Lattice symmetry and identification - the fundamental role of reduced cells in materials characterization.In theory, physical crystals can be represented by idealized i·de·al·ize v. i·de·al·ized, i·de·al·iz·ing, i·de·al·iz·es v.tr. 1. To regard as ideal. 2. To make or envision as ideal. v.intr. 1. mathematical lattices. Under appropriate conditions, these representations can be used for a variety of purposes such as identifying, classifying, and understanding the physical properties of materials. Critical to these applications is the ability to construct a unique representation of the 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 . The vital link that enabled this theory to be realized in practice was provided by the 1970 paper on the determination of reduced cells. This seminal seminal /sem·i·nal/ (sem´i-n'l) pertaining to semen or to a seed. sem·i·nal adj. Of, relating to, containing, or conveying semen or seed. paper led to a mathematical approach to lattice analysis initially based on systematic reduction procedures and the use of standard cells. Subsequently, the process evolved to a matrix approach based on group theory and linear algebra linear algebra Branch of algebra concerned with methods of solving systems of linear equations; more generally, the mathematics of linear transformations and vector spaces. that offered a more abstract and powerful way to look at lattices and their properties. Application of the reduced cell to both database work and laboratory research at NIST (National Institute of Standards & Technology, Washington, DC, www.nist.gov) The standards-defining agency of the U.S. government, formerly the National Bureau of Standards. It is one of three agencies that fall under the Technology Administration (www.technology. was immediately successful. Currently, this cell and/or and/or conj. Used to indicate that either or both of the items connected by it are involved. Usage Note: And/or is widely used in legal and business writing. procedures based on reduction are widely and r outinely used by the general scientific community: (i) for calculating standard cells for the reporting of crystalline Like a crystal. It implies a uniform structure of molecules in all dimensions. For example, phase change technology, widely used for rewritable optical discs, uses crystalline spots (bits) to reflect the laser beam. Amorphous, non-crystalline bits do not reflect light. materials, (ii) for classifying materials, (iii) in crystallographic crys·tal·log·ra·phy n. The science of crystal structure and phenomena. crys  tal·log database work (iv) in routine x-ray X-rayElectromagnetic radiation of extremely short wavelength (100 nanometres to 0.001 nanometre) produced by the deceleration of charged particles or the transitions of electrons in atoms. and neutron neutron, uncharged elementary particle of slightly greater mass than the proton. It was discovered by James Chadwick in 1932. The stable isotopes of all elements except hydrogen and helium contain a number of neutrons equal to or greater than the number of protons. diffractometry, and (v) in general crystallographic research. Especially important is its use in 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. determination and in identification. The focus herein is on the role of the reduced cell in lattice symmetry determination. Key words: crystallography; identification; mathematical lattices; reduction; symmetry determination. 1. Introduction In theory, physical crystals can be represented by idealized mathematical lattices. Under appropriate conditions, these representations can be used for a variety of purposes such as identifying, classifying, and understanding the physical properties of materials. Critical to these applications is the ability to construct a unique (1) representation of the lattice. The vital link that enabled this theory to be realized in practice was provided by a 1970 paper on the determination of reduced cells by Santoro Santoro is an Italian surname and may refer to the following people:
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 Mighell (3,4) based on group theory and linear algebra that offered a more abstract and powerful way look at lattices and their properties. Conceptually con·cep·tu·al adj. 1. Of or relating to concepts or mental conception: conceptual discussions that antedated development of the new product. 2. Of or relating to conceptualism. , the reduced cell is a unique primitive cell 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. based on the shortest three lattice translations. As it can be determined from any cell of any lattice and because it has an exact mathematical definition, it can be used as a standard cell. As such in one way or another it has been widely accepted and is routinely used in virtually every crystallographic laboratory worldwide. Application of this cell to both our database work and our laboratory research at NIST was immediately successful. Currently, this cell and/or procedures based on reduction are extensively used: (i) in calculating standard cells for the reporting of crystalline materials, (ii) in classifying materials, (iii) in crystallographic database work (iv) in routine x-ray and neutron diffractometry, and (v) in general crystallographic research. Especially important is its use in identification and in symmetry determination. 1.1 Identification At NIST, a new and highly selective analytical analytical, analytic pertaining to or emanating from analysis. analytical control control of confounding by analysis of the results of a trial or test. method for the identification of crystalline compounds was created (5-7). In practice, this procedure--based on cell-element type matching of the unknown against a file of known materials represented by their respective reduced cells--has proved an extremely practical and reliable technique to identify unknown materials. The uniqueness of the procedure was first demonstrated using the NBS (National Bureau of Standards) See NIST. NBS - National Bureau of Standards: part of the US Department of Commerce, now NIST. TODARS System (Terminal oriented o·ri·ent n. 1. Orient The countries of Asia, especially of eastern Asia. 2. a. The luster characteristic of a pearl of high quality. b. A pearl having exceptional luster. 3. Data and Analysis and Retrieval retrieval /re·triev·al/ (-tre´v'l) in psychology, the process of obtaining memory information from wherever it has been stored. re·triev·al n. System) at the Clemson ACA ACA - Application Control Architecture Meeting in 1976. Today the scientific community routinely uses this identification strategy, as it has been integrated into commercial x-ray diffractometers (8). In addition, the identification procedure--integrated into database distribution software--is routinely used in identifying unknowns against the various crystallographic databases. Finally, because of its high selectivity selectivity /se·lec·tiv·i·ty/ (se-lek-tiv´i-te) in pharmacology, the degree to which a dose of a drug produces the desired effect in relation to adverse effects. selectivity 1. , the method plays a critical role in the linking of data on a given material that appears in different scientific databases. This ability paves the way to the efficient use of multiple databases in the knowledge-based design and 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. of new materials. 1.2 Symmetry Determination Because the reduced cell is a unique standard cell, it can be used to determine the metric symmetry of a material as described by Mighell, Santoro, and Donnay Donnay is a commune of the département of Calvados, in the Basse-Normandie région, in France. Its postal code is 14220. The INSEE code is 14226. Coordinates: in the International Tables for X-Ray Crystallography X-ray crystallography, the study of crystal structures through X-ray diffraction techniques. When an X-ray beam bombards a crystalline lattice in a given orientation, the beam is scattered in a definite manner characterized by the atomic structure of the lattice. (9). The focus of this paper will be on the role of the reduced cell and form in symmetry determination of an original lattice and of the associated derivative derivative: see calculus. derivative In mathematics, a fundamental concept of differential calculus representing the instantaneous rate of change of a function. lattices. In addition, the impact of 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. 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: on lattice properties such as lattice metric singularities will be analyzed an·a·lyze tr.v. an·a·lyzed, an·a·lyz·ing, an·a·lyz·es 1. To examine methodically by separating into parts and studying their interrelations. 2. Chemistry To make a chemical analysis of. 3. . Research has shown that there exists a close link between metric and crystal symmetry. Consequently, symmetry determination procedures based on reduction and reduced forms are widely used in the software that is associated with automated au·to·mate v. au·to·mat·ed, au·to·mat·ing, au·to·mates v.tr. 1. To convert to automatic operation: automate a factory. 