Atomic Dispacement Parameter Nomenclature. Report of a Subcommittee on Atomic Displacement Parameter Nomenclature

Trueblood, K. N.; Bürgi, Hans‐Beat; Burzlaff, H.; Dunitz, J. D.; Gramaccioli, C. M.; Schulz, H.; Shmueli, U.; Abrahams, S. C.

doi:10.1107/s0108767396005697

Cited by 356 publications

(254 citation statements)

References 20 publications

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“…Following the discussion by Trueblood et al (39), when the temperature effect on the diffraction intensity I of a Bragg reflection is taken into account, Eq. 1 can be modified as follows:…”

Section: Resultsmentioning

confidence: 99%

On the dynamical nature of the active center in a single-site photocatalyst visualized by 4D ultrafast electron microscopy

Yoo

Thomas

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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Understanding the dynamical nature of the catalytic active site embedded in complex systems at the atomic level is critical to developing efficient photocatalytic materials. Here, we report, using 4D ultrafast electron microscopy, the spatiotemporal behaviors of titanium and oxygen in a titanosilicate catalytic material. The observed changes in Bragg diffraction intensity with time at the specific lattice planes, and with a tilted geometry, provide the relaxation pathway: the Ti 4+ =O 2− double bond transformation to a Ti 3+ −O 1− single bond via the individual atomic displacements of the titanium and the apical oxygen. The dilation of the double bond is up to 0.8 Å and occurs on the femtosecond time scale. These findings suggest the direct catalytic involvement of the Ti 3+ −O 1− local structure, the significance of nonthermal processes at the reactive site, and the efficient photo-induced electron transfer that plays a pivotal role in many photocatalytic reactions.ultrafast electron microscopy | single-site photocatalysis | titanium based photocatalyst | ulatrafast phenomena | time-resolved microscopy S ingle-site catalysts of both the thermally and photoactivated kind now occupy a prominent place in industrial-and laboratory-scale heterogeneous catalysis (1-8). Among the most versatile of these are the ones consisting of coordinatively unsaturated transition metal ions (Ti, Cr, Fe, Mn. . .) that occupy substitutional sites in well-defined, three-dimensionally extended, open-structure silicates of the zeolite type. The well-known and most widely used are the 4-or 5-coordinated Ti(IV) ions accommodated within the crystalline phase of silica, silicalite (9-14).Titanosilicates, especially, are used extensively both industrially and in the laboratory for a wide range of chemo-, regio-, and shapeselective oxidations of organic compounds (15-18). These single-site heterogeneous photocatalysts are quite distinct from those typified by TiO 2 , SrTiO 3 , and other titaniferous photocatalysts where the Ti(IV) ions are in 6-coordination; and where, in interpreting the processes involved in harnessing solar radiation, electronic band structure considerations hold sway in preference to the localized states (see, e.g., refs. 19, 20). It has been demonstrated (16-18, 21, 22) that single-site, coordinatively unsaturated Ti(IV)-centered photocatalysts are especially useful in the aerial oxidation of environmental pollutants in the photodegradation of NO (to N 2 and O 2 ), of H 2 O (to H 2 and O 2 ), and in the photocatalytic reduction of CO 2 to yield methanol. There is an exigent need to explore the precise nature of the electronic, temporal, and spatial changes accompanying the initial act of photoabsorption that sets in train the ensuing elementary chemical processes that are of vital environmental significance in, for example, the utilization of anthropogenic CO 2 as a chemical feedstock (23).Here, we report the use of 4D ultrafast electron microscopy (UEM) (24-26) to trace the spatiotemporal behavior of the Ti(IV) and O ...

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“…Following the discussion by Trueblood et al (39), when the temperature effect on the diffraction intensity I of a Bragg reflection is taken into account, Eq. 1 can be modified as follows:…”

Section: Resultsmentioning

confidence: 99%

On the dynamical nature of the active center in a single-site photocatalyst visualized by 4D ultrafast electron microscopy

Yoo

Thomas

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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“…In cases where the expressions in angle brackets may be approximated by Gaussians we can write hexp ð2pihuÞi ¼ exp ½À2p 2 hðhuÞ 2 i ¼ exp ðÀh T bhÞ (see [10]), where b is a matrix representing dimensionless atomic displacement parameters (ADPs). The components of b are defined as b ij ¼ 2p 2 a * i a * j U ij , where U ij are the frequently used ADPs in units of ðlengthÞ 2 and a * i and a * j are the lengths of the i-th and j-th reciprocal space vectors.…”

