 
FIG. 2 .  
5,173,087 
1 
CRYSTAL GROWTH IN A MICROGRAVITY 
ENVIRONMENT 
ORIGIN OF THE INVENTION 
The Invention described herein was made by employ- 
ees of the United States Government, and may be manu- 
factured and used by or for Government purposes with- 
out the payment of any royalties thereon of therefor. 
BACKGROUND OF THE INVENTION 
This invention relates to crystallization. Crystalline 
solids have many desirable properties such as purity, 
size, shape, color, and processability which are com- 
mercially advantageous. In addition for many materials 
crystallization is the best and cheapest method for pro- 
ducing that material industrially. 
Crystallization, a process whereby a solid separates 
from a solution, is well known. Conditions are imposed 
on the solution which allow a solid phase of crystalline 
particles to grow from atoms to a size sufficiently large 
to allow separation by physical methods. The basic 
principle behind crystallization is that a solution con- 
taining one or more solutes is altered by either cooling, 
removal of solvent, or addition of another substance so 
that the ability of the solvent to dissolve the solute is 
reduced, and a fraction of the solute forms a solid phase 
which can be removed from the mixture. In other 
words, if a solution in equilibrium between its solid and 
liquid phases is altered in such a way that the amount of 
dissolved solids exceeds the equilibrium concentration, 
the system will seek to reestablish an equilibrium condi- 
tion by getting rid of the excess solids. The resulting 
process is crystallization, and the concentration excess, 
termed supersaturation, is the driving force. 
The quantity of solid matter which a liquid can dis- 
solve and the effect on this quantity of changes in tem- 
perature, pressure, particle size, and the presence of 
foreign substances are not predictable. Gravitational 
phenomena, including convection, sedimentation, and 
interactions of materials with their containers all affect 
the crystal growth process. If they are not taken into 
consideration they can have adverse effects on the qual- 
ity and on crystal production because both the material 
transport and the crystal growth process are dominated 
by gravity-driven convection. The crystallization pro- 
cess, is also strongly affected by the presence and be- 
havior of buoyancy-driven convection. Unless precau- 
tions are taken to suppress convection currents, undesir- 
able results are possible. 
As a practical matter, convection and sedimentation 
can be completely eliminated most directly under con- 
ditions of low gravity attained during orbital flight. For 
this reason it is believed that higher quality forms of 
crystals and drugs can be manufactured in orbit, that is, 
under microgravity conditions. Consequently there is 
much current interest and experimentation in crystalli- 
zation processes conducted without gravitational ef- 
fects. Such crystallization processes are deemed to lead 
to better control of the quality and properties of crys- 
tals. Electronic measurements on these crystals charac- 
terize the crystalline perfection, and thus help to estab- 
lish the influence of microgravity on crystal growth. 
Microgravity is about one/millionth the level of gravity 
on earth. The term “zero gravity” is often used where 
microgravity is the correct term. 
There is one disadvantage to crystallization in space. 
That is the nucleation process. Because of the absence 
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of convection in a microgravity environment, cooling 
proceeds by thermal diffusion from the cold walls to the 
center of the solution chamber. Nucleation, which will 
frst begin where the temperature is the lowest, will 
occur on and near the chamber walls. Crystals, which 
nucleate heterogeneously on the walls, will have their 
growth modified and interfered with by their attach- 
ment to the wall. There is, then, a need for a new and 
improved nucleation process in space. By this invention 
such a nucleation process is provided. 
SUMMARY OF THE INVENTION 
Crystallization processes in microgravity involve 
cooling a solution to produce supersaturation sufficient 
to induce nucleation of crystals of the desired substance. 
Because of the absence of convection in a microgravity 
environment, cooling proceeds by thermal diffusion 
from the walls inwardly. This creates a temperature 
gradient from the walls to the solution chamber center. 
Crystals which form in this temperature gradient will be 
nucleated at different times, and possibly at different 
degrees of supersaturation as the cool front moves 
through the solution. In any event the nucleation pro- 
cess can not be localized, and the process is not easy to 
control. 
Herein crystals are nucleated by creating a small 
localized region of high relative supersaturation in a 
host solution at a lower degree of supersaturation. A 
process for effecting nucleation of crystals in micro- 
gravity is provided where buoyancy driven convection 
does not exist, and crystal growth is achieved by diffu- 
sion. The process includes forming a supersaturated 
solution of solute in a solvent by concentrating it to its 
state of metastable supersaturation. In a localized region 
of said metastable solution an increase in solute concen- 
tration is effected so that in that localized region a por- 
tion of the solution exceeds the metastable concentra- 
tion. That equilibrium departure is the driving force 
bringing about nucleation in the localized zone. 
