Ambiguities in powder indexing: conjunction of a ternary and binary lattice metric singularity in the cubic system.A lattice (theory) lattice - A partially ordered set in which all finite subsets have a least upper bound and greatest lower bound. This definition has been standard at least since the 1930s and probably since Dedekind worked on lattice theory in the 19th century; though he may not metric singularity (1) See technology singularity. (2) (Singularity) An experimental operating system from Microsoft for the x86 platform written almost entirely in C#, a .NET managed code language. Released in 2007, Singularity is a non-Windows research project. occurs when unit cells defining two (or more) lattices yield the identical set of unique calculated d-spacings. The existence of such singularities, therefore, has a practical and theoretical impact on the indexing of powder powder, any mass of fine particles or dust prepared by various mechanical means, e.g., grinding of solid substances, or by chemical means, e.g., precipitation from solutions. In a special sense, the word is applied to powdered propellant explosives, e.g. patterns. For example, in experimental practice an indexing program may find only the lower symmetry symmetry, generally speaking, a balance or correspondence between various parts of an object; the term symmetry is used both in the arts and in the sciences. member of a singularity. Obviously, it is important to recognize such cases and know how to proceed. Recently, we described: (1) a binary Meaning two. The principle behind digital computers. All input to the computer is converted into binary numbers made up of the two digits 0 and 1 (bits). For example, when you press the "A" key on your keyboard, the keyboard circuit generates and transfers the number 01000001 to the singularity involving a monoclinic mon·o·clin·ic adj. Of or relating to three unequal crystal axes, two of which intersect obliquely and are perpendicular to the third. monoclinic Adjective Crystallog and a rhombohedral lattice in a subcell-supercell relationship and (2) a second type of singularity--a ternary (programming) ternary - A description of an operator taking three arguments. The only common example is C's ?: operator which is used in the form "CONDITION ? EXP1 : EXP2" and returns EXP1 if CONDITION is true else EXP2. singularity--in which two of the three lattices are in a derivative derivative: see calculus. derivative In mathematics, a fundamental concept of differential calculus representing the instantaneous rate of change of a function. composite composite, alternate common name for Asteraceae or Compositae, the aster family. composite - aggregate relationship. In this work, we describe a ternary lattice metric singularity involving a cubic P, a tetragonal tet·ra·gon n. A four-sided polygon; a quadrilateral. [Late Latin tetrag P, and an orthorhombic or·tho·rhom·bic adj. Of or relating to a crystalline structure of three mutually perpendicular axes of different length. orthorhombic C lattice. Furthermore, there is a binary singularity, involving a hexagonal hex·ag·o·nal adj. 1. Having six sides. 2. Containing a hexagon or shaped like one. 3. Mineralogy P and orthorhombic P lattice, which is characterized char·ac·ter·ize tr.v. character·ized, character·iz·ing, character·iz·es 1. To describe the qualities or peculiarities of: characterized the warden as ruthless. 2. by a set of unique d-spacings very close to that of the ternary singularity. The existence of such singularities is more common than once thought and requires a paradigm shift A dramatic change in methodology or practice. It often refers to a major change in thinking and planning, which ultimately changes the way projects are implemented. For example, accessing applications and data from the Web instead of from local servers is a paradigm shift. See paradigm. in experimental practice. In addition singularities provide opportunities in material design as they point to highly specialized spe·cial·ize v. spe·cial·ized, spe·cial·iz·ing, spe·cial·iz·es v.intr. 1. To pursue a special activity, occupation, or field of study. 2. lattices that may be associated with unusual physical properties. Key words: ambiguities in powder indexing; derivative lattices; d-spacings; figure of merit Noun 1. figure of merit - a numerical expression representing the efficiency of a given system, material, or procedure efficiency - the ratio of the output to the input of any system ; indexing programs; lattice metric singularity; powder indexing; specialized lattices. ********** 1. Introduction Increasingly, crystal structures are being solved using powder diffraction Powder diffraction is a scientific technique using X-Ray or neutron diffraction on powder or microcrystalline samples for structural characterization of materials. Ideally, every possible crystalline orientation is represented equally in a powdered sample. data. This is due to the evolving power of the ab initio [Latin, From the beginning; from the first act; from the inception.] An agreement is said to be "void ab initio" if it has at no time had any legal validity. structure solving techniques using powder diffraction data and to the fact that in many cases it is impossible to obtain crystals of sufficient size to carry out a single crystal structure analysis. A critical step in the solution process is the determination of a unit cell that defines the lattice. This is commonly done with an indexing program such as DICVOL91[1] or TREOR[2]. A correct indexing solution is signaled by a high value of the resulting figure of merit (de Wolff Wolff , Kaspar Friedrich 1733-1794. German anatomist noted for his pioneering work in embryology. His chief work, Theoria Generationis (1759), refuted the theory of preformation, which held that the embryo is a fully formed miniature adult. [3]; Smith and Snyder Snyder, city (1990 pop. 12,195), seat of Scurry co., NW Tex., in a prairie and mesquite region; inc. 1907. Oil production is the city's main industry; natural gas is also refined and processed. [4]). However, a high figure of merit does not guarantee a correct solution. It is a necessary but not sufficient condition for correctness. For example in certain cases, a unique indexing solution does not exist. When a lattice metric singularity occurs [5], there are two or more cells that will account for the same set of observed ob·serve v. ob·served, ob·serv·ing, ob·serves v.tr. 1. To be or become aware of, especially through careful and directed attention; notice. 2. d-spacings. This mathematical condition is defined as follows:
A lattice metric singularity (LMS) occurs when unit cells
defining two (or more) lattices yield identical sets of unique
calculated d-spacings.
