NIST materials properties databases for advanced ceramics.The 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. Ceramics Division maintains two databases on thc physical, mechanical, thermal, and other properties of high temperature superconductors and structural ceramics. Crystallographic crys·tal·log·ra·phy n. The science of crystal structure and phenomena. crys  tal·log data are
featured prominently among the physical property data and serve several
important functions in the classification and evaluation of the property
values. The scope of materials, properties, and data evaluation
protocols are discussed for the two databases.Key words: ceramics; database; evaluated data; materials properties This is a list of materials properties. A materials property is an intensive, often quantitative property of a material, usually with a unit that may be used as a metric of value to compare the benefits of one material versus another to aid in materials selection. ; mechanical properties; physical properties; structural ceramics; superconductivity superconductivity, abnormally high electrical conductivity of certain substances. The phenomenon was discovered in 1911 by Kamerlingh Onnes, who found that the resistance of mercury dropped suddenly to zero at a temperature of about 4.2°K;. ; thermal properties. 1. Introduction Crystallography plays a central role in classifying and understanding the physical behavior of solid materials. It is for that reason that crystallographic data form an integral part of the data sets developed for the NIST materials properties databases for advanced ceramics. The two general classes of materials considered in this work are structural ceramics and high temperature superconductors. These materials form two distinct types of advanced ceramics that have shared a common dilemma: significant economic benefits have been anticipated, but advances in applications of the materials have been slow to accrue. Uncertainties regarding the reliability of property values have contributed to the slowness of the progress, both with respect to developing new applications and to refining the characteristics of the materials. The NIST ceramics data program (1,2) is pursuing a three- tiered approach to assist in the resolution of this problem. At the root of the effort is the basic collection and organization of property data into more readily accessible and usable formats. Once collected, the data are evaluated with respect to how the materials were prepared and how the properties were measured. Inevitably there are apparent discrepencies among the reported results, and a significant p ortion of the NIST effort is devoted to understanding those differences in values. The latter effort involves models of property relations as well as statistical comparisons and analyses. The evaluation of the data is particularly important in addressing the issues of two obvious, but extremely different, situations in data management: a lack of data and an abundance of data. Consider, for example, the case of high temperature superconductors (HTS HTS Heights HTS Harmonized Tariff System HTS High Throughput Screening (biomolecular assay screening) HTS High-Throughput Screening (Pharmaceutical Industry) HTS Harmonized Tariff Schedule ). The interest in HTS materials (3) is motivated by their threefold potential for impact in science, technology, and the economy (4). Scientifically, theories of conventional superconductivity do not appear to be adequate to explain the HTS phenomena, so new insights into material behavior are essential. Technologically, the production of an intense magnetic field using a superconductor A material that has little resistance to the flow of electricity. Traditional superconductors operate at absolute zero (-459.67 degrees Fahrenheit or -273.15 degrees Celsius). Experiments in the 1980s raised the temperature to -321 degrees Fahrenheit. with a high critical temperature ([T.sub.c]) may yield new processing control techniques for other advanced materials Advanced Materials is a leading peer-reviewed materials science journal published every two weeks. Advanced Materials includes Communications, Reviews, and Feature Articles from the cutting edge of materials science, including topics in chemistry, physics, . Economically, nondestructive non·de·struc·tive adj. Of, relating to, or being a process that does not result in damage to the material under investigation or testing. non scientific measurement devices, superefficient motors, and high speed computers may soon evolve. In view of such potential utility, more than 50 000 technical papers have been published since the discovery of the HTS pheno mena in 1986. Those papers are concerned predominantly with the production, characteristics, and properties of the HTS materials. This rather enormous amount of information makes access to the needed property data a somewhat daunting daunt tr.v. daunt·ed, daunt·ing, daunts To abate the courage of; discourage. See Synonyms at dismay. [Middle English daunten, from Old French danter, from Latin exercise. Fortunately, like other areas of forefront research, the focus of the HTS effort is on the central characteristics of the phenomenon, i. e., the critical temperatures, current densities, and field strengths, along with the structure of the materials. Other properties, particularly the thermal and mechanical properties (5), are studied also but appear more obscurely in the literature. The latter properties, however, are