DETAILED DESCRIPTION OF THE 
INVENTION 
In an earth orbiting spacecraft convection and sedi- 
mentation become negligibly small. Diffusion is the 
predominant mechanism of transport. Crystals can be 
grown by solute diffusion, but nucleation remains diffi- 
cult to control. The energetics of nucleation leads to an 
atomistic cluster which grows to a nucleus with an 
increase in solute concentration. An equilibrium exists 
between the solute and the solvent at saturation. At the 
saturation temperature solute and mother liquor coexist 
in thermodynamic equilibrium. According to theory 
this is a definite region of low driving force in which no 
crystal growth takes place. At a departure from this 
equilibrium condition existing crystals grow, but new 
crystals do not nucleate. This is the metastable region of 
supersaturation. Once the solute concentration exceeds 
the equilibrium for this metastable region the nucleation 
rate increases exponentially with increased concentra- 
tion. Thus at a certain definite departure from the meta- 
stable supersaturation state a homogeneous system will 
become critical and nucleate crystallites. To reach this 
concentration the solution is either cooled or evapo- 
rated until it is suf€iciently supersaturated for spontane- 
ous nucleation. 
In a microgravity environment the absence of con- 
vective heat transfer produces some undesirable results. 
5,173,087 
3 4 
Solution cooling and the resulting supersaturation pro- valve 14, is connected to a hot saturated solution reser- 
ceed by diffusion. Solution adjacent to a cooled wall, or voir, not shown. By means of plunger 16 a small amount 
fluid-gas interface will have a localized increase in its of the hot saturated solution from the solute reservoir is 
supersaturation. The proximity of solid surfaces or injected into the lower temperature supersaturated 
fluid-gas interfaces to the nucleated crystals tends to 5 growth solution 8 through tip 18 of hollow needle 6. 
distort the mass diffusion fields around the crystals. This This small quantity of hotter saturated solution pro- 
results in the nucleation of uncontrolled numbers of duces a local region 15 of high supersaturation as it 
crystals on the surfaces, such as the walls of the con- cools to the temperature of the host solution. The ther- 
tainer, or on the free surface of the liquid. The nucle- mal diffusivity is larger than the mass diffusivity. There- 
ation of large numbers of crystals at one time limits the 10 fore, when the drop or drops (small quantity) of hot, 
size to which the crystals will grow by rapidly deplet- concentrated solution enters the cooler, less concen- 
ing the solution of solute. This is particularly trouble- trated, but metastable host solution 8, the drop cools 
some in protein crystal growth where the production of and exceeds its own metastable region of supersatura- 
large crystals is the purpose for using microgravity. tion before the concentration can be reduced by mas 
By the practice of this invention the metastable state 15 diffusion into the solution 8. This high degree of super- 
of supersaturation is exceeded in a highly localized area saturation exceeding the metastable state results in nu- 
of the metastable solution. In this high supersaturation cleation of crystals 19. Since host solution 8 is metasta- 
location within the less supersaturated (metastable) host bly supersaturated these crystals can then grow in ves- 
solution nucleation will occur. This localized region sel or cooling chamber 2. Crystals are thus nucleated 
persists long enough for nucleation to occur because of 20 only in specific locations, and in controlled numbers 
the absence of buoyancy-driven convection in micro- only. This prevents the nucleation of crystals on solid 
gravity. After nucleation has occurred, diffusion will surfaces, or in such large numbers that they deplete the 
cause the region of high supersaturation to dissipate. solution before growing to useful sizes. In microgravity 
The supersaturation of the solution surrounding the the crystals grow suspended in the host solution so that 
nuclei will then return to the ambient value, preventing 25 there is no contact with solid surfaces during growth. 
