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PLATON and STRUCTURE VALIDATION

PLATON and STRUCTURE VALIDATION. Ton Spek National Single Crystal Service Facility, Utrecht University, The Netherlands . Goettingen, 13-Oct-2007. Overview of the Talk. What is PLATON Structure Validation Concluding Remarks Copy: http://cryst.chem.uu.nl. What is PLATON.

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PLATON and STRUCTURE VALIDATION

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  1. PLATON and STRUCTURE VALIDATION Ton Spek National Single Crystal Service Facility, Utrecht University, The Netherlands. Goettingen, 13-Oct-2007

  2. Overview of the Talk What is PLATON Structure Validation Concluding Remarks Copy: http://cryst.chem.uu.nl

  3. What is PLATON • PLATON is a collection of tools for single crystal structure analysis bundled within a single SHELX compatible program. • The tools are either extended versions of existing tools or unique to the program. • The program was/is developed over of period of more than 25 years in the context of our National Single Crystal Service Facility in the Netherlands.

  4. PLATON USAGE • Today, PLATON is most widely used implicitly in its validation incarnation for all single crystal structures that are validated with the IUCr CHECKCIF utility. • Tools are available in PLATON to analyze and solve the reported issues that need attention.

  5. OTHER PLATON USAGE • PLATON also offers guided/automatic structure determination and refinement tools for routine structure analyses from scratch (i.e. the ‘Unix-only’ SYSTEM S tool and the new FLIPPER/STRUCTURE tool that is based on the Charge Flipping Ab initio phasing method). • Next Slide: Main Function Menu 

  6. Selected Tools • ADDSYM – Detection and Handling of Missed (Pseudo)Symmetry • TwinRotMat – Detection of Twinning • SOLV – Report of Solvent Accessible Voids • SQUEEZE – Handling of Disordered Solvents in Least Squares Refinement (Easy to use Alternative for Clever Disorder Modelling) • BijvoetPair – Post-refinement Absolute Structure Determination (Alternative for Flack x) • VALIDATION – PART of IUCr CHECKCIF

  7. ADDSYM • Often, a structure solves only in a space group with lower symmetry than the correct space group. The structure should subsequently be checked for higher symmetry. • About 1% of the 2006 & 2007 entries in the CSD need a change of space group. • E.g. A structure solves only in P1. ADDSYM is a tool to come up with the proper space group and to carry out the transformation ( new .res) • Next slide: Recent example of missed symmetry

  8. Organic Letters (2006) 8, 3175 Correct Symmetry ? P1, Z’ = 8 CCo

  9. Test for Higher Symmetry • Start PLATON with a .ins or .cif • Click on ADDSYM on the main menu • Analyse automatically generated result •  Display next

  10. After Transformation to P212121, Z’ = 2

  11. (Pseudo)Merohedral Twinning • Options to handle twinning in L.S. refinement available in SHELXL, CRYSTALS etc. • Problem: Determination of the Twin Law that is in effect. • Partial solution: coset decomposition, try all possibilities (I.e. all symmetry operations of the lattice but not of the structure) • ROTAX (S.Parson et al. (2002) J. Appl. Cryst., 35, 168. (Based on the analysis of poorly fitting reflections of the type F(obs) >> F(calc) ) • TwinRotMat Automatic Twinning Analysis as implemented in PLATON (Based on a similar analysis but implemented differently)

  12. TwinRotMat Example • Originally published as disordered in P3. • Solution and Refinement in the trigonal space group P-3 R= 20%. • Run PLATON/TwinRotMat on CIF/FCF • Result: Twin law with an the estimate of the twinning fraction and the estimated drop in R-value • Example of a Merohedral Twin 

  13. Ideas behind the Algorithm • Reflections effected by twinning show-up in the least-squares refinement with F(obs) >> F(calc) • Overlapping reflections necessarily have the same Theta value within a tolerance. • Generate a list of implied possible twin axes based on the above observations. • Test each proposed twin law for its effect on R.

  14. Possible Twin Axis H” = H + H’ Candidate twinning axis (Normalize !) H’ H Reflection with F(obs) >> F(calc) Strong reflection H’ with theta close to theta of reflection H

  15. Solvent Accessible Voids • A typical crystal structure has only in the order of 65% of the available space filled. • The remainder volume is in voids (cusps) in-between atoms (too small to accommodate an H-atom) • Solvent accessible voids can be defined as regions in the structure that can accommodate at least a sphere with radius 1.2 Angstrom without intersecting with any of the van der Waals spheres assigned to each atom in the structure. • Next Slide: Void Algorithm: Cartoon Style 

  16. DEFINE SOLVENT ACCESSIBLE VOID STEP #1 – EXCLUDE VOLUME INSIDE THE VAN DER WAALS SPHERE

  17. DEFINE SOLVENT ACCESSIBLE VOID STEP # 2 – EXCLUDE AN ACCESS RADIAL VOLUME TO FIND THE LOCATION OF ATOMS WITH THEIR CENTRE AT LEAST 1.2 ANGSTROM AWAY

  18. DEFINE SOLVENT ACCESSIBLE VOID STEP # 3 – EXTEND INNER VOLUME WITH POINTS WITHIN 1.2 ANGSTROM FROM ITS OUTER BOUNDS

  19. Listing of all voids in the triclinic unit cell Cg

  20. VOID APPLICATIONS • Calculation of Kitaigorodskii Packing Index • As part of the SQUEEZE routine to handle the contribution of disordered solvents in crystal structure refinement • Determination of the available space in solid state reactions (Ohashi) • Determination of pore volumes, pore shapes and migration paths in microporous crystals

  21. SQUEEZE • Takes the contribution of disordered solvents to the calculated structure factors into account by back-Fourier transformation of density found in the ‘solvent accessible volume’ outside the ordered part of the structure (iterated). • Filter: Input shelxl.res & shelxl.hkl Output: ‘solvent free’ shelxl.hkl • Refine with SHELXL or Crystals • Note:SHELXL lacks option for fixed contribution to Structure Factor Calculation.