2. x-ray diffractometers. Likewise they are used by the crystallographic data centers to critically evaluate symmetry. 2. Determination of the Bravais Lattice Noun 1. Bravais lattice - a 3-dimensional geometric arrangement of the atoms or molecules or ions composing a crystal crystal lattice, space lattice lattice - an arrangement of points or particles or objects in a regular periodic pattern in 2 or 3 dimensions and Conventional Cell A cell is reduced provided it satisfies both the main and special conditions for reduction as given in Table 1. The main conditions are used to establish that a cell is based on the three shortest lattice translations whereas the special conditions serve to select a unique cell when two or more cells in the lattice have the same numerical numerical expressed in numbers, i.e. Arabic numerals of 0 to 9 inclusive. numerical nomenclature a numerical code is used to indicate the words, or other alphabetical signals, intended. values for the cell edges. Procedures and transformation matrices for calculating this cell are given in (2) and in Karen and Mighell (6) and are incorporated into the computer program NIST*LATTICE (10). From the reduced cell, the reduced form (a*a b*b c*c/b*c a*c a*b) is determined which can then be used to determine the metric symmetry (#) of the lattice via table lookup Searching for one item in a list or matrix of data (the table). Table lookups are used in countless operations to obtain a value or set of values such as retail and wholesale prices, product descriptions, street addresses, network routes, IP addresses and machine addresses. procedures. As the metric symmetry is highly correlated cor·re·late v. cor·re·lat·ed, cor·re·lat·ing, cor·re·lates v.tr. 1. To put or bring into causal, complementary, parallel, or reciprocal relation. 2. with the crystal symmetry, such lookup A data search performed within a predefined table of values (array, matrix, etc.) or within a data file. procedures are widely used in modern crystallography--e.g. in automated single-crystal x-ray diffractometers. 2.1 Classification of the 44 Reduced Forms In Table 2, the 44 reduced forms and the corresponding conventional cells are presented in a simple format. This table is a slight modification of Table 5.1.3.1, which was published in the International Tables for X-Ray Crystallography (1969) (9). It is a shortened short·en v. short·ened, short·en·ing, short·ens v.tr. 1. To make short or shorter. 2. version with appropriate errata er·ra·ta n. Plural of erratum. and addenda (11,12,13). Table 2 gives the transformation matrices relating the reduced cell to the corresponding conventional cell. For convenience, the reduced forms are grouped into four categories: 1) a = b = c; 2) a = b = c; 2 a = b [less than or equal to] c; 3) a [less than or equal to] b = c; and 4) a [less than or equal to] b [less than or equal to] c (i.e., no special conditions other than those required for the reduced cell). Within each category, the reduced forms are further divided into positive and negative reduced forms. To match a reduced form against the table, one starts with the highest possible category and works down. Once a match is found, the experimentalist can transform the reduced cell to the conventional cell using the matrix given in the last column of the table. 2.2 Rules for the Conventional Cells The conventional cells obtained by using Table 2 are logical cells for the reporting of crystallographic results as they are based on both symmetry and metric considerations. For cell edges not defined by symmetry, the shortest edges are used. The following conventions apply: (1) In the hexagonal hex·ag·o·nal adj. 1. Having six sides. 2. Containing a hexagon or shaped like one. 3. Mineralogy and tetragonal tet·ra·gon n. A four-sided polygon; a quadrilateral. [Late Latin tetrag systems, c is taken as the unique axis. (2) In the rhombohedral system (Crystallog.) a division of the hexagonal system embracing the rhombohedron, scalenohedron, etc. See also: Rhombohedral , the triply 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. hexagonal cell is used. (3) In the orthorhombic or·tho·rhom·bic adj. Of or relating to a crystalline structure of three mutually perpendicular axes of different length. orthorhombic system, the axes axes [L., Gr.] plural of axis. The straight lines which intersect at right angles and on which graphs are drawn. Usually the horizontal axis is the x-axis and the vertical one the y-axis. Called also axes of reference. of the primitive, body-centered, and face-centered cells are labeled to obey Obey can refer to:
adj. Of or relating to three unequal crystal axes, two of which intersect obliquely and are perpendicular to the third. monoclinic Adjective Crystallog system, b is taken as the unique axis, and a and c are chosen coincident co·in·ci·dent adj. 1. Occupying the same area in space or happening at the same time: a series of coincident events. See Synonyms at contemporary. 2. with the shortest two translations in the net perpendicular to b. (To assure the shortest translations, the conditions in the footnote Text that appears at the bottom of a page that adds explanation. It is often used to give credit to the source of information. When accumulated and printed at the end of a document, they are called "endnotes." for the specified spec·i·fy tr.v. spec·i·fied, spec·i·fy·ing, spec·i·fies 1. To state explicitly or in detail: specified the amount needed. 2. To include in a specification. 3. centered monoclinic lattices must be checked. In those cases for which the transformation matrix in the footnote premultiplies a given table matrix, the result ant cell centering is indicated in parentheses See parenthesis. parentheses - See left parenthesis, right parenthesis. following the transformation matrix.) The angle [beta] is taken to be non-acute. This choice allows primitive, side-centered, and body-centered cells. In the primitive and body-centered cells a and c obey a < c. The side-centered cell is taken as C-centered. (5) In the triclinic system, the conventional cell is the reduced cell with a [less than or equal to] b [less than or equal to] c. 2.3 Adoption of the Conventional Cells by the Scientific Community Today, conventional cells as specified above for Table 2--or closely related cells--are widely used for the reporting of crystallographic results in the scientific literature. For example, this is true for almost all structures reported in the Journals ChemCom and 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. Crystallographica C. As soon as it was published, Table 2 was integrated into the software associated with automated single-crystal x-ray diffractometers that collect the data. In addition, to facilitate the use of these conventions, Volume A of the International Tables for Crystallography has been expanded to give explicitly the required space group settings in the monoclinic system (e.g. the atomic Indivisible. An atomic operation, or atomicity, implies an operation that must be performed entirely or not at all. For example, if machine failure prevents a transaction to be processed to completion, the system will be rolled back to the start of the transaction. positions in an I-centered cell). The widespread acceptance and use of these conventions has had a major scientific impact both in solving structures and interpreting in·ter·pret v. in·ter·pret·ed, in·ter·pret·ing, in·ter·prets v.tr. 1. To explain the meaning of: interpreted the ambassador's remarks. See Synonyms at explain. the results of structure determinations. For example, use of the conventions has made structure determination more efficient, prevented duplicate DUPLICATE. The double of anything. 2. It is usually applied to agreements, letters, receipts, and the like, when two originals are made of either of them. Each copy has the same effect. structure determinations, helped to eliminate errors in symmetry determination, and helped prevent confusion especially in working with monoclinic structures, which include approximately ap·prox·i·mate adj. 1. Almost exact or correct: the approximate time of the accident. 2. 70 % of all organic and organometallic organometallic /or·ga·no·me·tal·lic/ (-me-tal´ik) consisting of a metal combined with an organic radical, used particularly for a compound in which the metal is linked directly to a carbon atom. crystalline compounds. 