essential to the development of practical applications of the materials. Thus, for some properties, there is a need to consolidate large amounts of data, while for other properties, there is a need to assess the reliablity of limited amounts of data. The emphasis on data evaluation leads rather naturally to the need for crystallographic data. The anisotropy anisotropy /an·isot·ro·py/ (an?i-sot´rah-pe) the quality of being anisotropic. anisotropy (an´āsôt´r of any physical property of a single crystal must be consistent with the observed symmetry in the physical structure of the crystal. By extension, anisotropy in the properties of polycrystalline Adj. 1. polycrystalline - composed of aggregates of crystals; "polycrystalline metals" crystalline - consisting of or containing or of the nature of crystals; "granite is crystalline" materials should be correlated with the degree of texturing or particle alignment in the sintered sin·ter n. 1. Geology A chemical sediment or crust, as of porous silica, deposited by a mineral spring. 2. A mass formed by sintering. v. sin·tered, sin·ter·ing, sin·ters v. bodies. Both crystal structure and texturing have important consequences for the behavior of materials subjected to external stimuli (temperature, pressure, and electromagnetic fields electromagnetic field Property of space caused by the motion of an electric charge. A stationary charge produces an electric field in the surrounding space. If the charge is moving, a magnetic field is also produced. A changing magnetic field also produces an electric field. ). Furthermore, structural data from crystallographic studies can be used to determine the coefficients of thermal expansion thermal expansion Increase in volume of a material as its temperature is increased, usually expressed as a fractional change in dimensions per unit temperature change. which, in turn, can be used in the evaluations of axial axial /ax·i·al/ (ak´se-al) of or pertaining to the axis of a structure or part. ax·i·al adj. 1. Relating to or characterized by an axis; axile. 2. and volumetric volumetric /vol·u·met·ric/ (vol?u-met´rik) pertaining to or accompanied by measurement in volumes. vol·u·met·ric adj. Of or relating to measurement by volume. derivatives of physical properties. Consequently, crystallographic data are indispensable in classifying and understanding the physical behavior of the materials, and these data help to form a basis on which to study and pursue the development of new materials. 2. Materials and Properties To be an effective resource, the scope of the information system must be consistent with the needs and interests of both the materials research community and the application designers. At the same time, the enormous body of data must be condensed con·dense v. con·densed, con·dens·ing, con·dens·es v.tr. 1. To reduce the volume or compass of. 2. To make more concise; abridge or shorten. 3. Physics a. to a more manageable and reliable subset. A balance, then, is sought between all that is available and all that is needed. That balance and the scope of the information system are influenced by three basic considerations: what materials should be covered; what properties are essential; and what measurement conditions are most relevant? Of these considerations, the first two are relatively straightforward, while the third one is a source of much concern. The approach taken in the current NIST effort to provide evaluated data for ceramics gives higher priorities to materials with greater potential for commercial applications or for advancing the scientific understanding of the materials and their properties. For HTS materials, for example, it is recognized that any potential application of these materials must anticipate the necessity of maintaining the material in a superconducting su·per·con·duct·ing adj. Having, exhibiting, or capable of superconductivity: "a revolutionary superconducting magnetic propulsion system" Colin Nickerson. state over long periods of time. Therefore, the technology of cryogenics cryogenics: see low-temperature physics. cryogenics Study and use of low-temperature phenomena. The cryogenic temperature range is from −238°F (−150°C) to absolute zero. At low temperatures, matter has unusual properties. is a critical factor in determining what will be commercially viable. Fortunately, the technology for sustaining liquid nitrogen Noun 1. liquid nitrogen - nitrogen in a liquid state atomic number 7, N, nitrogen - a common nonmetallic element that is normally a colorless odorless tasteless inert diatomic gas; constitutes 78 percent of the atmosphere by volume; a constituent of all living in a closed-cycle, regenerative re·gen·er·a·tive adj. 1. Of, relating to, or marked by regeneration. 2. Tending to regenerate. re·gen system is well developed, so that it is relatively routine to maintain a superconducting material at a temperature of 77 K, even on an industrial scale of operation. This consideration suggests that the materials with the greatest commercial interest should have [T.sub.c] > 77 K. For structural ceramics, the application environment is also a principal consideration in selecting a material. The requirements for these materials often include dimensional and mechanical stability at very high temperatures (greater than 1000[degrees]C) and durability in harsh environments. Thus, attention is usually directed towards advanced ceramics that retain their strength and hardness at high temperatures or that exhibit significant wear resistance. Overviews of the materials and properties in the NIST databases on high temperature superconductors (HTS) and structural ceramics (SCD ScD [L.] Scien´tiae Doc´tor (Doctor of Science). SCD 1 Sickle cell disease, see there 2 Subacute combined degeneration, see there 3 Sudden cardiac death, see there ) are given in Tables 1 and 2. In each case, an attempt is made to provide a comprehensive range of properties. However, the distribution of data within the two collections differs according to according to prep. 1. As stated or indicated by; on the authority of: according to historians. 