Herein singularities in the cubic system will be discussed. In particular special emphasis will be on the conjunction conjunction, in astronomy conjunction, in astronomy, alignment of two celestial bodies as seen from the earth. Conjunction of the moon and the planets is often determined by reference to the sun. of a ternary and a binary LMS (Learning Management System) An information system that administers instructor-led and e-learning courses and keeps track of student progress. Used internally by large enterprises for their employees, an LMS can be used to monitor the effectiveness of the that occurs in the cubic primitive (1) In computer graphics, a graphics element that is used as a building block for creating images, such as a point, line, arc, cone or sphere. (2) In programming, a fundamental instruction, statement or operation. See machine instruction. system. This conjunction means that in this system there will always be multiple indexing solutions that are mathematically correct Mathematically Correct is a website created by educators, parents, citizens and mathematicians / scientists who are concerned about the direction of reform mathematics curricula based on NCTM standards. It is one of the most frequently cited websites in the Math wars. . Consequently, in experimental practice care must be taken to obtain the correct answer. When using indexing procedures, there is no inherent reason to assume the correct answer is necessarily the lattice of highest symmetry. Clearly, in addition to indexing procedures, other methods--e.g., optical, single crystal, etc.,--should be routinely employed to establish uniquely the lattice and symmetry. Finally it will be shown that the lower symmetry lattices involved in the singularities discussed herein have unusual metric properties and are characterized by specialized reduced forms In social science and statistics, particularlly econometrics, a reduced form equation is a method of dealing with endogeneity. A reduced form equation is defined by James Stock & Mark Watson (2007) in the following way: . A specialized reduced form can signal that certain derivative lattices can have higher symmetry than the original lattice. Accordingly, it is expected the physical properties of actual crystals with such specialized lattices would be influenced by the singularity condition. 2. The Ternary Lattice Metric Singularity The three lattices involved in the ternary singularity are given in Table 1. The lattices I, II, and III are defined by primitive cells In geometry, solid state physics and mineralogy, particularly in describing crystal structure, a primitive cell, is a minimum cell corresponding to a single lattice point of a structure with translational symmetry in 2D, 3D, or other dimensions. 1 and 2, and C-centered cell 3, respectively. Alternatively, lattice III can be defined by the primitive reduced cell denoted as 3'. When one compares the volumes of cells 1,2,3' (i.e., the 3 primitive cells), one notes that the cell volumes are in a 3:1.5:1 relationship. In fact, cells 2 and 3' are derivative subcells of cell 1. The reduced forms for cells 1-3 that define the three lattices are given in Table 2. As the reduced forms are all different, the three cells clearly define different lattices. The reduced forms 3, 11 and 38 are characteristic of a primitive cubic, primitive tetragonal, and a C-centered orthorhombic lattice, respectively. Detailed inspection of the second two reduced forms shows that there is more specialization A career option pursued by some attorneys that entails the acquisition of detailed knowledge of, and proficiency in, a particular area of law. As the law in the United States becomes increasingly complex and covers a greater number of subjects, more and more attorneys are than required for the given reduced form type. For example, in the case of lattice II, the 1:1:2 relationship between the symmetrical symmetrical equally on both sides. symmetrical multifocal encephalopathy inherited disease in two forms: Limousin form appears at about a month old with blindness, forelimb hypermetria, hyperesthesia, nystagmus, aggression, weight dot products--a*a:b*b:c*c--of the reduced form implies (logic) implies - (=> or a thin right arrow) A binary Boolean function and logical connective. A => B is true unless A is true and B is false. The truth table is A B | A => B ----+------- F F | T F T | T T F | F T T | T It is surprising at first that A => a highly specialized lattice. In Table 3, we present the unique d-spacings for the three lattices. The sets of unique interplanar spacings are identical. However, the columns labeled M for lattices I-III show that the number of d-spacings with a given calculated d-value The introduction to this article provides insufficient context for those unfamiliar with the subject matter. Please help [ improve the introduction] to meet Wikipedia's layout standards. You can discuss the issue on the talk page. can be different. Consider a calculated d-value equal to 1.2910 [Angstrom angstrom (ăng`strəm), abbr. Å, unit of length equal to 10−10 meter (0.0000000001 meter); it is used to measure the wavelengths of visible light and of other forms of electromagnetic radiation, such as ultraviolet ] (Note: 1 [Angstrom] [= 0.1 nm] is the common unit in crystallography). For this value the table shows that the numbers calculated for lattices I, II, and III are 1, 2 and 7, respectively. When the program NBS (National Bureau of Standards) See NIST. NBS - National Bureau of Standards: part of the US Department of Commerce, now NIST. *AIDS83[8] calculates more than one (not symmetrically sym·met·ri·cal also sym·met·ric adj. Of or exhibiting symmetry. sym·met  ri·cal·ly adv.Adv. 1. related) d-spacing with the same value, the hkl indices for only the first of the group are given in Table 3. For the nonspecialized lattice of tetragonal or orthorhombic symmetry, the program would calculate M discrete A component or device that is separate and distinct and treated as a singular unit. d-spacings for those cases in which M >1 in Table 3. Inspection of d-spacing data for lattices II and III reveals that these two lattices are highly specialized in the sense that the value of M is often greater than 1. Thus the patterns have far fewer discrete lines than normally possible for the given symmetry. This is shown in Table 4. In column four of this table, the compression ratio compression ratio Degree to which the fuel mixture in an internal-combustion engine is compressed before ignition. It is defined as the volume of the combustion chamber with the piston farthest out divided by the volume with the piston in the full-compression position ( is given which is the ratio of the unique d-spacings to the total calculated d-spacings. For the tetragonal lattice, the compression ratio is 0.422 when the d-spacings are calculated out to a 2[theta Theta A measure of the rate of decline in the value of an option due to the passage of time. Theta can also be referred to as the time decay on the value of an option. If everything is held constant, then the option will lose value as time moves closer to the maturity of the option. ] of 55[degrees] with [lambda] = 0.7093 [Angstrom]. 