3. Population Statistics The reduced cell and reduced form are routinely calculated using NBS*AIDS83 (14) for all compounds entering the various crystallographic databases including the Cambridge Structural Database The Cambridge Structural Database (CSD), is a repository for small molecule crystal structures. Scientists use x-ray crystallography to determine the packing of individual molecules in a crystal. (15), and the ICDD ICDD Illinois Council on Developmental Disabilities ICDD Interface Control/Design Document 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. File (16) and NIST Crystal Data (17). For organic compounds in NIST Crystal Data, Tables 3, 4, and 5 give the metric lattice statistics for the 44 reduced forms, the 14 Bravais lattices, and the 7 crystal systems, respectively. These results are in sharp contrast to the corresponding population statistics 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 for which the higher symmetry reduced forms, Bravais lattices and crystal systems are more heavily populated pop·u·late tr.v. pop·u·lat·ed, pop·u·lat·ing, pop·u·lates 1. To supply with inhabitants, as by colonization; people. 2. . Table 3 shows that most organic compounds (82 %) crystallize crys·tal·lize also crys·tal·ize v. crys·tal·lized also crys·tal·ized, crys·tal·liz·ing also crys·tal·iz·ing, crys·tal·liz·es also crys·tal·iz·es v.tr. 1. in lattices that are 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 only 6 of the 44 reduced forms (31-35, 44). Furthermore, collectively many materials (9.5 %) crystallize in the 13 side-centered monoclinic reduced forms (10, 14, 17, 20, 25, 27-30, 37, 39, 41, and 43). Table 4 shows that most organic compounds crystallize in a triclinic, monoclinic, or orthorhombic Bravais lattice with the primitive lattice (87.1 %) by far the most common. Table 5 shows the distribution by crystal system. Only 5.8 % of organic compounds are in the higher symmetry--rhombohedral, tetragonal, hexagonal and cubic--crystal systems. A comparison of the statistics with those reported earlier (18) shows the same general distribution. However, as molecules studied become larger and more complex, the triclinic system becomes more common (19.8 % vs 15 %). 4. Applications in Routine Diffractometry and in Data Evaluation 4.1 Routine Diffractometry The reduced cell is a standard cell that can be calculated (10) from any experimentally determined cell that defines the lattice. From this unique cell, one calculates the reduced form, which is then used to establish--by matching against the 44 reduced forms in Table 2--the metric lattice symmetry. Research with the crystallographic databases has proved that the metric and crystal symmetry are almost always the same. Furthermore, crystal symmetry can never exceed the lattice metric symmetry (e.g., if the metric symmetry is triclinic, the crystal symmetry must be triclinic). Consequently, as an integral part of the strategy for symmetry determination (19) outlined in Fig. 1, the experimentalist first establishes the metric symmetry and then the crystal symmetry. Thus in modern diffractometry, automated procedures use reduction procedures: (i) to establish if the compound has previously been investigated (8) and (ii) to obtain the metric symmetry. 4.2 Data Evaluation on Individual Entries Because of the link between metric and crystal symmetry, the relationships in Table 2 are routinely used by the Crystallographic Data Centers in the critical evaluation of data. It is not uncommon for a compound to be reported to be spoken of; to be mentioned, whether favorably or unfavorably. See also: Report in a space group of too low symmetry. A remarkable case of what can happen is illustrated in Table 6, in which, five independent determinations of 1,8-terpin are given (20-24) in chronological chron·o·log·i·cal also chron·o·log·ic adj. 1. Arranged in order of time of occurrence. 2. Relating to or in accordance with chronology. order (left to right). The first two papers report lattice parameters only, whereas the latter three describe full structure refinements. Reduction techniques prove that all five papers report the same compound (i.e., the reduced cells/compositions are identical). Note that for Lattice IV, the compound is described in a C-centered monoclinic space group. However, inspection of Table 2, reveals that the reduced form (reduced form number = 16) corresponds to an F-centered orthorhombic lattice. In the final study (Lattice V), Marsh and Herbstein correct determination 4 and refine the compound in the F-centered orthorhombic lattice. It is instructive in·struc·tive adj. Conveying knowledge or information; enlightening. in·struc  tive·ly adv. to note that the
authors of determinations 4 and 5 make no reference to determination 3,
which was originally correct!4.3 Data Evaluation on Sets of Compounds Experience in data evaluation has shown that experimentalists sometime miss the symmetry for centered Bravais lattices. In such cases, the compound is often reported in a crystal system of too low symmetry. For example, sometimes a crystalline compound that is rhombohedral is incorrectly reported in a C-centered monoclinic space group. Likewise an F-centered orthorhombic compound (e.g. determination 4 in Table 6) is sometimes incorrectly reported in a C-centered monoclinic space group. Using a crystallographic database one can systematically evaluate any given reduced from type. To evaluate this problem, all of the reduced forms in NIST Crystal Data (17) that correspond to orthorhombic centered lattices--i.e., reduced forms 8, 13, 16, 19, 23, 26, 36, 38, 40, 42--have been analyzed. The results of the analysis are summarized in Table 7. The total number of compounds crystallizing in a given reduced form is given in the column labeled ALL. Those reported in the orthorhombic and monoclinic systems are presented in the columns labeled orthorhombic and monoclinic, respectively. As noted above the crystal and metric symmetry are highly correlated. Consequently, in Table 7, the compounds reported in the monoclinic system represent cases with potential error. Indeed a further analysis of selected cases from this category has revealed that many of these monoclinic compounds should have been reported in the orthorhombic system. For example, the selected compounds that were reported in monoclinic space groups but with metric orthorhombic F-centered lattices (reduced form 16, and 26) were shown using MISSYM (25,26) to have the higher crystal symmetry. 5. Derivative Lattices, Specialized Reduced Forms, and Lattice Metric Singularities 5.1 Derivative Lattices Derivative lattice theory can be applied to the systematic study of lattices and to identification procedures. To understand and evaluate lattice symmetry, it is necessary to calculate and 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. the symmetry of the sets of associated derivative lattices. Definitions and treatment of derivative lattices are given in (27). A convenient method for calculating the derivative sub- and superlattices of an original lattice of any desired multiplicity mul·ti·plic·i·ty n. pl. mul·ti·plic·i·ties 1. The state of being various or manifold: the multiplicity of architectural styles on that street. 2. is outlined in reference (28) in an Appendix appendix, small, worm-shaped blind tube, about 3 in. (7.6 cm) long and 1-4 in. to 1 in. (.64–2.54 cm) thick, projecting from the cecum (part of the large intestine) on the right side of the lower abdominal cavity. . (Multiplicity is defined as equal to the value of the determinant determinant, a polynomial expression that is inherent in the entries of a square matrix. The size n of the square matrix, as determined from the number of entries in any row or column, is called the order of the determinant. of the transformation matrix. Thus the value of the determinant times the volume of the original lattice is equal to the volume of the derivative lattice.) This method generates unique sets of upper triangular matrices for any given value of the determinant of the matrix. The required calculation can conveniently be done by the computer program NIST*LATTICE (10). Table 8 gives the upper triangular matrices required to calculate the unique superlattices of mu ltiplicities two, three, and four associated with an original lattice. 5.2 Specialized Reduced Forms Sometimes a reduced form will exhibit 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 beyond that required for one of the 44 reduced forms in Table 2. Specialization can occur in two ways--a legitimate function of the crystal lattice crystal lattice Three-dimensional configuration of points connected by lines used to describe the orderly arrangement of atoms in a crystal. Each point represents one or more atoms in the actual crystal. or from an experimental error. For example, it can occur when one is dealing with an original lattice which is also a derivative lattice of a lattice with higher metric symmetry (see Tables 9 and 10). To recognize and characterize such specialization is desirable because many properties of crystals are not only related to the symmetry of the original lattice, but also to the symmetry of the associated derivative lattices. 5.2.1 Specialized Reduced Forms Derived de·rive v. de·rived, de·riv·ing, de·rives v.tr. 1. To obtain or receive from a source. 