2. In keeping with: according to instructions. 3. the focal interest of the material classs. For superconductors, that interest is centered on the critical temperture ([T.sub.c]) and the critical current density ([j.sub.c]) and the associated properties needed to understand the critical behavior. The majority of the HTS materials are oxide superconductors, but a useful range of the newer borocarbide superconductors is also included. For many of the materials in Table 1, the only property data available are the basic superconductor characteristics, such as the critical temperature. Because of the nonstoichiometry of HTS materials, it is not unusual for the lattice parameters at room temperature and pressure to be reported to be spoken of; to be mentioned, whether favorably or unfavorably. See also: Report as part of the HTS material identification data. Indeed, oxygen content and lattice parameters often are sufficiently well correlated that the measurement of one can be used to make an empirical estimate of the other based on the observed correlation. In contrast, studies on structural ceramics tend to focus on the mechanical properties of the materials, flexural strength Flexural strength is also known as modulus of rupture, bend strength, or fracture strength. Flexural strength is measured in terms of stress, and thus is expressed in pascals (Pa) in the SI system. being, by far, the most frequently measured property. For design purposes, mechanical and thermal properties are desired, not only as functions of temperature, but also as functions of bulk physical characteristics such as density, mean grain size, and porosity. 3. Data Evaluation Perhaps the most important consideration of a reference database is the reliability of the data. The unpleasant consequences of unreliable data can be all too readily imagined. Nevertheless, there is often a struggle between the goal of having the best data and the quandary of having no data at all. In the HTS and SCD data efforts, therefore, the development of a database is viewed as a dynamic process in which the data set is continuously subject to refinement. In this process, an effort is made to ensure the reliability of the data, while treating all data as potentially valuable (6). The resulting compromise is to use the best available data and to assign to each data set an indicator, called the data evaluation level, Table 3, to apprise the user of the current status of the data. There are four stages of data evaluation, Table 4, that may be distinguished. The stages are progressive, each stage having useful results and subsequent stages building on preceding stages. The basic effort, Stage I, involves identifying and gathering the information that is available. While the identification of suitable sources of data involves some degree of judgement, the 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. applied is more a matter of relevance than of merit. This effort is greatly facilitated by the use of computerized databases of titles and abstracts that can be searched for keywords. Upon the completion of Stage I, it is immediately possible to make comparisons of data and to obtain useful deductions about the materials and properties. Figure 1 shows a typical situation in which the critical temperature, [T.sub.c], for [YBa.sub.2][Cu.sub.3][O.sub.x] (Y:123) is examined with respect to oxygen content (7). In constructing this plot, no constraint regarding the processing of the material or its chemical or microstructural comp osition was applied. The resulting plot, not surprisingly, exhibits a considerable amount of scatter among the data points. Nevertheless, it is already clear that the value of [T.sub.c] depends on the oxygen content, and, in this figure, the dependence is roughly linear. By design, Stage II data evaluation is more discriminating than Stage I. In Stage II, attention is given specifically to the processing and composition data for the material and to the descriptions of the measurement procedures. Figure 2 illustrates how significant details can be revealed by such restrictions. For Fig. 2, the data in Fig. 1 were filtered such that only data appropriate to single phase, homogeneous specimens were used. The-clearly reproducible two-plateau characteristic of [T.sub.c] vs x for Y:123 is readily apparent. The modest goal of the data evaluation in Stage II is to ensure that the materials, measurements, and results are reasonable. In Stage III the data are examined more closely for consistency among related properties. In this stage, the emphasis is on the property relations rather than the individual measurements of the properties. For example, thermal conductivity ([kappa Kappa Used in regression analysis, Kappa represents the ratio of the dollar price change in the price of an option to a 1% change in the expected price volatility. Notes: Remember, the price of the option increases simultaneously with the volatility. ]) and thermal diffusivity In heat transfer analysis, thermal diffusivity (symbol:  ) is the ratio of thermal conductivity to volumetric heat capacity.n See expansion, thermal coefficient. ([alpha]) which, in turn, is related to the temperature dependence of the bulk density. This res ult, combined with the independently determined specific heat ([C.sub.p]), permits the correlation of thermal conductivity and diffustivity to be optimized in such a manner that the four constituent properties are simultaneously mutually consistent. The agreement between the data points and the smooth curves attests to the effectiveness of the procedure. The highest level of evaluation effort, Stage IV requires the development of explicit material models along with models describing the interactions among the constituent component of the material. Crystallographic and microstructural data are highly desirable in this work. In one study on Y:123, for example, an examination was made of how the critical temperature varies as the crystalline structure is perturbed per·turb tr.v. per·turbed, per·turb·ing, per·turbs 1. To disturb greatly; make uneasy or anxious. 2. To throw into great confusion. 3. by a variation of the oxygen content or by the application of an external pressure (9). A model involving the lattice parameters of the crystal structure, the relative atomic coordinates of the the constituent ions, and the distribution of valence electrons valence electron n. An electron in an outer shell of an atom that can participate in forming chemical bonds with other atoms. valence electron was considered in an attempt to describe the variation of [T.sub.c] under hydrostatic pressure hydrostatic pressure The pressure exerted by a fluid at equilibrium at a given point within the fluid, due to the force of gravity. Hydrostatic pressure increases in proportion to depth measured from the surface because of the increasing weight of fluid and, by extension, to predict the variation of [T.sub.c] under uniaxial uniaxial /uni·ax·i·al/ (u?ne-ak´se-al) 1. having only one axis. 2. developing in an axial direction only. uniaxial 1. having only one axis. 2. developed in an axial direction only. stress. 4. Conclusion The HTS and SCD databases have been developed to serve as reference databases for the numeric properties of nonconventional superconductors and structural ceramics. Crystallographic data are utilitzed in these databases to serve several functions. The crystallographic data sets themselves are, of course, part of the reference information characterizing the materials. Conversely, crystallographic data may be used for purposes of identification such as when lattice parameters are specified as part of the search criteria. Crystallographic data are also used both in data evaluation efforts, to help ensure that only data from comparable materials are being analyzed together, and in developing or applying models of material behavior. Many physical properties depend significantly on the phase compositions of the constituent particles, the interface or grain boundary A grain boundary is the interface between two grains in a polycrystalline material. Grain boundaries disrupt the motion of dislocations through a material so reducing crystallite size is a common way to improve strength, as described by the Hall-Petch relationship. regions, and the possible surface layers. Similarly, the size, shape, and distribution of pores, which may be treated formally as a secondary phase, can have a dramatic influence on property values. Crystallographic data often provide the key to understanding how these atomic and microstructural features affect the bulk properties of the material. [FIGURE 1 OMITTED] [FIGURE 2 OMITTED] [FIGURE 3 OMITTED]
Table 1
Materials in the HTS and SCD databases
High temperature superconductors
Class Examples (a)
Oxides Y-Ba-Cu-O, Bi(Pb)-Sr-Ca-Cu-O, ...
(>170 chemical families)
Borocarbides Y-Ni-B-C, ... (>25 chemical
families)
Structural ceramics
Class Examples (a)
Borides [TaB.sub.2], [TiB.sub.2],
[ZrB.sub.2], ...
Carbides [B.sub.4]C, SiC, TiC, diamond, ...
Nitrides AIN, BN, [Si.sub.3][N.sub.4], ...
Oxides [Al.sub.2][O.sub.3], BeO,
MgO, mullite, [SiO.sub.2],
[TiO.sub.2], [ZrO.sub.2], ...
Oxynitrides sialon, silicon oxynitride, ...
(a)HTS materials are summarized here by chemical family designations.
For example, Y-Ba-Cu-o represents all the superconducting chemical
compositions of Y, Ba, Cu, and O. This family includes
[YBa.sub.2][Cu.sub.3][O.sub.x], [YBa.sub.2][Cu.sub.4][O.sub.y], and
[Y.sub.2][Ba.sub.4][Cu.sub.7] [O.sub.z], Elemental substitutions yield
different chemical families (e.g., Y-Ba-Cu-O and Y-Ba(La)-Cu- O).
Further variations occur due to nontoichiometry
(b)SCD materials are summarized here by generic formulas. Variations
include differing sintering aids, densities, porosities, and grain
sizes.
Table 2
Principal properties in the HTS an SCD databases
Category Examples
Physical Crystallography, grain size,
density, porosity
Mechanical Elasticity (a), strength,
hardness, toughness, creep
Thermal Conductivity, diffusivity,
expansion, specific heat
Corrosion (b) Rate, activation energy, products
Conduction (c) [T.sub.c], [j.sub.c], [H.sub.c1]
[H.sub.c2], resistivity,
thermopower, Hall effect
susceptibility
(a)Elasticity tensor for single crystal specimens. Young's, shear, and
bulk moduli and Poisson's ratio for polycrystalline materials.
