^ord to the Wise
lution
The two most fundamental properties that character-ize a mineral and distinguish it from other mineralsare its chemical composition (the elements of which it
is made and their relative proportions) and crystal structure(the three-dimensional arrangement of its constituent atomsor ions). Thus, a given mineral has a specific compositionthat in part defines it. For example, the mineral quartz con-tains oxygen and silicon in a fixed ratio of 20:1 Si. That is, forevery two oxygen ions there is one silicon ion. This is indi-cated by the subscripts in the chemical formula of quartz,SiO,. Similarly, the formula of fayalite, Fe,SiO^, indicates theratio of Fe:Si:O is 2:1:4.
In nature, however, no minerals are truly pure; they alwayscontain some elements other than those that define them.For example, quartz usually contains some Al and Ge as wellas Si and O. Although both of these impurities substitutefor Si in the crystal structure of quartz, their concentrationsrarely exceed parts-per-million {1 ppm = 0.0001 wt. %)levels. Thus, minerals such as quartz are typically "close" tobeing pure in composition.
Unlike quartz, most minerals can allow extensive substitu-tions between certain elements among specific sites in theircrystal structures and can thus exhibit extensive variationin chemical composition; this is called a solid solution. Let'sconsider a simple example: olivine. In the olivine crystalstructure, the identical ionic charges and similar sizes ofFe'^ and Mg- allow these ions to substitute freely for eachother within any given octahedral site—i.e., they form asolid solution. As a result, olivine's chemical formula can bewritten as X,SiO^, where X can be either Fe- or Mg-* or anycombination of the two. The conventional way to expressthis relationship is to place the elements that make up thesolid solution in parentheses separated by commas-—i.e.,(Fe,Mg),SiO^. This formula tells us that there can be anyproportion of Fe and Mg from Fe,SiO^ {pure fayalite) toFe|Mg|SiO^ to Mg,SiO^ (pure forsterite). This is shown sche-matically in figure 1.
In cases where solid solutions occur, it is convenientto think of a mineral structure as a collection of crystal-lographic sites (e.g., tetrahedral and octahedral sites) withspecific linkages and arrangements in which variable butspecific elemental constituents can reside. Indeed, Klein andHurlbut (1999) state that "a solid solution is a mineral struc-ture in which specific atomic site(s) are occupied in variable
Dr. John Rakovan, an executive editor o/Rocks & Minerals, is aprofessor of mineralogy and geochemistry at Miami Universityin Oxford, Ohio.
JOHN RAKOVANDepartment of Geology
Miami UniversityOxford, Ohio 45056
• FavaHie- • Forstertte •
Fe Me
%Fe 100 90
90 80
60
60
50
50
40
40
30
30
20
20
Figure 1. Schematic representation of the Fe-Mg solid solutionin olivine. The compositional boundary between fayalite andforsterite is at 50% Fe / 50% Mg. The solid solution between Feand Mg is one of several in the olivine structure. Solid-solutioncompositions can be expressed in several equivalent ways. Forexample, tbe composition indicated by the red X can be writtenas Mg, Fey SiO . or Fo70Fa30, or Fa30, Fo70.
e I
Figure 2. Ball-stick representations of the apatite structure:(001) projection, and the A, B, and C atomic sites. There are twodistinct A-sites, labeled AI and A2, which are normally occupiedby Ca. The complete coordination spheres of the A2 and B sitesare not visible in this orientation.
proportions by two or more different chemical elements (orgroups)." Fxtreme cases are found in mineral groups suchas apatite, amphibole, pyroxene, feldspar, and tourmaline.The formula for fluorapatite is Ca^(PO^),F, but numeroussolid solutions occur among most of the crystallographicsites in its structure (fig. 2). To express this we can write theformula as A.(BO,),C where the A-site can be occupied tovarying degrees with Ca, Sr, Na, Mn, Fe, Y, Pb, Ba, La, Ce, U,Th, and so forth; the B-site with P, As, Si, V, S, and so forth;and the C-site with F, Cl, OH, and so forth (Pan and Fleet2002). Because the structure of apatite allows for so many
Volume 80, Novemher/December 2005 449
substitutions, many of which form complete or extensivesolid solutions, there are more than twenty-eight differentminerals with this structure, all of which are said to be apa-tite-group minerals.