3. The Binary Lattice Metric Singularity The two lattices involved in the binary singularity are given in Table 5. These lattices are defined by primitive cells 4 and 5. Cell 4 defines an orthorhombic lattice whereas cell 5 of twice the volume defines a hexagonal lattice The hexagonal lattice or equilateral triangular lattice is one of the five 2D lattice types. Three nearby points form an equilateral triangle. In images four orientations of such a triangle are by far the most common. . The nature of the lattice relationship can be deduced from the transformation matrix relating the two cells. Thus lattice V is a superlattice A superlattice is a material with periodically alternating layers of several substances. Such structures possess periodicity both on the scale of each layer's crystal lattice and on the scale of the alternating layers. of lattice IV. The reduced forms for cells 1 and 2 defining the two lattices are given in Table 6. As the reduced forms are different, the two cells clearly define different lattices. The reduced form type 32 is characteristic for a primitive orthorhombic lattice and reduced form 22 for a hexagonal lattice. Detailed inspection of each reduced form (or normalized reduced form) shows that there is more specialization than required for the given reduced form type. For example, in the case of lattice IV, the 1:1.5:3 relationship between the symmetrical dot products--a*a:b*b:c*c--of the reduced form implies a highly specialized lattice. In Table 7, we present the unique d-spacings for the two lattices. The sets of unique interplanar spacings are identical. However, the columns labeled M for lattices IV and V show that the number of d-spacings with a given calculated d-value can be different. Consider a calculated d-value equal to 1.3056. For this value, the table shows that the numbers calculated for lattices IV and V are 4 and 2, respectively. When the program NBS*AIDS83[8] calculates more than one (not symmetrically related) d-spacing with the same value, the hkl indices for only the first of the group are given in the table. For a nonspecialized lattice of orthorhombic or hexagonal symmetry, the program would calculate M discrete d-spacings for those cases in which M >1 in Table 7. Inspection of the two patterns reveals that these two lattices are highly specialized in the sense that the value of M is often greater than 1. Thus the patterns have far fewer discrete lines than normally possible for the given symmetry. This is shown in Table 8. In column 4 of this table, the compression ratio is given which is the ratio of the unique d-spacings to the total calculated d-spacings. For the orthorhombic lattice, the compression ratio is 0.29 when the d-spacings are calculated out to a 2[theta] of 55[degrees] with [lambda] = 0.7093 [Angstrom]. 4. Conjunction of Lattice Metric Singularities in the Cubic P System The singularities discussed above can present difficulties in indexing powder patterns. As an example, let us assume that an indexing program is presented with a set of observed d-spacings obtained from a crystal whose lattice is correctly defined by a cubic primitive unit cell. What should the indexing program reveal? Mathematically math·e·mat·i·cal also math·e·mat·ic adj. 1. Of or relating to mathematics. 2. a. Precise; exact. b. Absolute; certain. 3. , a unique indexing solution does not exist. As the data in Table 3 illustrate, three distinct lattices--defined by a cubic P, a tetragonal P, and an orthorhombic C unit cell--are characterized by the same set of unique d-spacings. Further complicating com·pli·cate tr. & intr.v. com·pli·cat·ed, com·pli·cat·ing, com·pli·cates 1. To make or become complex or perplexing. 2. To twist or become twisted together. adj. 1. this situation is the fact that this ternary LMS is in conjunction with a binary LMS, i.e., the two lattices in the binary LMS (Table 7) are characterized by a set of d-spacings that is almost the same as the one in the ternary LMS (Table 3). This conjunction is demonstrated in Table 9 which shows how closely the sets of d-spacings in the two singularities are related. Consider a data set comprised of the first 20 possible d-spacings for the cubic P crystal. In addition assume that merely one d-spacings [2.7386] is accidentally absent. In this case there are five possible answers that are mathematically correct! In fact, using this data set as input to the Boultif and Louer indexing program [1], it was possible to obtain all five answers. 5. Discussion The results above are described in terms of a lattice defined by a cubic primitive cell (a = 8.6603 [Angstrom]). However, by the principle of similarity Similarity is some degree of symmetry in either analogy and resemblance between two or more concepts or objects. The notion of similarity rests either on exact or approximate repetitions of patterns in the compared items. , the same ambiguities in indexing exist with respect to experimental data determined from any crystal characterized by a cubic primitive cell. Furthermore, as the cubic primitive lattice is common for inorganic inorganic /in·or·gan·ic/ (in?or-gan´ik) 1. having no organs. 2. not of organic origin. in·or·gan·ic n. 1. materials, the above type of ambiguity Ambiguity Delphic oracle ultimate authority in ancient Greece; often speaks in ambiguous terms. [Gk. Hist.: Leach, 305] Iseult’s vow pledge to husband has double meaning. [Arth. can often present difficulties in common practice. This is especially true today as more and more structures are solved from powder data only. As demonstrated above, there is more than one mathematically correct answer when indexing "ideal" data from a cubic primitive crystal. In experimental practice, however, the situation is more complex as the quality of the observed data is influenced by such factors as experimental errors, accidental accidental /ac·ci·den·tal/ (ak?si-den´t'l) 1. occurring by chance, unexpectedly, or unintentionally. 2. nonessential; not innate or intrinsic. absences, and impurities. Consequently the indexing program may not yield all the potential answers and it may not yield the correct answer! This happened to us in the course of our experimental work. In our case, we obtained only the orthorhombic solution in the binary singularity when, in fact, the crystal was later shown to be cubic primitive. Other scenarios are equally possible. For example, if one obtains only the primitive tetragonal or C-centered orthorhombic cell of the ternary singularity, then one would have a derivative subcell of the correct lattice. Subsequent structure solving techniques may then yield an incorrect Incorrect means to not be correct and may also refer to:
How can errors in lattice determination be prevented? One key to prevention is to inspect the reduced form. A warning flag is extra specialization in the reduced form. As Table 2 and 6 show, the reduced forms for the lower symmetry indexing answers all have more specialization than required for the given reduced form type [7]. For example, in Table 2 the symmetrical scalars of the reduced form (a*a b*b c*c) for lattice II are in the ratio 1:1:2 (whereas the requirement is simply 1:1:1+x). Extra specialization of this nature commonly indicates that something is unusual such as an incorrect answer or a highly specialized lattice. Another key to error prevention is to use other methods along with powder indexing. For example, any primitive cell determined via the precession method would distinguish between the potential indexing solutions. Likewise, optical techniques, such as polarization polarization Property of certain types of electromagnetic radiation in which the direction and magnitude of the vibrating electric field are related in a specified way. microscopy microscopy /mi·cros·co·py/ (mi-kros´kah-pe) examination under or observation by means of the microscope. mi·cros·co·py n. 1. The study of microscopes. 2. , would be helpful in determining the correct lattice symmetry. Finally, the crystallographic crys·tal·log·ra·phy n. The science of crystal structure and phenomena. crys  tal·log databases should be