2. From an Original Cubic F Lattice Specialized reduced forms can be generated by calculating derivative sublattices of an original cubic F lattice. The matrices (X) for calculating the sublattices are derived as noted from the Q matrices in Table 8. Table 9 shows sets of sublattices of an original cubic F lattice. Relations of the first seven sublattices in the Table to the original lattice are specified by a set of seven unique transformation matrices (X, \x\ = 1/2), the next 13 are specified by 13 unique transformation matrices (X, \X\ = 1/3), etc. The sublattices have different orientations with respect to the original lattices. In the general triclinic system, they also have seven different reduced forms. But as Table 9 illustrates, for the cubic F original cell, six of the sublattices (\X\ = 1/2) have identical reduced forms (i.e., reduced form 23 = C-centered Bravais Lattice). This reduced form exhibits specialization as the relation (b*b = 3 a*a) is not required. In fact, as the table shows, all the sublattices with symmetry less than c ubic have extra specialization in the reduced form. 5.2.2 Specialized Reduced Forms Derived From an Original Cubic P Lattice A second example of specialization can be generated by calculating derivative superlattices of an original cubic P lattice. The matrices (Q) for calculating the superlattices are given in Table 8. Table 10 shows sets of superlattices of an original cubic P lattice. Relations of the first seven superlattices in the Table to the original lattice are specified by a set of seven unique transformation matrices (Q, \Q\ = 2), the next 13 are specified by 13 unique transformation matrices (Q, \Q\ = 3), etc. As the table shows, all the superlattices with symmetry less than cubic have extra specialization in the reduced form. In Tables 9 and 10, the reduced forms are represented in a normalized form--i.e., all the dot products are divided by smallest--so that extra specialization can readily be recognized. 5.3 Experimental Error Resulting From Omitted Nodes Specialization sometimes occurs--especially if the original cell is of high symmetry--simply because the experimenter has determined a derivative rather than the original cell defining the lattice. Suppose a supercell A supercell is a severe thunderstorm with a deep, persistently rotating updraft (a mesocyclone).[1] Supercell thunderstorms are the largest, most severe class of thunderstorms. of two times the volume of a primitive reciprocal Bilateral; two-sided; mutual; interchanged. Reciprocal obligations are duties owed by one individual to another and vice versa. A reciprocal contract is one in which the parties enter into mutual agreements. cell has been selected. Depending on which nodes in the reciprocal lattice In crystallography, the reciprocal lattice of a Bravais lattice is the set of all vectors K such that for all lattice point position vectors R. are omitted, one can obtain seven different superlattices of twice the volume of the original cell (note that some of the seven may be metrically met·ri·cal adj. 1. Of, relating to, or composed in poetic meter: metrical verse; five metrical units in a line. 2. Of or relating to measurement. identical--see Table 10--but have different orientations relative to the original lattice). Nevertheless, if a cell from a given 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. is used as a basis cell, it is possible to calculate the set of seven sublattices of this superlattice. One of these is the true lattice. 5.4 Lattice Metric Singularities (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 ) in 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. Indexing A lattice 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. (LMS) occurs when unit cells defining two or more lattices yield the identical set of unique calculated d-spacings (29). In Table 11, 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. LMS is illustrated. In this highly unusual singularity, all four lattices are different Bravais lattices, each of which is characterized by a different reduced form. Furthermore, Lattices II-IV are all derivative sublattices of a cubic I-centered Bravais lattice and are all characterized by specialized reduced forms. Recently 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. LMS was analyzed in which two of the lattices were hexagonal and one was orthorhombic. In this case, the two hexagonal lattices 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. had the same volume and all three reduced forms were specialized. The existence of such singularities provides a warning to researchers who index powder patterns and rely on "Figures of Merit" as a sign of correctness. 6. Conclusion Symmetry determination and identification procedures based on reduction have proved invaluable in crystallography and in the materials sciences materials science Study of the properties of solid materials and how those properties are determined by the material's composition and structure, both macroscopic and microscopic. . The symmetry determination strategies outlined herein are based on the fact that the reduced cell represents a unique standard cell that can be calculated from any cell of the lattice. This cell can be rigorously defined 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. . Consequently, procedures based on reduction are highly reliable and are widely used in the scientific community--by individual scientists as well as by the crystallographic data centers. Because of their precise mathematical nature, they have been adapted to automated diffractometry and are routinely used as an integral part of structure-determination methodology worldwide. Due somewhat to serendipity serendipity happy finding of an unexpected object or solution while searching for something else. , however, the most significant and lasting value of this work is probably not reduction itself. Rather, reduction has played a key transition role in helping to move the discipline of crystallography in new directions with new insights. The research on reduction proved that there are excellent reasons for looking at the crystal lattice from an entirely different point of view. Consequently, with time, many other lattice-related papers followed, including papers on sublattices and superlattices, composite composite, alternate common name for Asteraceae or Compositae, the aster family. composite - aggregate lattices, coincidence Coincidence is the noteworthy alignment of two or more events or circumstances without obvious causal connection. The word is derived from the Latin co- ("in", "with", "together") and incidere ("to fall on"). site lattices, and lattice-metric singularities in the indexing of powder patterns. At NIST, the mathematical analysis Analysis has its beginnings in the rigorous formulation of calculus. It is the branch of mathematics most explicitly concerned with the notion of a limit, whether the limit of a sequence or the limit of a function. of lattices was pursued further and evolved to a matrix approach that offered a more abstract and powerful way to look at lattices and their properties. The matrix approach, in particular, has many applications including, for example, symmetry determination (3,30). [FIGURE 1 OMITTED]
Table 1
Conditions for a reduced cell (a)
The cell is specified by three noncoplanar vectors: a, b, c. The cell
matrix (a*a b*b c*c/b*c a*c a*b) is defined by the dot products between
these vectors.
A. Positive Reduced form, Type I cell, all angles < 90[degrees]
Main conditions:
a*a [less than or equal to] b*b [less than or equal to] c*c;
b*c [less than or equal to] 1/2 b*b;
a*c [less than or equal to] 1/2 a*a;
a*b [less than or equal to] 1/2 a*a
Special conditions:
(a) if a*a = b*b then b*c [less than or equal to] a*c
(b) if b*b = c*c then a*c [less than or equal to] a*b
(c) if b*c = 1/2 b*b then a*b [less than or equal to] 2 a*c
(d) if a*c = 1/2 a*a then a*b [less than or equal to] 2 b*c
(e) if a*b = 1/2 a*a then a*c [less than or equal to] 2 b*c
B. Negative reduced form, Type II cell, all angles [greater than or
equal to] 90[degrees]
Main conditions:
(a) a*a [less than or equal to] b*b [less than or equal to] c*c;
\b*c\ [less than or equal to] 1/2 b*b;
\a*c\ [less than or equal to] 1/2 a*a;
\a*b\ [less than or equal to] 1/2 a*a
(b) (\b*c\ + \a*c\ + \a*b\) [less than or equal to] 1/2 (a*a + b*b)
Special conditions:
(a) if a*a = b*b then \b*c\ [less than or equal to] \a*c (b) if b*b = c*c then \a*c\ [less than or equal to] \a*b (c) if \b*c\ = 1/2 b*b then a*b = 0
(d) if \a*c\ = 1/2 a*a then a*b = 0
(e) if \a*b\ = 1/2 a*a then a*c = 0
(f) if(\b*c\ + \a*c\ + \a*b\) = 1/2 (a*a + b*b) then a*a [less than
or equal to] 2 \a*c\ + \a*b
(a.) To be reduced the cell must be in normal representation (type I or
II) and all the main and special conditions for the given cell type must
be satisfied. The main conditions are used to establish that a cell is
based on the three shortest lattice translations. The special conditions
are used to select a unique cell when two or more cells in the lattice
have the same numerical values for the cell edges.