further nucleation. Diffusion-controlled growth of the An alternate embodiment of this invention, shown in 
few crystals nucleated in the local zone will then pro- FIG. 2, includes the insertion of a cooled rod 20 into the 
ceed in the metastable supersaturated solution without host solution. Thus, instead of being a hollow needle, 
interference from surfaces. element 20 can be a cooled tip of a rod. The insertion of 
The first Skylab I11 demonstration was diffusion in 30 an insulated (24) rod 20 with a cold tip into a supersatu- 
liquids. In Skylab IV Rochelle salt growth tests were rated solution results in cooling an area 15 surrounding 
conducted. Crystal growth experiments were also de- the rod. Since thermal diffusion in a fluid is faster than 
veloped to investigate PbS, CaC03 and TTF-TCNQ. mass diffusion, the solution adjacent the depleted region 
Each of these crystals are technologically important. will cool, and hence, as in the first embodiment, will 
PbS is a semiconductor, and CaC03 has useful optical 35 exceed the metastable supersaturation state before mass 
properties. The important property of TTF-TCNQ is its diffusion depletes that part of the solution. Nucleation 
one-dimensional electrical conductivity. A significant will then occur in that region only, the effect being 
observation in microgravity experiments was that com- similar to the hot fluid injection method. The growth of 
bined effects of vehicular motion, crew motion, thruster a crystal, or crystals, so nucleated will form a solute- 
firings to dump angular momentum from the accumula- 40 depleted region adjacent the growing face. This region 
tion of gravity gradient torques, and other sources of will remain stable in the convection-free microgravity 
acceleration or g-jitter integrated over three days did environment. 
not produce any discernible mixing. They do not, there- In the light of the teachings of this invention ramifica- 
fore, affect the nucleation process herein. tions and modifications will occur to those in this field. 
45 As an example various crystallization vessels cap be 
used, for instance glove boxes and the like. Further, in PREFERRED EMBODIMENT O F  THE 
addition to the proteins and other crystals mentioned INVENTION 
There are two methods for creating a small localized hereinbefore, the invention herein is applicable to any of 
region of high relative saturation which exceeds the the usual inorganic crystals such as potassium sulfates, 
metastable supersaturation state in a host supersaturated 50 aluminum sulfate, sodium sulfate, barium bromide, bar- 
solution. One method is to introduce a small amount of ium iodide, beryllium sulfate, beryllium chloride, cad- 
a solution which is saturated at a higher temperature mium nitrate and the like. In addition organic crystals 
than the host solution. Another method is to cool only are within the contemplation of the invention, for exam- 
a small portion of the localized area. ple, acetamide, benzoic acid, cinnamic acid, glutamic 
55 acid, glycine, oxalic acid, salicylic acid, tartaric acid, 
urea and others. Such ramifications are deemed to be DESCRIPT1oN OF THE 
In the drawing FIG. 1 is a schematic view, partially 
in section, of a cooling chamber adapted for use in the What is claimed is: 
first method. 1. A process for effecting nucleation in microgravity 
FIG. 2 is a view, partially cut away, showing the 60 crystallization where buoyancy-driven convection does 
second method. not exist, which comprises cooling a solution of solute 
A preferred embodiment of the invention is that in a solvent in a cooling chamber to the saturation tem- 
shown in FIG. 1. It can, perhaps, best be understood perature and then further cooling that saturated solu- 
from a discussion in conjunction with that figure. tion to a state of metastable supersaturation thus form- 
Cooling chamber 2, provided with insulation 4, is 65 @g a metastable host solution, then in a local region 
provided with a hollow needle 6 which is also insulated, injecting a saturated solution of solute at a saturation 
at 7. The needle tip is inserted into a body of supersatu- temperature above the temperature of the metastable 
rated growth solution 8 in chamber 2. Line 12, through host solution into the lower temperature host solution, 
within the scope of this invention. 
5,173,087 
c 
J 
thns exceeding the metastable limit of saturation at the 
point of injection to form crystals in that local region 
before its concentration can be reduced by mass diffu- 
sion into the host solution, wherein said local region is 
located so that no contact. occurs between the crystals 
and the solid surfaces of the cooling chamber. 
2. A process for effecting nucleation in microgravity 
crystallization where buoyancy-driven convection does 
not exist, which comprises cooling a solution of solute 
in a solvent in a cooling chamber to the saturation tem- 
perature and then further cooling that saturated solu- 
tion to a state of metastable supersaturation thus form- 
6 
ing a metastable host solution, initiating nucleation and 
crystal growth in a local region by cooling that local 
region as the remaining metastable host solution does 
not exceed its metastable limit of supersaturation and 
said local region is located so that no contact occurs 
between the crystals and the solid surfaces of the cool- 
ing chamber. 
3. The process of claim 2 wherein the local region in 
10 the metastable host solution is cooled by inserting into 
the local region an element colder than the local region. 
* * * * *  
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Crystal growth in a microgravity environment

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