There are actually three types of solid solution in miner-als, namely, substitutional, interstitial, and omission solidsolutions. Suhstitutional solid solution, the most commontype, is where one ion substitutes for another in a regularlyoccupied crystallographic site. This is exemplified by olivineand apatite (described above). The relative sizes and chargesof the ions that are substituting for one another as well as thetemperature at which the substitutions take place determinethe extent to which a given substitutional solid solution willoccur. If all degrees of substitution are possible, it is said thatit is a complete solid solution.
In the case where a solid solution occurs between twoions with different charges (e.g., Ca'"" and La- * in fluorapa-tite), other substitutions must occur in order to maintaincharge neutrality (a necessity for a stable mineral). This isknown as a coupled substitution. In apatite, there are severalknown substitutions that can couple with the Ca'* 4*La^*substitution to maintain charge balance. These include Na" ',Ca-% Si*' P^ , O-, F , and a vacancy (an unoccupied Ca ^site represented as D). These coupled substitutions can beexpressed as follows:
Interstitial F"
Note that if you add up all of the charges on the left andright side of each coupled substitution, they are equivalent.The 2La ^ + D <» 3Ca" is an example of an omission solidsolution, where the presence of a vacant site is part of thesubstitution.
In an interstitial solid solution, substituent atoms or ionsare added to void spaces (interstitial sites) between normalatomic sites. The structure of fluorite, CaF,, exemplifies thisnicely (fig. 3). In fluorite, Ga- ^ is surrounded (coordinated)by 8 F in a cubic geometry. These Ga-F , cubes alternate withcubically coordinated void spaces along the axial directionsof the structure. A common group of substituents that formpartial solid solutions with Ca in fiuorite are the lanthanides(e.g.. La). Lanthanide ions most commonly have a 3+ charge.Thus, if they are to substitute for Ga-+, another substitutionmust be coupled with it to maintain charge neutrality. Themost common substitution coupled with Ga-" •» La* is IS•a- F, where IS is an interstitial site.
In everyday usage, the term solution is most commonlyapplied to a liquid. For instance, seawater is a solution inwhich solids such as NaGl and gasses such as GO, and manyother solids and gasses are dissolved. Solutions can exist inany state of matter, however, including a gas solution (e.g.,air), and as just discussed, a solid solution. In this issue ofRocks & Minerals, Simmons et al. describe recent tourmalinediscoveries from Mount Mica, Maine. One of the pockets
Figure 3. Ball-stick (left) and polyhedral (right) representationsof the fluorite structure. The red sphere represents La-* thathas substituted for Ca ^ on a regularly occupied site with cubiccoordination. An extra F' is added to an interstitial site to chargebalance the La'' *» Ca * suhstitution.
recently exposed at this deposit contained the tourmalinespecies schorl, elbaite, rossmanite, and foitite, which rep-resent four different solid solutions in tourmaline. Thesubstitutions in the tourmaline structure are so varied andextensive that mineralogists often refer to it as a "garbagecan" mineral.
As one can imagine, with so many possible compositionalvariations due to solid solutions, the naming of mineralscan get quite complicated. Nomenclature recommendationsfor solid solutions, as set forth by the Gommission on NewMinerals and Mineral Names (GNMMN) of the Interna-tional Mineralogical Association, can be found in Nickel(1992). This and other nomenclature recommendations ofthe GNMMN can be downloaded from the GNMMN Website, http://www.geo.vu.nl/users/ima-cnmmn/.
ACKNOWLEDGMENTSI would like to thank Kendall Hauer and Bob Cook for their
reviews of this manuscript.
REFERENCES
Klein, C. K., and C. S. Hurlbut. 1999. Manual of mineralogy. Rev.21st ed. New York: John Wiley & Sons.
Nickel, E. H. 1992. Solid solutions in mineral nomenclature. Cana-dian Mineralogist 30:231-34.
Pan, Y., and M. E. Eleet. 2002, Compositions of the apatite-groupminerals: Substitution mechanisms and controlling factors. InPhosphates: Geochemkal, gcobiologica! and materials ijnportance,ed. M. Kohn, J. Rakovan, and J. M. Hughes, 13-49. Reviews inmineralogy and geochemistry. Washington, DC: MineralogicalSociety of America. •
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