routinely searched for the same and related materials and to orient o·ri·entv. 1. To locate or place in a particular relation to the points of the compass. 2. To align or position with respect to a point or system of reference. 3. the crystal under study with extant ex·tant adj. 1. Still in existence; not destroyed, lost, or extinct: extant manuscripts. 2. Archaic Standing out; projecting. materials. The above discussion has focused on the cubic crystals characterized by a primitive lattice. However, for cubic crystals, mathematical ambiguities in indexing are not confined con·fine v. con·fined, con·fin·ing, con·fines v.tr. 1. To keep within bounds; restrict: Please confine your remarks to the issues at hand. See Synonyms at limit. to crystals characterized by a cubic primitive lattice. They also occur in the centered cubic lattices. In the cubic F system, there is a ternary lattice metric singularity and in the cubic I system there is a quaternary quaternary /qua·ter·nary/ (kwah´ter-nar?e) 1. fourth in order. 2. containing four elements or groups. qua·ter·nar·y adj. 1. Consisting of four; in fours. lattice metric singularity [9]. Table 10 presents the four lattices in the quaternary LMS. Inspection of Table 10 reveals that the Lattices II-IV are derivative sublattices of lattice I. The volume volume ratios for the four reduced cells for lattices I-IV are 1:1/2:1/3:1/4. As in the ternary LMS in the cubic P system, the reduced forms for lattices I-IV have more specialization than required for the given reduced form type. 6. Conclusion The above analysis shows that lattice metric singularities are inherent in the cubic system. In the Cubic P, I and F systems, we encounter a ternary (in conjunction with a binary), a quaternary, and a ternary lattice metric singularity, respectively. Singularities are a mathematical property of lattices which cannot be ignored. Consequently, one cannot prove that a crystal is cubic by indexing procedures alone. Obviously, it is important to be aware of all members of a singularity. Due to a variety of factors (i.e., quality of data, accidental absences, quality of crystal, etc.), indexing programs may miss some of the members of a given singularity. In the above discussion, it was noted that in experimental practice, it is possible to miss the highest symmetry member of a singularity. When a singularity occurs, which member represents the correct solution? Usually one would expect that the indexing solution with the highest symmetry is the correct solution. But is this a valid assumption? Have certain crystals inadvertently and unknowingly been assigned as·sign tr.v. as·signed, as·sign·ing, as·signs 1. To set apart for a particular purpose; designate: assigned a day for the inspection. 2. an erroneous erroneous adj. 1) in error, wrong. 2) not according to established law, particularly in a legal decision or court ruling. higher crystal symmetry? Alternatively, if a crystal is indexed on the basis of a lower symmetry lattice, is this a valid assumption? The following example illustrates an actual case. 6.1 Singularities in Experimental Practice--Os[O.sub.2] Knowledge of singularities is important in experimental practice. Thus one should be aware when one is dealing with a member of a singularity. For example, a case of especial es·pe·cial adj. 1. Of special importance or significance; exceptional: an occasion of especial joy. 2. interest is Os[O.sub.2] which has been reported [10-13] to be a rutile rutile, mineral, one of three forms of titanium dioxide (TiO2; see titanium). It occurs in crystals, often in twins or rosettes, and is typically brownish red, although there are black varieties. type structure crystallizing in the tetragonal system. An analysis of the reported cell dimensions shows that this lattice is involved in the type of quaternary singularity shown above in Table 10. In fact, the data reported in the Powder Diffraction File [12](PDF (Portable Document Format) The de facto standard for document publishing from Adobe. On the Web, there are countless brochures, data sheets, white papers and technical manuals in the PDF format. no 43-1044) can be refined to yield a cubic I-centered cell [a = 6.36553(2) [Angstrom]] with an excellent figure of merit [M(20) = 178, F(20) = 77)]. Likewise the other two members of this quaternary singularity can also be refined to yield a high figure of merit. In understanding the physical properties of this material, the fact that Os[O.sub.2] is reported as the tetragonal member of a quaternary singularity has practical and theoretical consequences. First, was an error made in symmetry determination? Was it incorrect to assume that this compound is tetragonal like all the other rutile-related structures (see Table II of Rogers, et al. [11]? Most likely an error was not made as Boman [13] has carried out a "precision determination" of the tetragonal crystal structure based on single crystal techniques. Second, if the tetragonal cell and space group are indeed correct, there are interesting implications. This means that the lattice of this compound, in contrast to all the other rutile type structures, is special as it is a rutile structure involved in a singularity. The Os[O.sub.2] crystal would have a superlattice of higher symmetry and be characterized by a powder pattern with far fewer unique d-spacings than related rutile-type materials. 6.2 Singularities Offer Opportunities Lattice metric singularities offer novel opportunities. They provide a mechanism to evaluate powder indexing programs. If working properly, an indexing program should obtain all members of a singularity. From the database building perspective, they provide a mathematical mechanism to evaluate certain types of lattices which are defined by specialized reduced cells. And from the synthetic Synthetic A financial instrument that is created artificially by simulating another instrument with the combined features of a collection of other assets. Notes: perspective, their existence makes it possible to prepare compounds with potentially unusual physical properties.
Table 1. The three lattices involved in a ternary lattice metric
singularity (a). The unique sets of calculated d-spacings for the three
lattices are identical
Lattice
Lattice I: Lattice II: Lattice III: III:
Cubic P Tetragonal P Orthorhombic C Reduced P
Cell 1 Cell 2 Cell 3 Cell 3'
a([Angstrom]) 8.660254 6.123724 4.082483 4.082483
b([Angstrom]) 8.660254 6.123724 12.247449 6.454972
c([Angstrom]) 8.660254 8.660254 8.660254 8.660254
[alpha]([degrees]) 90.0 90.0 90.0 90.0
[beta]([degrees]) 90.0 90.0 90.0 90.0
[gamma]([degrees]) 90.0 90.0 90.0 108.435
V([Angstrom]3) 649.52 324.76 433.01 216.51
c/a 1.4142 2.1213 2.1213
c/b 0.7071 1.3416
(a) Lattice relationships:
Cell 1 [right arrow] Cell 2 T = [0 -1/2 1/2 / 0 1/2 1/2 / -1 0 0]
Cell 1 [right arrow] Cell 3 T = [0 -1/3 1/3 / 0 1 1 / -1 0 0]
Cell 2 [right arrow] Cell 3 T = [0 -2/3 0 / -2 0 0 / 0 0 -1]
Cell 3'[right arrow] Cell 1 T = [2 1 0 / -1 1 0 / 0 0 1]
Cell 2 [right arrow] Cell 1 T = [-1 1 0 / 0 0 1 / 1 1 0]
NIST*LATTICE[6] was used to determine the above and other lattice
relationships cited herein.
Table 2. Reduced form data for cells 1-3 (a) defining Lattices I-III.
The reduced forms for the tetragonal P and the orthorhombic C lattices
have extra specialization
Lattice I: Lattice II:
Cubic P Tetragonal P
Reduced form 3 11
number
Reduced form a*a a*a a*a a*a a*a c*c
definition (b) 0 0 0 0 0 0
Reduced form 75.0 75.0 75.0 37.5 37.5 75.0
([[Angstrom].sup.2]) 0 0 0 0 0 0
Reduced form 1 1 1 1 1 2
normalized 0 0 0 0 0 0
Lattice III:
Orthorhombic C
Reduced form 38
number
Reduced form a*a b*b c*c
definition (b) 0 0 -a*a/2
Reduced form 16.667 41.667 75.0
([[Angstrom].sup.2]) 0 0 -8.331
Reduced form 1 2.5 4.5
normalized 0 0 -0.5
(a) Cell dimensions for cells 1-3 are given in Table 1.