(b)SCD only.
(c)HTS only. Critical temperature, current density, and magnetic field
strengths are identified by a subscript c.
Table 3
Data evaluation levels
Designation Comment
Certified Standard reference values,
specific to known
production batches
Validated Confirmed via correlations and
models
Evaluated Basic acceptance criteria satisfied
Commercial Manufacturer's data for specific
commercial materials
Typical Derived from surveys of nominally
similar materials
Research Preliminary values from work in
progress
Unevaluated All other data
Table 4
Stages of data evaluation
Evaluation
Stage Scope level Comment
I Data Collection Unevaluated Publicly accessible data
II Basic Criteria Evaluated Material and measurement
specification;
documentation; comparisons
III Relational Validated Correlations and property
Analysis relations; inter-population and
value estimates possible
IV Modeling Validated Synthesis of data and theory;
predictive capability
Accepted: August 22, 2001 Available online: http://www.nist.gov/jres 5. References (1.) R. G. Munro and E. F. Begley, Standard Reference Database Number 30, Structural Ceramics, Standard Reference Data Program, NIST, Gaithersburg (1991, 1993, 1998), and webSCD, http://www.ceramics.nist.gov. (2.) R. G. Munro and E. F. Begley, Standard Reference Database Number 62, High Temperature Superconductors, Standard Reference Data Program, NIST, Gaithersburg (1995, 1997), and webHTS, http://www.ceramics.nist.gov. (3.) M. B. Maple, High [T.sub.c] oxide superconductors, MRS MRS - Modifiable Representation System. An integration of logic programming into Lisp. ["A Modifiable Representation System", M. Genesereth et al, HPP 80-22, CS Dept Stanford U 1980]. Bul. XIV (1), 20-21 (1989). (4.) Committee on Science, Engineering, and Public Policy, Report of the Research Briefing Panel on High-Temperature Superconductivity Unsolved problems in physics: What is the responsible mechanism that causes certain materials to exhibit superconductivity at temperatures much higher than around 50 kelvin? High-temperature superconductors (abbreviated high , National Academy Press, Washington, DC. (1987). (5.) R. G. Munro, Mechanical Properties, in Handbook of Superconductivity, C. P. Poole, Jr., ed., Academic Press, San Diego San Diego (săn dēā`gō), city (1990 pop. 1,110,549), seat of San Diego co., S Calif., on San Diego Bay; inc. 1850. San Diego includes the unincorporated communities of La Jolla and Spring Valley. Coronado is across the bay. (1999) pp. 569-624. (6.) R. G. Munro and H. Chen, Data evaluation methodology for high temperature superconductors, in Computerization com·put·er·ize tr.v. com·put·er·ized, com·put·er·iz·ing, com·put·er·iz·es 1. To furnish with a computer or computer system. 2. To enter, process, or store (information) in a computer or system of computers. and Networking of Materials Databases A materials database is a database used to store experimental, standards or design data for materials in such a way that they can be retrieved efficiently by humans or computer programs. : Fifth Volume, ASTM ASTM abbr. American Society for Testing and Materials STP STP or standard temperature and pressure, standard conditions for measurement of the properties of matter. The standard temperature is the freezing point of pure water, 0°C; or 273.15°K;. 1311, S. Nishijima and S. Iwata, eds., American Society for Testing and Materials, Philadelphia (1997) pp. 198-210. (7.) R. G. Munro and H. Chen, Reference relations for the evaluation of the materials properties of orthorhombic or·tho·rhom·bic adj. Of or relating to a crystalline structure of three mutually perpendicular axes of different length. orthorhombic [YBa.sub.2][Cu.sub.3][O.sub.x] superconductors, J. Am. Ceram. Soc. 79 (3), 603-608 (1996). (8.) R. G. Munro, Material properties of sintered [alpha]-SiC, J. Phys. Chem. Ref. Dat. 26 (5), 1195-1203 (1997). (9.) H. Chen and R. G. Munro, Dependence of the critical temperature on atomic structure in orthorhombic [YBa.sub.2][Cu.sub.3][O.sub.x], Phys. Rev. B 53 (18), 12496-12501 (1996). About the authors: Ronald G. Munro is a physicist in the NIST Ceramics Division of the Materials Science and Engineering Materials science and engineering A multidisciplinary field concerned with the generation and application of knowledge relating to the composition, structure, and processing of materials to their properties and uses. Laboratory. The 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. is an agency of the Technology Administration, U.S. Department of Commerce. |
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