Table 2
Metric classification of the 44 reduced forms (a). From the nature of
the reduced form, one can determine the reduced form number, Bravais
lattice, and the transformation matrix to the conventional cell
Reduced form matrix
Reduced
form First row Second row
No. a*a b*b c*c b*c a*c
a = b = c
1 a*a a*a a*a a*a/2 a*a/2
2 a*a a*a a*a b*c b*c
3 a*a a*a a*a 0 0
4 a*a a*a a*a -\b*c\ -\b*c 5 a*a a*a a*a -a*a/3 -a*a/3
6 a*a a*a a*a -a*a + \a*b\/2 -a*a + \a*b\/2
7 a*a a*a a*a -\b*c\ -a*a + \b*c\/2
8 a*a a*a a*a -\b*c\ -\a*c
a = b
9 a*a a*a c*c a*a/2 a*a/2
10 a*a a*a c*c b*c b*c
11 a*a a*a c*c 0 0
12 a*a a*a c*c 0 0
13 a*a a*a c*c 0 0
14 a*a a*a c*c -\b*c\ -\b*c15 a*a a*a c*c -a*a/2 -a*a/2
16 a*a a*a c*c -\b*c\ -\b*c17 a*a a*a c*c -\b*c\ -\a*c
b = c
18 a*a b*b b*b a*a/4 a*a/2
19 a*a b*b b*b b*c a*a/2
20 a*a b*b b*b b*c a*c
21 a*a b*b b*b 0 0
22 a*a b*b b*b -b*b/2 0
23 a*a b*b b*b -\b*c\ 0
24 a*a b*b b*b -b*b - a*a/3/2 -a*a/3
25 a*a b*b b*b -\b*c\ -\a*c
a [less than or
equal to] b [less
than or equal to] c
26 (g) a*a b*b c*c a*a/4 a*a/2
27 a*a b*b c*c b*c a*a/2
28 a*a b*b c*c a*b/2 a*a/2
29 a*a b*b c*c a*c/2 a*c
30 a*a b*b c*c b*b/2 a*b/2
31 a*a b*b c*c b*c a*c
32 a*a b*b c*c 0 0
33 a*a b*b c*c 0 -\a*c34 a*a b*b c*c 0 0
35 a*a b*b c*c -\b*c\ 0
36 a*a b*b c*c 0 -a*a/2
37 a*a b*b c*c -\b*c\ -a*a/2
38 a*a b*b c*c 0 0
39 a*a b*b c*c -\b*c\ 0
40 a*a b*b c*c -b*b/2 0
41 a*a b*b c*c -b*b/2 -\a*c42 a*a b*b c*c -b*b/2 -a*a/2
43 a*a b*b c*c -b*b - \a*b\/2 -a*a - \a*b\/2
44 a*a b*b c*c -\b*c\ -\a*c
Reduced form matrix
Reduced Reduced
form Second row form Bravais
No. a*b type lattice
a = b = c
1 a*a/2 + Cubic
2 b*c + Rhombohedral
3 0 - Cubic
4 -\b*c\ - Rhombohedral
5 -a*a/3 - Cubic
6 -\a*b\ - Tetragonal
7 -a*a + \b*c\/2 - Tetragonal
8 -(\a*a\-\b*c\-\a*c\) - Orthorhombic
a = b
9 a*a/2 + Rhombohedral
10 a*b + Monoclinic
11 0 - Tetragonal
12 -a*a/2 - Hexagonal
13 -\a*b\ - Orthorhombic
14 -\a*b\ - Monoclinic
15 0 - Tetragonal
16 -(a*a-2\b*c\) - Orthorhombic
17 -(a*a-\b*c\-\a*c\) - Monoclinic
b = c
18 a*a/2 + Tetragonal
19 a*a/2 + Orthorhombic
20 a*c + Monoclinic
21 0 - Tetragonal
22 0 - Hexagonal
23 0 - Orthorhombic
24 -a*a/3 - Rhombohedral
25 -\a*c\ - Monoclinic
a [less than or
equal to] b [less
than or equal to] c
26 (g) a*a/2 + Orthorhombic
27 a*a/2 + Monoclinic
28 a*b + Monoclinic
29 a*a/2 + Monoclinic
30 a*b + Monoclinic
31 a*b + Triclinic
32 0 - Orthorhombic
33 0 - Monoclinic
34 -\a*b\ - Monoclinic
35 0 - Monoclinic
36 0 - Orthorhombic
37 0 - Monoclinic
38 -a*a/2 - Orthorhombic
39 -a*a/2 - Monoclinic
40 0 - Orthorhombic
41 0 - Monoclinic
42 0 - Orthorhombic
43 -\a*b\ - Monoclinic
44 -\a*b\ - Triclinic
Cell
Reduced transformation
form Bravais reduced [right arrow]
No. lattice conventional
a = b = c
1 F 111/111/111
2 hR 110/101/111
3 P 100/010/001
4 hR 110/101/111
5 I 101/110/011
6 I 011/101/110
7 I 101/110/011
8 I 110/101/011
a = b
9 hR 100/110/113
10 C (d) 110/110/001
11 P 100/010/001
12 P 100/010/001
13 C 110/110/001
14 C (d) 110/110/001
15 I 100/010/112
16 F 110/110/112
17 I (e) 101/110/011
b = c
18 I 011/111/100
19 I 100/011/111
20 C (b) 011/011/100
21 P 010/001/100
22 P 010/001/100
23 C 011/011/100
24 hR 121/011/100
25 C (b) 011/011/100
a [less than or
equal to] b [less
than or equal to] c
26 (g) F 100/120/102
27 I (f) 011/100/111
28 C 100/102/010
29 C 100/120/001
30 C 010/012/100
31 P 100/010/001
32 P 100/010/001
33 P 100/010/001
34 P 100/001/010
35 P 010/100/001
36 C 100/102/010
37 C (c) 102/100/010
38 C 100/120/001
39 C (d) 120/100/001
40 C 010/012/100
41 C (b) 012/010/100
42 I 100/010/112
43 I 100/112/010
44 P 100/010/001
(a)Based on Table 5.1.3.1 of the International Tables for X-Ray
Crystallography (9) and published revisions (11,12,13).
(b)If a*a < 4\a*c
(c)If b*b < 4\b*c
(d)If c*c < 4\b*c\ } Premultiply table matrix by 001/010/101 (I
centered).
(e)If 3a*a < c*c + 2\a*c
(f)If 3b*b < c*c + 2\b*c\ } Premultiply table matrix by 101/010/100 (C
centered).
(g)No required relationships between symmetrical scalars for reduced
forms 26-44.
Table 3
Reduced form frequency for 133 613 organic compounds
Reduced Bravais lattice Count % Total
form No. (a)
1 Cubic F 165 0.12
2 Rhombohedral R 324 0.24
3 Cubic P P 544 0.41
4 Rhombohedral R 441 0.33
5 Cubic I 137 0.10
6 Tetragonal I 123 0.09
7 Tetragonal I 231 0.17
8 Orthorhombic I 28 0.02
9 Rhombohedral R 281 0.21
10 Monoclinic C/I 2151 1.61
11 Tetragonal P 1499 1.12
12 Hexagonal P 921 0.69
13 Orthorhombic C 737 0.55
14 Monoclinic C/I 1277 0.96
15 Tetragonal I 304 0.23
16 Orthorhombic F 265 0.20
17 Monoclinic I/C 765 0.57
18 Tetragonal I 504 0.38
19 Orthorhombic I 188 0.14
20 Monoclinic C/I 667 0.50
21 Tetragonal P 1154 0.86
22 Hexagonal P 801 0.60
23 Orthorhombic C 327 0.24
24 Rhombohedral R 351 0.26
25 Monoclinic C/I 398 0.30
26 Orthorhombic F 386 0.29
27 Monoclinic I/C 2350 1.76
28 Monoclinic C 110 0.08
29 Monoclinic C 436 0.33
30 Monoclinic C 141 0.11
31 Triclinic P 13959 10.45
32 Orthorhombic P 27154 20.32
33 Monoclinic P 15937 11.93
34 Monoclinic P 20554 15.38
35 Monoclinic P 20048 15.00
36 Orthorhombic C 237 0.18
37 Monoclinic C/I 1201 0.90
38 Orthorhombic C 442 0.33
39 Monoclinic C/I 2718 2.03
40 Orthorhombic C 232 0.17
41 Monoclinic C/I 393 0.29
42 Orthorhombic I 136 0.10
43 Monoclinic I 138 0.10
44 Triclinic P 12458 9.32
(a)Reduced form number (see Table 2).
Table 4
Population frequency for the 14 Bravais lattices for 133 613 organic
compounds
Bravais lattice Count % Total
1 Triclinic P 26417 19.77
2 Monoclinic P 56539 42.32
3 Monoclinic C/I 12745 9.54
4 Orthorhombic P 27154 20.32
5 Orthorhombic C 1975 1.48
6 Orthorhombic I 352 0.26
7 Orthorhombic F 651 0.49
8 Rhombohedral P 1397 1.05
9 Tetragonal P 2653 1.99
10 Tetragonal I 1162 0.87
11 Hexagonal P 1722 1.29
12 Cubic P 544 0.41
13 Cubic I 137 0.10
14 Cubic F 165 0.12
Table 5
Population frequency by crystal system for 133 613 organic compounds
Bravais lattice Count % Total
1 Triclinic 26417 19.77
2 Monoclinic 69284 51.85
3 Orthorhombic 30132 22.55
4 Rhombohedral 1397 1.05
5 Tetragonal 3815 2.86
6 Hexagonal 1722 1.29
7 Cubic 846 0.63
Table 6
Crystallographic parameters reported for 1,8-terpin
([C.sub.10][H.sub.20][O.sub.2]*[H.sub.2]O) in Refs. [20-24]. Lattice IV
was incorrectly reported as monoclinic. However, the reduced form (No.
