Exploiting texture to estimate the relative intensities of overlapping reflections

Baerlocher, Christian; McCusker, Lynne B.; Prokic, Sinisa; Wessels, Thomas

doi:10.1524/zkri.219.12.803.55861

Cited by 19 publications

(14 citation statements)

References 27 publications

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“…The method presented here is especially useful for crystals that are too small, samples that are not pure, or zeolites with complicated structures. A.: A rational design of alkyl-aromatics dealkylation-transalkylation catalysts using C 8 Table S3. Final atomic position compared with the position refined by X-ray powder diffraction.…”

Section: Discussionmentioning

confidence: 99%

“…Several novel approaches such as incorporating crystal chemical information (FOCUS) [3,4], using pore/channel information to generate structure envelopes [5,6], or using textured samples to generate more singlecrystal-like data [7,8] have been developed for this purpose. However, when the structures become too complex and a large portion of the reflections overlap in the powder diffraction pattern, structure determination from X-ray powder diffraction data alone is very difficult.…”

Section: Introductionmentioning

confidence: 99%

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Structure determination of the zeolite IM-5 using electron crystallography

Sun

Hovmöller

et al. 2010

Zeitschrift Für Kristallographie

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Abstract. The structure of the complex zeolite IM-5 (Cmcm, a ¼ 14.33(4) A, b ¼ 56.9(2) A, c ¼ 20.32(7) A) was determined by combining selected area electron diffraction (SAED), 3D reconstruction of high resolution transmission electron microscopy (HRTEM) images from different zone axes and distance least squares (DLS) refinement. The unit cell parameters were determined from SAED. The space group was determined from extinctions in the SAED patterns and projection symmetries of HRTEM images. Using the structure factor amplitudes and phases of 144 independent reflections obtained from HRTEM images along the [100], [010] and [001] directions, a 3D electrostatic potential map was calculated by inverse Fourier transformation. From this 3D potential map, all 24 unique Si positions could be determined. Oxygen atoms were added between each Si--Si pair and further refined together with the Si positions by distance-least-squares. The final structure model deviates on average 0.16 A for Si and 0.31 A for O from the structure refined using X-ray powder diffraction data. This method is general and offers a new possibility for determining the structures of zeolites and other materials with complex structures.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Structure determination of the zeolite IM-5 using electron crystallography

Sun

Hovmöller

et al. 2010

Zeitschrift Für Kristallographie

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“…Several ideas were developed to assist (and improve) the extraction of integrated intensities from the powder pattern: those where no additional data must be collected, like the Patterson function (Chapter 12 in [3]), triplet relation based (Chapter 11 in [3]) or maximum entropy related (Chapter 14 in [3]) and those based on multiple datasets, like texture and thermal dilatation based (Chapter 9 in [3] and [21]). …”

Section: Methods Using Intensity Extractionmentioning

confidence: 99%

“…Intense development of PM methods was started by zeolite research [26]. The texture method for integrated intensities extraction was developed on zeolite samples [21]. A nice topology-guided dual space method has been developed for zeolites [28], but the approach is easily modified to any other class of compound with a typical underlying topology.…”

Section: Non-molecular Compounds: Extended Solidsmentioning

confidence: 99%

Crystal Structures from Powder Diffraction: Principles, Difficulties and Progress

Černý

2017

Crystals

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Abstract:The structure solution from powder diffraction has undergone an intense evolution during the last 20 years, but is far from being routine. Current challenges of powder crystallography include ab initio crystal structure determination on real samples of new materials with specific microstructures, characterization of intermediate reaction products from in situ, in operando studies and novel phases from in situ studies of phase diagrams. The intense evolution of electron diffraction in recent years, providing an experimental (precession) and theoretical (still under intense development) solution to strong dynamic scattering of electrons, smears the traditional frontier between poly-and single-crystal diffraction. Novel techniques like serial snapshot X-ray crystallography point in the same direction. Finally, for the computational chemistry, theoreticians hand-in-hand with crystallographers develop tools where the theory meets experiment for crystal structure refinement, which becomes an unavoidable step in the validation of crystal structures obtained from powder diffraction.Keywords: powder diffraction; structure solution; X-ray diffraction; DFT calculations; electron diffraction The structure solution means in this article determination of the (average) 3D-periodic arrangement of the atoms in the crystal using mainly the information content of Bragg scattering in the diffraction pattern. The case of aperiodic crystals (modulated and quasicrystals), of short-range order (diffuse scattering), as well as of nano-crystals (crystals without measurable Bragg signals) will not be discussed here. The structure prediction, on the other hand, will be used in the sense of the determination of the 3D arrangement of the atoms in the crystal using mainly first-principle calculations, and any experimental observation, like the diffraction pattern, is used only for the validation of the predicted structural model. Indexing: Still a BottleneckDespite an intense development of indexing algorithms in the last 20 years, the detection of the correct lattice may still be a bottleneck of the structure solution in the case of low resolution powder patterns or in the case of monoclinic and triclinic symmetry. A review of known indexing algorithms may be found in Chapter 7 of [3], Chapter 5 of [6] and Chapter 7 of [7]. Each crystallographer and each crystal may work better with a particular algorithm, but as is said in another excellent indexing The advantage of the dichotomy algorithm is its speed (especially in Fox) and its robustness towards low data quality. Indexing is followed by space group determination, which is based on systematic extinction analysis supported by the knowledge of crystal physical properties, like piezoelectricity, the presence of which excludes centrosymmetric space groups. Fairly robust algorithms for space group determination are based on full pattern fitting (Le Bail or Pawley), available in most software packages. The indexing can be quite difficult for the crystals lying on opposite ends of the s...

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“…Varying the temperature of the sample for low-symmetry unit cells often leads to anisotropic thermal expansion, and therefore allows overlapped peaks to be untangled (Shankland et al, 1997;Brunelli et al, 2003). Similarly, if a sample can be prepared with a significant degree of preferred orientation, then overlapped peaks will have different intensities depending on the orientation of the sample (Dahms & Bunge, 1986;Bunge et al, 1989;Cerny, 1996;Baerlocher et al, 2004). Combining multiple data sets together, where either the cell parameters or the preferred orientation are different, gives some information about the way in which the overlapped peaks should be partitioned.…”

Section: Improvements In Data Quality Via the Use Of Multiple Data Setsmentioning

confidence: 99%

Powder crystallography on macromolecules

Margiolaki

Wright

2007

Acta Cryst Sect A

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Following the seminal work of Von Dreele, powder X-ray diffraction studies on proteins are being established as a valuable complementary technique to singlecrystal measurements. A wide range of small proteins have been found to give synchrotron powder diffraction profiles where the peak widths are essentially limited only by the instrumental resolution. The rich information contained in these profiles, combined with developments in data analysis, has stimulated research and development to apply the powder technique to microcrystalline protein samples. In the present work, progress in using powder diffraction for macromolecular crystallography is reported.

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Exploiting texture to estimate the relative intensities of overlapping reflections

Cited by 19 publications

References 27 publications

Structure determination of the zeolite IM-5 using electron crystallography

Structure determination of the zeolite IM-5 using electron crystallography

Crystal Structures from Powder Diffraction: Principles, Difficulties and Progress

Powder crystallography on macromolecules

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