(b) See metric classification of the 44 reduced forms given in Table 2
of Ref.[7].
Table 3. Ternary lattice metric singularity. The values of the
calculated d-spacings ([Angstrom]) for the three lattices are identical
Lattice I: Lattice II: Lattice III:
Cubic P (a) Tetragonal P (b) Orthorhombic C (c)
No. h k l d-calc M (d) h k l d-calc M h k l d-calc M
1 1 0 0 8.6603 1 0 0 1 8.6603 1 0 0 1 8.6603 1
2 1 1 0 6.1237 1 1 0 0 6.1237 1 0 2 0 6.1237 1
3 1 1 1 5.0000 1 1 0 1 5.0000 1 0 2 1 5.0000 1
4 2 0 0 4.3301 1 1 1 0 4.3301 2 0 0 2 4.3301 1
5 2 1 0 3.8730 1 1 1 1 3.8730 1 1 1 0 3.8730 1
6 2 1 1 3.5355 1 1 0 2 3.5355 1 1 1 1 3.5355 2
7 2 2 0 3.0619 1 2 0 0 3.0619 2 0 4 0 3.0619 1
8 3 0 0 2.8868 1 0 0 3 2.8868 2 1 3 0 2.8868 4
9 3 1 0 2.7386 1 2 1 0 2.7386 1 1 3 1 2.7386 1
10 3 1 1 2.6112 1 2 1 1 2.6112 2 0 2 3 2.6112 1
11 2 2 2 2.5000 1 2 0 2 2.5000 1 0 4 2 2.5000 1
12 3 2 0 2.4019 1 1 1 3 2.4019 1 1 3 2 2.4019 1
13 3 2 1 2.3146 1 2 1 2 2.3146 1 1 1 3 2.3146 1
14 4 0 0 2.1651 1 2 2 0 2.1651 2 0 0 4 2.1651 1
15 4 1 0 2.1004 1 2 2 1 2.1004 2 1 5 0 2.1004 2
16 3 3 0 2.0412 1 3 0 0 2.0412 2 0 6 0 2.0412 5
17 3 3 1 1.9868 1 3 0 1 1.9868 2 0 6 1 1.9868 2
18 4 2 0 1.9365 1 3 1 0 1.9365 3 2 2 0 1.9365 1
19 4 2 1 1.8898 1 3 1 1 1.8898 1 2 2 1 1.8898 3
20 3 3 2 1.8464 1 3 0 2 1.8464 1 0 6 2 1.8464 2
21 4 2 2 1.7678 1 3 1 2 1.7678 2 2 2 2 1.7678 2
22 5 0 0 1.7321 1 0 0 5 1.7321 2 0 0 5 1.7321 2
23 5 1 0 1.6984 1 3 2 0 1.6984 2 2 4 0 1.6984 2
24 5 1 1 1.6667 1 3 2 1 1.6667 3 2 4 1 1.6667 4
25 5 2 0 1.6082 1 1 1 5 1.6082 2 1 7 0 1.6082 2
26 5 2 1 1.5811 1 3 2 2 1.5811 1 1 7 1 1.5811 3
27 4 4 0 1.5309 1 4 0 0 1.5309 2 0 8 0 1.5309 1
28 5 2 2 1.5076 1 2 0 5 1.5076 2 0 8 1 1.5076 4
29 5 3 0 1.4852 1 4 1 0 1.4852 2 0 6 4 1.4852 3
30 5 3 1 1.4639 1 4 1 1 1.4639 3 2 4 3 1.4639 1
31 6 0 0 1.4434 1 3 3 0 1.4434 4 2 6 0 1.4434 4
32 6 1 0 1.4237 1 3 3 1 1.4237 1 2 6 1 1.4237 1
33 6 1 1 1.4049 1 4 1 2 1.4049 2 1 7 3 1.4049 2
34 6 2 0 1.3693 1 4 2 0 1.3693 3 2 6 2 1.3693 1
35 6 2 1 1.3525 1 4 2 1 1.3525 3 0 8 3 1.3525 3
36 5 4 1 1.3363 1 3 2 4 1.3363 1 3 1 1 1.3363 3
37 5 3 3 1.3207 1 4 1 3 1.3207 2 0 6 5 1.3207 2
38 6 2 2 1.3056 1 4 2 2 1.3056 2 0 4 6 1.3056 1
39 6 3 0 1.2910 1 3 3 3 1.2910 2 1 9 0 1.2910 7
40 6 3 1 1.2769 1 2 1 6 1.2769 1 1 9 1 1.2769 2
(a) Cell 1 (Cubic P): a = 8.660254 [Angstrom], V = 649.52
[[Angstrom].sup.3].
(b) Cell 2 (Tetragonal P): a = 6.123724 [Angstrom], c = 8.660254
[Angstrom], V = 324.76 [[Angstrom].sup.3].
(c) Cell 3 (Orthorhombic C): a = 4.082483 [Angstrom], b = 12.247449
[Angstrom] c = 8.660254 [Angstrom], V = 433.01 [[Angstrom].sup.3].
(d) Number of lines calculated (NBS*AIDS83[8]) with the specified
d-spacing value.
Table 4. Ternary lattice metric singularity. The d-spacings for each
lattice were calculated (a) using the specified 2[theta] maximum values
and [lambda] = 0.7093 [Angstrom]. The number of unique d-spacings for
the three lattices is identical. The low values for the compression
ratios for lattices II and III show that they are specialized (i.e.,
many d-spacings have the same value)
2[theta] Unique Total Compression
Maximum d-spacings d-spacings Ratio (b)
40 59 59 1
Cell 1 (c) 45 74 74 1
Lattice 1 50 90 90 1
55 106 106 1
40 59 117 0.504
Cell 2 (d) 45 74 157 0.471
Lattice II 50 90 202 0.446
55 106 251 0.422
40 59 140 0.421
Cell 3 (e) 45 74 189 0.392
Lattice III 50 90 251 0.359
55 106 322 0.329
(a) NBS*AIDS83[8].
(b) Compression ratio = "unique d-spacings / possible d-spacings" for a
given symmetry.