16) for Cell 4 shows that the lattice is metrically F-centered
orthorhombic. Numbers in parentheses represent standard deviations
No. 1[20] 2[21] 3[22]
Lattice I Lattice II Lattice III
Orthorhombic F Orthorhombic F Orthorhombic F
Literature cells
Cell Cell 1 Cell 2 Cell 3
a([Angstrom]) 18.51 18.60 10.930(2)
b([Angstrom]) 22.87 23.00 18.425(5)
c([Angstrom]) 10.96 10.86 22.791(6)
[alpha]([degrees]) 90.0 90.0 90.0
[beta]([degrees]) 90.0 90.0 90.0
[gamma]([degrees]) 90.0 90.0 90.0
V([[Angstrom].sup.3]) 4639.6 4645.9 4589.8
Sp. Gr. F* Fdd2 Fdd2
Yr. Pub. 1951 1965 1982
Reduced cells
Cell R1 R2 R3
a([Angstrom]) 10.76 10.769 10.712
b([Angstrom]) 10.76 10.769 10.712
c([Angstrom]) 12.68 12.718 12.638
[alpha]([degrees]) 102.72 102.43 102.74
[beta]([degrees]) 102.72 102.43 102.74
[gamma]([degrees]) 118.74 119.44 118.65
V([[Angstrom].sup.3]) 1159.9 1161.5 1147.4
Reduced forms
Form F1 F2 F3
a*a 115.68 115.98 114.74
b*b 115.68 115.98 114.74
c*c 160.79 161.74 159.72
b*c -30.03 -29.48 -29.87
a*c -30.03 -29.48 -29.87
a*b -55.62 -57.00 -55.00
Form No. 16 16 16
No. 4[23] 5[24]
Lattice IV Lattice V
Monoclinic C Orthorhombic F
Literature cells
Cell Cell 4 Cell 5
a([Angstrom]) 10.912(3) 18.421
b([Angstrom]) 22.791(4) 22.791
c([Angstrom]) 10.705(2) 10.912
[alpha]([degrees]) 90.0 90.0
[beta]([degrees]) 120.64 90.0
[gamma]([degrees]) 90.0 90.0
V([[Angstrom].sup.3]) 2290.6 4581.2
Sp. Gr. Cc Fdd2
Yr. Pub. 1986 1988
Reduced cells
Cell R4 R5
a([Angstrom]) 10.705 10.705
b([Angstrom]) 10.705 10.705
c([Angstrom]) 12.634 12.634
[alpha]([degrees]) 102.71 102.71
[beta]([degrees]) 102.71 102.71
[gamma]([degrees]) 118.72 118.72
V([[Angstrom].sup.3]) 1145.3 1145.3
Reduced forms
Form F4 F5
a*a 114.60 114.60
b*b 114.60 114.60
c*c 159.62 159.62
b*c -29.77 -29.77
a*c -29.77 -29.77
a*b -55.06 -55.06
Form No. 16 16
Table 7
Analysis of the centered orthorhombic Bravais lattices in NIST Crystal
Data. The total number of organic compounds in all 44 reduced forms is
133 613 out of which 2978 have centered orthorhombic lattices
No. Bravais Reduced ALL (a) Monoclinic (b) Orthorhombic (c)
lattice form No.
1 OI (d) 8 28 3 25
2 OC 13 737 159 578
3 OF 16 265 22 243
4 OI 19 188 19 169
5 OC 23 327 158 169
6 OF 26 386 22 364
7 OC 36 237 109 128
8 OC 38 442 154 288
9 OC 40 232 139 93
10 OI 42 136 11 125
Sum = 2978 796 2182
No. % Lower
symmetry
1 10.7
2 21.6
3 8.3
4 10.1
5 48.3
6 5.7
7 46.0
8 34.8
9 59.9
10 8.1
(a)Total number of compounds with specified reduced form.
(b)Number of compounds reported as monoclinic. For these compounds, the
crystal symmetry is less than the metric symmetry.
(c)Number of compounds reported as orthorhombic. For these compounds,
the crystal symmetry is equal to the metric symmetry.
(d)Orthorthombic I- centered (i.e., 1st letter = system; 2nd letter =
centering).
Table 8
Unique Q matrices (28, 10) generating 7, 13, and 35 superlattices for
\Q\ = 2, 3, and 4, respectively. The unique matrices generating 7, 13,
35 sublattices for \X\ = [1/2], [1/3] [1/4] are obtained by taking the
transpose of the inverse of the matrices given for the superlattices.
For each value of \Q\ or \X\, the matrices can be applied to any
primitive cell of the original lattice, but they must be applied to the
same cell
100 / 010 / 002 100 / 011 / 002 101 / 010 / 002
\Q\ = 2 101 / 011 / 002 100 / 020 / 001 110 / 020 / 001
200 / 010 / 001
100 / 010 / 003 100 / 011 / 003 100 / 012 / 003
101 / 010 / 003 101 / 011 / 003 101 / 012 / 003
\Q\ = 3 102 / 010 / 003 102 / 011 / 003 102 / 012 / 003
100 / 030 / 001 110 / 030 / 001 120 / 030 / 001
300 / 010 / 001
100 / 010 / 004 100 / 011 / 004 100 / 012 / 004
100 / 013 / 004 101 / 010 / 004 101 / 011 / 004
101 / 012 / 004 101 / 013 / 004 102 / 010 / 004
102 / 011 / 004 102 / 012 / 004 102 / 013 / 004
103 / 010 / 004 103 / 011 / 004 103 / 012 / 004
\Q\ = 4 103 / 013 / 004 100 / 020 / 002 100 / 021 / 002
101 / 020 / 002 101 / 021 / 002 110 / 020 / 002
110 / 021 / 002 111 / 020 / 002 111 / 021 / 002
100 / 040 / 001 110 / 040 / 001 120 / 040 / 001
130 / 040 / 001 200 / 010 / 002 200 / 011 / 002
201 / 010 / 002 201 / 011 / 002 200 / 020 / 001
210 / 020 / 001 400 / 010 / 001
Table 9
Specialized derivative sublattices (derived from a Cubic F lattice). All
sublattices with symmetry less than cubic have extra specialization in
their reduced form
Reduced Reduced form (a)
form First row Second row
No. a-a b-b c-c b-c a-c
Original lattice
1 2 2 2 1 1
7 Sublattices \X = 1/2
3 1 1 1 0 0
23 1 3 3 -1 0
13 Sublattices \X = 1/3
12 2 2 4 0 0
18 4 10 10 1 2
19 2 14 14 5 1
35 Sublattices \X = 1/4
5 3 3 3 -1 -1
9 2 2 6 1 1
11 1 1 2 0 0
21 1 4 4 0 0
23 1 12 12 -4 0
26 4 5 9 1 2
33 3 4 11 0 -1
Reduced Reduced
form (a)
form Second row No.
No. a-b Bravais lattice lattices
Original lattice
1 1 Cubic F 1
7 Sublattices \X = 1/2
3 0 Cubic P 1
23 0 Orthorhombic C 6
13 Sublattices \X = 1/3
12 -1 Hexagonal P 4
18 2 Tetragonal I 3
19 1 Orthorhombic I 6
35 Sublattices \X = 1/4
5 -1 Cubic I 1
9 1 Rhombohedral P 4
11 0 Tetragonal P 3
21 0 Tetragonal P 3
23 0 Orthorhombic C 6
26 2 Orthorhombic F 6
33 0 Monoclinic P 12
Reduced
form
No. V/[V.sub.org]
Original lattice
1 1
7 Sublattices \X = 1/2
3 1/2
23 1/2
13 Sublattices \X = 1/3
12 1/3
18 1/3
19 1/3
35 Sublattices \X = 1/4
5 1/4
9 1/4
11 1/4
21 1/4
23 1/4
26 1/4
33 1/4
(a)The reduced forms have been normalized.