Section: Theory 21 Definitionmentioning

confidence: 99%

The three-dimensional pair distribution function analysis of disordered single crystals: basic concepts

Weber¹,

Simonov

2012

Zeitschrift für Kristallographie

107

132

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Abstract. Theory and principles of the three-dimensional pair distribution function analysis of disordered single crystals are introduced. The mathematical framework is presented and the appearance of pair distribution function patterns is discussed on the examples of some basic disorder models. It is further demonstrated how pair distribution function maps are affected by typical experimental problems. Approaches for a better understanding of such effects and strategies for a proper handling of artifacts in diffuse scattering experiments are proposed.

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“…Most of these analyses are concerned with protein structure and conformation. In contrast, much less attention has been paid to the atomic displacement parameter (Trueblood et al, 1996), B-values obtained from X-ray crystal structure analysis of proteins. The efforts in this direction have been concerned mainly with optimizing methods for prediction of antigenicity and flexibility of different polypeptide segments of a protein (Ragone et al, Reprint requests to: M.R.N.…”

mentioning

confidence: 99%

Analysis of temperature factor distribution in high‐resolution protein structures

1997

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The temperature factors obtained from X-ray refinement of proteins at high resolution show large variations from one structure to another. However, the B-values expressed in units of standard deviation about their mean value @'-factor) at the Ccu atoms show remarkably characteristic frequency distribution. In all of the 1 I O proteins examined in this study, the frequency distribution exhibited a bimodal distribution. The peaks in the B'-factor frequency distribution occur at -1.1 and 0.4 for a bin size of 0.5. The peak at lower temperature factor corresponds largely to buried residues, whereas the peak at larger value corresponds to exposed residues. The distribution could be accurately described as a superposition of two Gaussian functions. The parameters describing the distribution are therefore characteristic of protein structures. The frequency distribution for a given amino acid over all the proteins also shows a similar bimodal distribution, although the areas under the two Gaussians differ from one amino acid to another. The area under the frequency distribution curve for any interval in B'-factor represents the propensity of the amino acid to occur in that interval. This propensity is related both to the hydrophilicity/hydrophobicity of the residue and the tendency of the residue to impose a different degree of rigidity on the polypeptide chain. The frequency distribution of stretches of high B'-factors departs appreciably from that expected for a random distribution. The correlation in the B-values of sequentially proximal residues is probably responsible for the bimodal distribution.Keywords: accessibility; Gaussian functions; proteins; statistics; temperature factors Statistical analysis has formed a large component of the research efforts put forth to understand protein structure and function, due to the enormous diversity and complexity of their structures (Johnson et al., 1994). Statistical approaches have been developed to predict the secondary structure from the primary sequence (Chou & Fasman 1974; Gamier et al., 1978; Gamier, 1990) and for testing the compatibility of model tertiary folds for a given sequence of unknown structure (Bowie et al., 1991;Luthy et al., 1991Luthy et al., , 1992. A variety of statistical analyses has also been performed on conformational states of main chains and side chains (Dunbrack & Karplus, 1993), hydrogen bonding (Ippolito et al., 1990), water structure (Thanki et al., 1991), and topological features of secondary structural elements (Levitt & Chothia, 1976;Taylor & Thomton, 1983). Most of these analyses are concerned with protein structure and conformation. In contrast, much less attention has been paid to the atomic displacement parameter (Trueblood et al., 1996), B-values obtained from X-ray crystal structure analysis of proteins. The efforts in this direction have been concerned mainly with optimizing methods for prediction of antigenicity and flexibility of different polypeptide segments of a protein (Ragone et al., Reprint requests to: M.R.N. Murth...

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Atomic Dispacement Parameter Nomenclature. Report of a Subcommittee on Atomic Displacement Parameter Nomenclature

Cited by 356 publications

References 20 publications

On the dynamical nature of the active center in a single-site photocatalyst visualized by 4D ultrafast electron microscopy

On the dynamical nature of the active center in a single-site photocatalyst visualized by 4D ultrafast electron microscopy

The three-dimensional pair distribution function analysis of disordered single crystals: basic concepts

Analysis of temperature factor distribution in high‐resolution protein structures

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