(c) Cell 1 (Cubic P): a = 8.660254 [Angstrom], V = 649.52
[[Angstrom].sup.3].
(d) Cell 2 (Tetragonal P): a = 6.123724 [Angstrom], c = 8.660254
[Angstrom], V = 324.76 [[Angstrom].sup.3].
(e) Cell 3 (Orthorhombic C): a = 4.082483 [Angstrom], b = 12.247449
[Angstrom], c = 8.660254 [Angstrom], V = 433.01 [[Angstrom].sup.3].
Table 5. The two lattices involved in a binary lattice metric
singularity (a). The unique sets of calculated d-spacings for the two
lattices are identical
Lattice IV: Lattice V:
Orthorhombic P Hexagonal P
Cell 4 Cell 5
a([Angstrom]) 5.0 10.0
b([Angstrom]) 6.123724 10.0
c([Angstrom]) 8.660254 6.123724
[alpha]([degrees]) 90.0 90.0
[beta]([degrees]) 90.0 90.0
[gamma]([degrees]) 90.0 120.0
V([[Angstrom].sup.3]) 265.17 530.33
c/a 1.7320 0.6124
c/b 1.4142
(a) Lattice relationships:
Cell 4 [right arrow] Cell 5 T = [2 0 0 / - 1 0 -1 / 0 1 0].
NIST*LATTICE[6]was used to determine these and other lattice
relationships cited herein.
Table 6. Reduced form data for cells 4-5 (a) defining Lattices IV-V.
Both reduced forms have extra specialization
Lattice IV: Lattice V:
Orthorhombic P Hexagonal P
Reduced form 32 22
number
Reduced form a*a b*b c*c a*a b*b b*b
definition (b) 0 0 0 -b*b/2 0 0
Reduced form 25.0 37.5 75.0 37.5 100 100
([[Angstrom].sup.2]) 0 0 0 -50 0 0
Reduced form 1 1.5 3 1 2.67 2.67
normalized 0 0 0 -1.33 0 0
(a) Cell dimensions for cells 4-5 are given in Table 5.
(b) See metric classification of the 44 reduced forms given in Table 2
of Ref.[7].
Table 7. Binary lattice metric singularity. The values of the calculated
d-spacings for the two lattices are identical
Lattice I: Lattice II:
Orthorhombic (a) Hexagonal (b)
No. h k l d-calc M (c) h k l d-calc M
1 0 0 1 8.6603 1 1 0 0 8.6603 1
2 0 1 0 6.1237 1 0 0 1 6.1237 1
3 1 0 0 5.0000 2 1 0 1 5.0000 2
4 1 0 1 4.3301 2 2 0 0 4.3301 1
5 1 1 0 3.8730 1 1 1 1 3.8730 1
6 1 1 1 3.5355 2 2 0 1 3.5355 1
7 1 0 2 3.2733 1 2 1 0 3.2733 1
8 0 2 0 3.0619 1 0 0 2 3.0619 1
9 0 0 3 2.8868 3 3 0 0 2.8868 3
10 1 2 0 2.6112 2 3 0 1 2.6112 2
11 2 0 0 2.5000 4 2 0 2 2.5000 2
12 2 0 1 2.4019 1 3 1 0 2.4019 1
13 2 1 0 2.3146 2 2 2 1 2.3145 1
14 2 1 1 2.2361 2 3 1 1 2.2361 2
15 2 0 2 2.1651 2 4 0 0 2.1651 1
16 0 2 3 2.1004 1 3 0 2 2.1004 1
17 0 3 0 2.0412 3 4 0 1 2.0412 2
18 0 3 1 1.9868 2 3 2 0 1.9868 2
19 2 2 0 1.9365 2 2 2 2 1.9365 1
20 1 3 0 1.8898 4 1 1 3 1.8898 4
21 0 3 2 1.8464 2 2 0 3 1.8464 1
22 2 1 3 1.8058 1 4 1 1 1.8058 1
23 2 2 2 1.7678 2 4 0 2 1.7678 1
24 0 0 5 1.7321 2 5 0 0 1.7321 2
25 3 0 0 1.6667 4 5 0 1 1.6667 4
26 1 0 5 1.6366 3 4 2 0 1.6366 1
27 3 1 0 1.6082 2 3 3 1 1.6082 2
28 2 3 0 1.5811 5 4 2 1 1.5811 2
29 2 3 1 1.5554 2 5 1 0 1.5554 2
30 0 4 0 1.5309 1 0 0 4 1.5309 1
31 3 1 2 1.5076 3 5 1 1 1.5076 3
32 2 3 2 1.4852 2 4 0 3 1.4852 1
33 1 4 0 1.4639 2 1 1 4 1.4639 2
34 3 0 3 1.4434 7 6 0 0 1.4434 3
35 1 3 4 1.4237 2 4 3 0 1.4237 2
36 3 1 3 1.4049 2 6 0 1 1.4049 1
37 3 2 2 1.3868 5 5 2 0 1.3868 5
38 1 1 6 1.3525 2 3 0 4 1.3525 2
39 3 0 4 1.3207 2 6 1 0 1.3207 2
40 2 4 0 1.3056 4 6 0 2 1.3056 2
(a) Cell 4 (Orthorhombic P): a = 5.0 [Angstrom], b = 6.123724
[Angstrom], c = 8.660254 [Angstrom], V = 265.17 [[Angstrom].sup.3].
(b) Cell 5 (Hexagonal P): a = 10.0 [Angstrom], c = 6.123724 [Angstrom],
V = 530.33 [[Angstrom].sup.3].
(c) Number of lines calculated (NBS*AIDS83[8]) with the specified d-
spacing value.
Table 8. Binary lattice metric singularity. The d-spacings for each
lattice were calculated (a) using the specified 2[theta] maximum values
and [lambda] = 0.7093 [Angstrom]. The number of unique d-spacings for
the two lattices is identical. The low values for the compression ratios
for lattices IV and V show that they are special (i.e., many d-spacings
have the same value)
2[theta] Unique Total Compression
Maximum d-spacings d-spacings Ratio (b)
40 64 174 0.368
Cell 4 (c) 45 81 242 0.335
Lattice IV 50 97 306 0.317
55 117 400 0.292
40 64 126 0.508
Cell 5 (d) 45 81 171 0.474
Lattice V 50 97 215 0.451
55 117 275 0.425
(a) NBS*AIDS83[8].
(b) Compression ratio = "unique d-spacings/possible d-spacings" for a
given symmetry.