Table 10
Specialized derivative superlattices (derived from a Cubic P original
lattice). All superlattices with symmetry less than cubic have extra
specialization in their reduced form
Reduced Reducedform (a)
form First row Second row
No. a-a b-b c-c b-c
Original lattice
1 1 1 1 0
7 Superlattices \Q\ = 2
1 2 2 2 1
11 1 1 4 0
21 1 2 2 0
13 Superlattices
11 1 1 9 0
12 2 2 3 0
40 1 2 5 -1
35 Superlattices \Q\ = 4
5 3 3 3 -1
9 2 2 6 1
11 1 1 2 0
11 1 1 16 0
15 2 2 5 -1
21 1 4 4 0
23 2 3 3 -1
32 1 2 8 0
40 1 4 5 -2
Reduced Reducedform (a)
form Second row
No. a-c a-b Bravais lattice
Original lattice
1 0 0 Cubic P
7 Superlattices \Q\ = 2
1 1 1 Cubic F
11 0 0 Tetragonal P
21 0 0 Tetragonal P
13 Superlattices
11 0 0 Tetragonal P
12 0 -1 Haxagonal P
40 0 0 Orthorhombic C
35 Superlattices \Q\ = 4
5 -1 -1 Cubic I
9 1 1 Rhombohedral P
11 0 0 Tetragonal P
11 0 0 Tetragonal P
15 -1 0 Tetragonal I
21 0 0 Tetragonal P
23 0 0 Orthorhombic C
32 0 0 Orthorhombic P
40 0 0 Orthorhombic C
Reduced
form No.
No. lattices V/[V.sub.org]
Original lattice
1 1 1
7 Superlattices \Q\ = 2
1 1 2
11 3 2
21 3 2
13 Superlattices
11 3 3
12 4 3
40 6 3
35 Superlattices \Q\ = 4
5 1 4
9 4 4
11 3 4
11 3 4
15 3 4
21 3 4
23 6 4
32 6 4
40 6 4
(a)The reduced forms have been normalized.
Table 11
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 reduce cell and
normalized reduced form. The normalized reduced forms reveal extra
specialization in forms F2-F4
Lattice I Lattice II Lattice III
Cubic I Tetragonal P Orthorhombic F
Conventional cells
Cell Cell 1 Cell 2 (a) Cell 3 (b)
a([Angstrom]) 10.0000 7.0711 4.7140
b([Angstrom]) 10.0000 7.0711 10.0000
c([Angstrom]) 10.0000 5.0000 14.1421
[alpha]([degrees]) 90.0 90.0 90.0
[beta]([degrees]) 90.0 90.0 90.0
[gamma]([degrees]) 90.0 90.0 90.0
V([Angstrom]3) 1000.0 250.0 666.67
Reduced cells
Cell R1 R2 (d) R3 (e)
a([Angstrom]) 8.6603 5.0000 4.7140
b([Angstrom]) 8.6603 7.0711 5.5277
c([Angstrom]) 8.6603 7.0711 7.4536
[alpha]([degrees]) 109.471 90.0 82.251
[beta]([degrees]) 109.471 90.0 71.565
[gamma]([degrees]) 109.471 90.0 64.761
V(Angstrom]3) 500.0 250.0 166.67
Normalized reduced forms
Form F1 F2 F3
a*a 3 1 4
b*b 3 2 5.5
c*c 3 2 10
b*c -1 0 1
a*c -l 0 2
a*b -l 0 2
Form No. 5 21 26
Lattice IV
Orthorhombic P
Conventional cells
Cell Cell 4 (c)
a([Angstrom]) 3.5355
b([Angstrom]) 5.0000
c([Angstrom]) 7.0711
[alpha]([degrees]) 90.0
[beta]([degrees]) 90.0
[gamma]([degrees]) 90.0
V([Angstrom]3) 125.0
Reduced cells
Cell R4 (f)
a([Angstrom]) 3.5355
b([Angstrom]) 5.0000
c([Angstrom]) 7.0711
[alpha]([degrees]) 90.0
[beta]([degrees]) 90.0
[gamma]([degrees]) 90.0
V(Angstrom]3) 125.0
Normalized reduced forms
Form F4
a*a 1
b*b 2
c*c 4
b*c 0
a*c 0
a*b 0
Form No. 32
Transformations
(a)Cell 2 [right arrow] Cell 1 [002/1-10/110][DELTA]=4.
(b)Cell 3 [right arrow] Cell 1 [1/2-2/3-1/2/2 1/3 0/1/2 -2/3 1/2]
[DELTA]=3/2.
(c)Cell 4 [right arrow] Cell 1 [020/201/20-1] [DELTA]=8.
(d)R2 [right arrow] R1 [1-10/-101/-10-1] [DELTA]=2.
(e)R3 [right arrow] R1 [110/-210/0-11] [DELTA]=3.
(f)R4 [right arrow] R1 [0-1-1/210/0-11] [DELTA]=4.
Acknowledgments See About this product. The author gratefully acknowledges a long-term Long-term Three or more years. In the context of accounting, more than 1 year. long-term 1. Of or relating to a gain or loss in the value of a security that has been held over a specific length of time. Compare short-term. collaboration Working together on a project. See collaborative software. in research on lattices--as indicated in the references--with Vicky Vicky has multiple meanings:
lends money gratis. [Br. Lit.: Merchant of Venice] See : Generosity Antonio schemes against his brother Prospero. [Br. Lit.: The Tempest] See : Treachery Santoro. I thank them for many interesting experiences, conversations, and enjoyable times with respect to our productive endeavors. In addition, the NIST Center for Neutron Research, the Ceramics ceramics (sərăm`ĭks), materials made of nonmetallic minerals that have been permanently hardened by firing at a high temperature, or objects made of such materials. Division, and the Standard Reference Data Program are all thanked for their support of this research. Finally, the author thanks Ronald Munro Mun·ro , Alice Born 1931. Canadian writer noted for vivid novels and short stories of life in rural Ontario. Her collections of stories include Dance of the Happy Shades (1968) and Moons of Jupiter (1982). Noun 1. and Shozo Takagi Takagi is a common surname in Japan, meaning "tall tree" in Japanese, and may refer to:
Accepted: August 22, 2001 Available online: http://www.nist.gov/jres (#.) The metric symmetry is the symmetry of the lattice only treated as a mathematical entity. Consequently, it is equal to or greater than the crystal symmetry but never less. 7. References (1.) P. Niggli, Handbuch der Experimentalphysik, Vol 7, Part 1. Leipzig Leipzig (līp`tsĭkh), city (1994 pop. 490,850), Saxony, E central Germany, at the confluence of the Pleisse, White Elster, and Parthe rivers. : Akademischc Verlagsgesellschaft (1928). (2.) A. Santoro and A. D. Mighell, Determination of Reduced Cells, Acta Cryst, A26, 124-127 (1970). (3.) V. L. Karen (Himes) and A. D. Mighell, A Matrix Approach to Symmetry, Acta Cryst. A43, 375-384 (1987). (4.) V. L. Karen and A. D. Mighell, Converse (logic) converse - The truth of a proposition of the form A => B and its converse B => A are shown in the following truth table: A B | A => B B => A ------+---------------- f f | t t f t | t f t f | f t t t | t t Transformation Analysis, J. Appl. Cryst. 24, 1076-1078 (1991). (5.) A. D. Mighell, The Reduced Cell: Its Use in the Identification of Crystalline Materials, J. Appl. Cryst. 9, 491-498 (1976). (6.) V. L. Karen and A. D. Mighell, NBS*Lattice: A Program to Analyze Lattice Relationships, Natl. Bur. Stand. (U.S.) Tech. Note 1214 (1985). (7.) A. D. Mighell and V. L. Karen, Compound Identification and Characterization Using Lattice-Formula Matching Techniques, Acta Cryst. A42, 101-105 (1986). (8.) S. K. Bryam, C. F. Campana, J. Fait, and R. A. Sparks Sparks, city (1990 pop. 53,367), Washoe co., W Nev., just E of Reno; inc. 1905. The Southern Pacific RR was the major employer until the dieselization of railroad engines forced the closing (1957) of the railroad shops there. , Using NIST Crystal Data within Siemens' Software for Four-circle and Smart CCD CCD in full charge-coupled device Semiconductor device in which the individual semiconductor components are connected so that the electrical charge at the output of one device provides the input to the next device. Diffractometers, J. Res. Natl. Inst. Stand. Technol. 