  22. SQUEEZE Algorithm • Calculate difference map (FFT) • Use the VOID-map as a mask on the FFT-map to set all density outside the VOID’s to zero. • FFT-1 this masked Difference map -> contribution of the disordered solvent to the structure factors • Calculate an improved difference map with F(obs) phases based on F(calc) including the recovered solvent contribution and F(calc) without the solvent contribution. • Recycle to 2 until convergence.

  23. SQUEEZE In the Complex Plane Fc(solvent) Fc(total) Fc(model) Fobs Solvent Free Fobs Black: Split Fc into a discrete and solvent contribution Red: For SHELX refinement, temporarily substract recovered solvent contribution from Fobs.

  24. Comment • The Void-map can also be used to count the number of electrons in the masked volume. • A complete dataset is required for this feature. • Ideally, the solvent contribution is taken into account as a fixed contribution in the Structure Factor calculation (CRYSTALS) otherwise it is substracted temporarily from F(obs)^2 (SHELXL) and re-instated afterwards with info saved beyond column 80 for the final Fo/Fc list.

  25. Publication Note • Always give the details of the use of SQUEEZE in the comment section • Append the small CIF file produced by PLATON to the main CIF • Use essentially complete data sets with sufficient resolution only. • Make sure that there is no unresolved charge balance problem.

  26. Post-Refinement Absolute Structure Determination • Generally done as part of the least squares refinement with a ‘twinning’ parameter.(Flack x) • Determine Flack x parameter + su • Validity Analysis following the Flack & Bernardinelli criteria. • Often indeterminate conclusions obtained in the case of light atom structures • Alternative approaches offered by PLATON 

  27. Scatter Plot of Bijvoet Differences • Plot of the Observed Bijvoet Differences against the Calculated Differences. • A Least-Squares line is calculated • The Green least squares line should run from the lower left to the upper right corner for the correct absolute structure. • Vertical bars on data points indicate the su on the Bijvoet Difference. Example 

  28. Excellent Correlation

  29. Practical Aspects of Flack x • The structure should contain atoms with sufficiently strong anomalous dispersion contributions for the radiation used (generally MoKa) in the experiment (e.g. Br). • Preferably, but not nesessarily, a full set of Friedel pairs is needed. (danger: correlation !) • Unfortunately, many relevant pharmaceuticals contain in their native form only light atoms that at best have only weak anomalous scattering power and thus fail the strict Flack conditions.

  30. Light Atom Targets Options for the Absolute Structure Determination of Light Atom Compounds • Add HBr in case of tertiary N. • Co-crystallize with e.g. CBr4. • Co-crystallize with compound with known. absolute configuration. • Alternative: Statistical analysis of Bijvoet pair differences.

  31. Statistical Analysis of Bijvoet Pairs • Many experimentalists have the feeling that the official Flack x method is too conservative. • This Experience is based on multiple carefully executed experiments with compounds with known absolute structure. • The feeling is that also in light atom structures the average of thousands of small Bijvoet differences will point in the direction of the correct enantiomorph. • Example: The Nonius CAD4 test crystal 

  32. MoKa, P212121 Example: Ammonium Bitartrate Test

  33. Ammonium BiTartrate (MoKa)

  34. Bayesian Approach • Rob Hooft (Bruker) has developed an alternative approach for the analyses of Bijvoet differences that is based on Bayesian statistics. (Paper under review) • Under the assumption that the material is enantiopure, the probability that the assumed absolute structure is correct, given the set of observed Bijvoet Pair Differences, is calculated. • An extension of the method also offers the Fleq y (Hooft y) parameter to be compared with the Flack x. • Example: Ascorbic Acid, P21, MoKa data 

  35. MoKa Natural Vitamin C, L-(+)Ascorbic Acid

  36. L-(+) Ascorbic Acid

  37. Hooft y Proper Procedure • Collect data with an essentially complete set of Bijvoet Pairs • Refine in the usual way (preferably) with BASF and TWIN instructions (SHELXL) • Structure Factors to be used in the analysis are recalculated in PLATON from the parameters in the CIF (No Flack x contribution).

  38. Do we need Validation ?Some Statistics • Validation CSD Entries 2006 + 2007 • Number of entries: 35760 • # of likely Space Group Changes: 384 • # of structures with voids: 3354 • Numerous problems with H, O, OH, H2O etc.

  39. Structure Validation • Some Examples of Recently Published Structures with a Problem that Apparently Escaped the Attention of the Referees. • Promote CheckCif as the Current (Partial) IUCr Solution to this problem. • Details of what PLATON can do in this Context. • Next: An Example of a strange structure in the CSD 

  40. Structure of an Interesting CH3 Bridged Zr Dimer Paper has been cited 47 times ! So can we believe this structure? The Referees did …! But … H .. H = 1.32 Ang. !

  41. Comment • The methyl hydrogen atoms are expected outside the Zr2C2 ring (and indeed have been found in similar structures) • Referees likely had no access to (or did not access) the primary data other than the ORTEP illustration in the paper. • General problem: A limited number of experts is available to referee too many structural papers that offer only limited primary (deposited) data.

  42. Dalton Trans. (2001), 729-735 Next Slide: ORTEP with downloaded CIF data 

  43. FromCSD

  44. Organometallics (2006) 25, 1511-1516 Next Slide: This is why the reported density is low and the R and Rw high 

  45. Solvent Accessible Void of 235 Ang3 out of 1123 Ang3 Not Accounted for in the Refinement Model

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