(c) Cell 4 (Orthorhombic P): a = 5.0 [Angstrom], b = 6.123724
[Angstrom], c = 8.660254 [Angstrom], V = 265.17 [[Angstrom].sup.3].
(d) Cell 5 (Hexagonal P): a = 10.0 [Angstrom], c = 6.123724 [Angstrom],
V = 530.33 [[Angstrom].sup.3].
Table 9. Conjunction of a Ternary (Lattices I, II, III) and a Binary
(Lattices IV and V) Lattice Metric Singularity. The sets of calculated
d-spacings ([Angstrom]) for the lattices in the ternary (I, II, III) and
binary (IV, V) singularities are almost identical
Lattice I: Lattice II: Lattice III:
Cubic P (a) Tetragonal P (b) Orthorhombic C (c)
No d-calc d-calc d-calc
1 8.6603 8.6603 8.6603
2 6.1237 6.1237 6.1237
3 5.0000 5.0000 5.0000
4 4.3301 4.3301 4.3301
5 3.8730 3.8730 3.8730
6 3.5355 3.5355 3.5355
7
8 3.0619 3.0619 3.0619
9 2.8868 2.8868 2.8868
10 2.7386 2.7386 2.7386
11 2.6112 2.6112 2.6112
12 2.5000 2.5000 2.5000
13 2.4019 2.4019 2.4019
14 2.3146 2.3146 2.3146
15
16 2.1651 2.1651 2.1651
17 2.1004 2.1004 2.1004
18 2.0412 2.0412 2.0412
19 1.9868 1.9868 1.9868
20 1.9365 1.9365 1.9365
21 1.8898 1.8898 1.8898
22 1.8464 1.8464 1.8464
Lattice IV: Lattice V:
Orthorhombic P (d) Hexagonal P (e)
No d-calc d-calc
1 8.6603 8.6603
2 6.1237 6.1237
3 5.0000 5.0000
4 4.3301 4.3301
5 3.8730 3.8730
6 3.5355 3.5355
7 3.2733 3.2733
8 3.0619 3.0619
9 2.8868 2.8868
10
11 2.6112 2.6112
12 2.5000 2.5000
13 2.4019 2.4019
14 2.3146 2.3145
15 2.2361 2.2361
16 2.1651 2.1651
17 2.1004 2.1004
18 2.0412 2.0412
19 1.9868 1.9868
20 1.9365 1.9365
21 1.8898 1.8898
22 1.8464 1.8464
(a) Cell 1 (Cubic P): a = 8.660254 [Angstrom], V = 649.52
[[Angstrom].sup.3].
(b) Cell 2 (Tetragonal P): a = 6.123724 [Angstrom], c = 8.660254
[Angstrom], V = 324.76 [[Angstrom].sup.3].
(c) Cell 3 (Orthorhombic C): a = 4.082483 [Angstrom], b = 12.247449
[Angstrom], c = 8.660254 [Angstrom], V = 433.01 [[Angstrom].sup.3].
(d) Cell 4 (Orthorhombic P): a = 5.0 [Angstrom], b = 6.123724
[Angstrom], c = 8.660254 [Angstrom], V = 265.17 [[Angstrom].sup.3].
(e) Cell 5 (Hexagonal P): a = 10.0 [Angstrom], c = 6.123724 [Angstrom],
V = 530.33 [[Angstrom].sup.3].
Table 10. Quaternary lattice metric singularity. The four lattices yield
the same set of unique calculated d-spacings. For each lattice the table
gives the conventional cell along with the corresponding reduced cell
and normalized reduced form
Lattice I: Lattice II:
Cubic I Tetragonal P
Conventional Cells
Cell Cell 1 Cell 2
a([Angstrom]) 8.6603 6.1237
b([Angstrom]) 8.6603 6.1237
c([Angstrom]) 8.6603 4.3301
[alpha]([degrees]) 90.0 90.0
[beta]([degrees]) 90.0 90.0
[gamma]([degrees]) 90.0 90.0
V([[Angstrom].sup.3]) 649.52 162.38
a/c 1.0 [square root of 2]
b/c 1.0 [square root of 2]
Reduced Cells
Cell R1 R2 (a)
a([Angstrom]) 7.5000 4.3301
b([Angstrom]) 7.5000 6.1237
c([Angstrom]) 7.5000 6.1237
[alpha]([degrees]) 109.471 90.0
[beta]([degrees]) 109.471 90.0
[gamma]([degrees]) 109.471 90.0
V([[Angstrom].sup.3]) 324.76 162.38
Normalized Reduced Forms
Form F1 F2
a*a 1 1
b*b 1 2
c*c 1 2
b*c -1/3 0
a*c -1/3 0
a*b -1/3 0
Form No. 5 21
Lattice III: Lattice IV:
Orthorhombic F Orthorhombic P
Conventional Cells
Cell Cell 3 Cell 4
a([Angstrom]) 4.0825 3.0619
b([Angstrom]) 8.6603 4.3301
c([Angstrom]) 12.2475 6.1237
[alpha]([degrees]) 90.0 90.0
[beta]([degrees]) 90.0 90.0
[gamma]([degrees]) 90.0 90.0
V([[Angstrom].sup.3]) 433.01 81.19
a/c 1/3 1/2
b/c [square root of (1/2)] [square root of (1/2)]
Reduced Cells
Cell R3 (b) R4 (c)
a([Angstrom]) 4.0825 3.0619
b([Angstrom]) 4.7871 4.3301
c([Angstrom]) 6.4550 6.1237
[alpha]([degrees]) 82.251 90.0
[beta]([degrees]) 71.565 90.0
[gamma]([degrees]) 64.761 90.0
V([[Angstrom].sup.3]) 108.25 81.19
Normalized Reduced Forms
Form F3 F4
a*a 1 1
b*b 1.375 2
c*c 2.500 4
b*c 1/4 0
a*c 1/2 0
a*b 1/2 0
Form No. 26 32
Transformations
(a) R2 [right arrow] R1 [1 -1 0 / -1 0 1 / -1 0 -1] [DELTA] = 2.
(b) R3 [right arrow] R1 [1 1 0 / -2 1 0 / 0 -1 1] [DELTA] = 3.
(c) R4 [right arrow] R1 [0 -1 -1 / 2 1 0 / 0 -1 1] [DELTA] = 4.