101, 295 (1996). (9.) A. D. Mighell, A. Santoro, and J. D. H. Donnay, Reduced-cells section, published in International Tables for X-Ray Crystallography, Vol. I, 3rd ed., Birmingham Birmingham, cities, United States Birmingham (bûr`mĭnghăm') 1 City (1990 pop. 265,968), seat of Jefferson co., N central Ala., in the Jones Valley near the southern end of the Appalachian system; founded and inc. , Kynoch Kynoch was a manufacturer of ammunition, later incorporated into ICI but remaining as a brand name for sporting cartridges. History After the First World War many of the UK ammunition and explosives manfacturers were brought together under Nobel Explosives Press (1969) pp. 530-535. (10.) V. L. Karen and A. D. Mighell, NIST*LATTICE--A Program to Analyze Lattice Relationships, Version of Spring 1991, NIST Technical Note 1290 (1991). (See also NBS Technical Note 1214 (see Ref. [6]). (11.) E. Parthe and J. Hornstra, Acta Cryst. A29, 309 (1973). (12.) A. D. Mighell, A. Santoro, and J. D. H. Donnay, Acta Cryst. B27, 1837-1838 (1971). (13.) A. D. Mighell, A. Santoro, and J. D. H. Donnay, Acta Cryst. B31, 2942 (1975). (14.) A. D. Mighell, C. R., Hubbard, and J. K. Stalick, NBS*AIDS8O: 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 (USA), Tech. Note 1141(1981). (NBS*A1DS83 is a development of NBS*AIDS80). (15.) The Cambridge Structural Database, Cambridge Crystallographic Data Centre The Cambridge Crystallographic Data Centre (CCDC) is a crystallographic organisation based in Cambridge, England. It is a non-profit organisation whose primary role is the compilation and maintenance of the Cambridge Structural Database, a database of small molecule crystal (CCDC CCDC Cambridge Crystallographic Data Centre CCDC Centre City Development Corporation (San Diego, California) CCDC Consultant in Communicable Disease Control CCDC Certified Chemical Dependency Counselor CCDC Colorado Cross-Disability Coalition ), Cambridge Cambridge, city, Canada Cambridge (kām`brĭj), city (1991 pop. 92,772), S Ont., Canada, on the Grand River, NW of Hamilton. It was formed in 1973 with the amalgamation of Galt, Hespeler, and Preston, all founded in the early 19th cent. CB2 1EZ, England England, the largest and most populous portion of the United Kingdom of Great Britain and Northern Ireland (1991 pop. 46,382,050), 50,334 sq mi (130,365 sq km). It is bounded by Wales and the Irish Sea on the west and Scotland on the north. . (16.) The Powder Diffraction File, 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. , 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, PA 19073. (17.) NIST Crystal Data (Version 1.03-1995), A Database with Chemical and Crystallographic Information. NIST Crystallographic Data Center, 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. (18.) A. D. Mighell and J. R. Rodgers, Lattice Symmetry Determination, Acta Cryst. A36, 321-326 (1980). (19.) A. D. Mighell, V. L. Karen(Himes), and J. R. Rodgers, Space-Group Frequencies for Organic Compounds, Acta Cryst. A39, 737-740 (1983). (20.) W. C. McCrone, Terpinol Ter´pin`ol n. 1. (Chem.) Any oil substance having a hyacinthine odor, obtained by the action of acids on terpin, and regarded as a related hydrate. Hydrate hydrate (hī`drāt), chemical compound that contains water. A common hydrate is the familiar blue vitriol, a crystalline form of cupric sulfate. Chemically, it is cupric sulfate pentahydrate, CuSO4·5H2O. (cis), Anal anal (a´n'l) relating to the anus. a·nal adj. 1. Of, relating to, or near the anus. 2. . Chem. 23, 1523 (1951). (21.) Von Von. For some German names beginning thus, see under the proper name; e.g., for Otto von Bismarck, see Bismarck, Otto von. (Voice On the Net, Video On the Net) A trade show sponsored by pulver. H. Strunz and B. Contag, Evenkit, Flagstaffit, Idrialin Idrialin is a mineral wax accompanying the mercury ore in Idria. According to Goldschmidt it can be extracted by means of xylol, amyl alcohol or turpentine; also without decomposition, by distillation in a current of hydrogen, or carbon dioxide. und Reficit, Neucs Jahib. Mineral. Monatsh 19, 19-25 (1965). (22.) T. Suga, T. Hirata, and T. Aoki Aoki (青木 blue tree) . An X-ray Crystallographic Study on cis-trans Configuarational Assignment to "cis- cis- a prefix denoting on this side, the same side, or the near side. cis- pref. Having a pair of identical atoms or groups on the same side of a plane that passes through two carbon atoms linked by a double bond: " and "trans-1, 8-terpins" and a Proposal of New Designation DESIGNATION, wills. The expression used by a testator, instead of the name of the person or the thing he is desirous to name; for example, a legacy to. the eldest son of such a person, would be a designation of the legatee. Vide 1 Rop. Leg. ch. 2. 2. for Discriminating dis·crim·i·nat·ing adj. 1. a. Able to recognize or draw fine distinctions; perceptive. b. Showing careful judgment or fine taste: Between the Configuarational Isomers isomers (ī´sōmurz), n.pl 1. organic compounds having the same empirical formula–i.e. , Bull. Chem. Soc. Jpn. 55, 914-917 (1982). (23.) T.-I. Ho, M.-C. Cheng, S.-M. Peng, F.-C. Chen, and C.-C. Tsau, Structure of Terpin terpin a product obtained by the action of nitric acid on oil of turpentine and alcohol, used as an expectorant in the form of the hydrate. , Acta Cryst. C42, 1787-1789 (1986). (24.) R. E. Marsh and F. H. Herbstein, More Space-Group Changes, Acta Cryst. B44, 77-88 (1988). (25.) Y. Le Page, MISSYM, J. Appl. Cryst. 20, 264-269 (1987). (26.) Y. Le Page, MISSYM, J. Appl. Cryst. 21, 983-984 (1988). (27.) A. Santoro and A. D. Mighell, Properties of Crystal Lattices: The Derivative Lattices and their Determination, Acta Cryst. A28, 284-287 (1972). (28.) A. Santoro and A. D. Mighell, Coincidence-Site Lattices, Acta Cryst. A29, 169-175 (1973). (29.) A. D. Mighell, Lattice Metric Singularities and Their Impact on the Indexing of Powder Patterns, Powder Diffraction 15(2), 82-85 (2000). (30.) V. L. Karen and A. D. Mighell, US Patents 5,168,457 and 5,235,523, Apparatus apparatus /ap·pa·ra·tus/ (ap?ah-ra´tus) pl. appara´tus, apparatuses a number of parts acting together to perform a special function. branchial apparatus pharyngeal a. and Methods for Identifying and Comparing Lattice Structures and Determining Lattice Structure Symmetries (1992,1993). About the author: Alan A`lan´ n. 1. A wolfhound. 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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