Accepted: November November: see month. 17, 2004 Available online: http://www.nist.gov/jres 7. References [1] A. Boultif and D. Louer, Indexing of Powder Diffraction Patterns for Low-Symmetry Lattices by the Successive Dichotomy di·chot·o·my n. pl. di·chot·o·mies 1. Division into two usually contradictory parts or opinions: "the dichotomy of the one and the many" Louis Auchincloss. Method, J. Appl. Crystallogr. 24, 987-993 (1991). [2] P.-E. Werner Werner is a name of Germanic origins that could refer to numerous people or entities.
The oldest known usage of the name was in the Habsburg family.
[3] P. M. de Wolff, A Simplified sim·pli·fy tr.v. sim·pli·fied, sim·pli·fy·ing, sim·pli·fies To make simple or simpler, as: a. To reduce in complexity or extent. b. To reduce to fundamental parts. c. Criterion
[4] G. S. Smith and R. L. Snyder, [F.sub.N]: A Criterion for Rating Powder Diffraction Patterns and Evaluating the Reliability of Powder-Pattern Indexing, J. Appl. Crystallogr. 12, 60-65 (1979). [5] A. D. Mighell and A. Santoro Santoro is an Italian surname and may refer to the following people:
adj. 1. a. Of or relating to geometry and its methods and principles. b. Increasing or decreasing in a geometric progression. 2. Ambiguities in the Indexing of Powder Patterns, J. Appl. Crystallogr. 8, 372-374 (1975). [6] V. L. Karen Karen Any member of a variety of tribal peoples of southern Myanmar (Burma). Constituting the second largest minority in Myanmar, the Karen are not a unitary group in any ethnic sense, as they differ among themselves linguistically, religiously, and economically. and A. D. Mighell, NIST*LATTICE-A Program to Analyze an·a·lyze v. 1. To examine methodically by separating into parts and studying their interrelations. 2. To separate a chemical substance into its constituent elements to determine their nature or proportions. 3. Lattice Relationships, Version of Spring 1991, NIST Technical Note 1290 (1991). National Institute of Standards and Technology National Institute of Standards and Technology, governmental agency within the U.S. Dept. of Commerce with the mission of "working with industry to develop and apply technology, measurements, and standards" in the national interest. , Gaithersburg, MD, 20899. [7] A. D. Mighell, Lattice Symmetry and Identification--The Fundamental Role of Reduced Cells in Materials Characterization A rather long and fancy word for analyzing a system or process and measuring its "characteristics." For example, a Web characterization would yield the number of current sites on the Web, types of sites, annual growth, etc. , J. Res. Natl. Inst. Stand. Technol. 106, 983-995 (2001). [8] A. D. Mighell, C. R. Hubbard, and J. K. Stalick, NBS*AIDS80: A FORTRAN Program Noun 1. FORTRAN program - a program written in FORTRAN computer program, computer programme, programme, program - (computer science) a sequence of instructions that a computer can interpret and execute; "the program required several hundred lines of code" for Crystallographic Data Evaluation, National Bureau of Standards National Bureau of Standards: see National Institute of Standards and Technology. National Bureau of Standards - National Institute of Standards and Technology (U.S.), NBS Technical Note 1141 (1981). (NBS*AIDS83 is a development of NBS*AIDS80). [9] A. D. Mighell, Ambiguities in powder pattern indexing: A ternary lattice metric singularity, Powder Diffraction 16, 144-148 (2001). [10] P. C. Yen, R. S. Chen, C. C. Chen, Y. S. Huang Huang (Chinese: 黃) is a Chinese surname. While Huang is the pinyin romanisation of the word, it may also be romanised as Wong, Vong, Bong, Ng, Uy, Wee, Oi, Oei or Ooi, Ong, Hwang, or Ung due to pronunciations of the word in , and K. K. Tiong, Growth and characterization of Os[O.sub.2] single crystals, J. of Crystal Growth 262, 271-276 (2004). [11] D. B. Rogers, R. D. Shannon Shannon, principal river of the Republic of Ireland and longest (c.240 mi/390 km) in the British Isles. It rises near Cuilcagh Mt., NW Co. Cavan, and flows S through the Central Plain into Co. Limerick, where it turns west in a broad estuary (c. , A. W. Sleight and J. L. Gillson, Crystal Chemistry of Metal Dioxides with Rutile-Related Structures, Inorganic Chem. 8, 841-849 (1969). [12] Powder Diffraction File (PDF), International Centre for Diffraction Data The International Centre for Diffraction Data (ICDD) maintains a database of powder diffraction patterns, the Powder Diffraction File (PDF), including the d-spacings (related to angle of diffraction) and relative intensities of observable diffraction peaks. (ICDD ICDD Illinois Council on Developmental Disabilities ICDD Interface Control/Design Document ), Newtown Newtown, town (1990 pop. 20,779), Fairfield co., SW Conn., on the Housatonic; inc. 1711. Pressure gauges, plastics, and paper and metal products are made, and dairy and fruit farms are in the area. Square, 12 Campus Blvd Blvd abbr (= boulevard) → Bd ., Newton Newton, cities, United States Newton. 1 City (1990 pop. 16,700), seat of Harvey co., S central Kans., in an agricultural area; inc. 1872. Square, PA 19073-3273. [13] C.-E. Boman, Precision Determination of the Crystal Structure of Osmium osmium (ŏz`mēəm), metallic chemical element; symbol Os; at. no. 76; at. wt. 190.2; m.p. 3,045±30°C;; b.p. 5,027±100°C;; sp. gr. 22.57 at 20°C;; valence usually +0 to +8. Dioxide dioxide /di·ox·ide/ (-ok´sid) an oxide with two oxygen atoms. di·ox·ide n. A compound containing two oxygen atoms per molecule. , Acta acta (ăk`tə), official texts of ancient Rome, written or carved on stone or metal. Usually acta were texts made public, although publication was sometimes restricted. Acta were first posted or carved for general reading c.131 B.C. Chem. Scand Scand Scandinavian . 24, 123-128 (1970). Alan A`lan´ n. 1. A wolfhound. D. Mighell National Institute of Standards and Technology, Gaithersburg, MD 20899-8520 alan.mighell@nist.gov See .gov and GovNet. (networking) gov - The top-level domain for US government bodies. About the author: Alan D. Mighell has been a research scientist at NIST since 1964. His research interests include structural crystallography and the design and development of mathematical procedures for materials identification, for establishing lattice relationships, and for the evaluation of crystallographic data. The National Institute of Standards and Technology is an agency of the Technology Administration, U.S. Department of Commerce. |
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