international union of crystallography\(\def\hfill{\hskip 5em}\def\hfil{\hskip 3em}\def\eqno#1{\hfil {#1}}\)

Journal logoSTRUCTURAL
CHEMISTRY
ISSN: 2053-2296

Notes for authors 2008

Keywords: Notes for authors.

Acta Crystallographica Section C: Crystal Structure Communications publishes full papers with details of crystal structures determined by diffraction methods. It specializes in the rapid dissemination of high-quality studies of novel and challenging crystal and molecular structures of interest in the fields of chemistry, biochemistry, mineralogy, pharmacology, physics and materials science. The unique checking, editing and publishing facilities of the journal ensure the highest standards of structural reliability and presentation, while providing for reports on studies involving special techniques or difficult crystalline materials.

1. Submission requirements

1.1. Author checking of manuscripts

All papers must be submitted in Crystallographic Information File (CIF) ASCII format (MIME or other encoded formats should be avoided if possible). Details about CIFs are given in Hall, Allen & Brown [Acta Cryst. (1991), A47, 655–685] . Guidelines for the preparation and editing of a CIF, the data items required therein, standard data codes and keywords, CIF templates, example CIFs, and data-validation criteria and procedures are available via the online author help page (see §7[link]). A general CIF editor (enCIFer) is available from https://www.ccdc.cam.ac.uk/products/encifer/index.html ; a CIF editor for authors, publCIF, is available from //journals.iucr.org/c/services/cifinfo.html . The Section Editor, Co-editors and Editorial Office staff are also available to assist any author with any technical CIF problems. Please note that this help does not include rewriting papers which do not reach the standards specified in §1.7.[link]

Authors are required to pre-check their submission using the checkcif service at //journals.iucr.org/services/cif/checking/checkfull.html . Any reported problems with the submitted data will need to be corrected before submission. If the report contains validation alerts about the consistency, adequacy or quality of the data, these will need to be addressed, or, if the authors consider there are specific valid or unavoidable reasons for these alerts, the validation response form (VRF) supplied by checkcif must be completed and included in the submitted CIF, preferably with the addition of appropriate explanatory text in the published experimental section of the CIF.

The text and tables of a paper may be previewed by sending the CIF (after completing the pre-check) to the printcif service at //journals.iucr.org/services/cif/printcif.html or by using publCIF.

1.2. Categories of submission

Section C publishes two categories of papers. The requested category must be specified in the submitted CIF as _publ_requested_category, using one of the codes listed below.

(a) Full papers describe one or more structure determinations. These submissions are validated (see §3[link]) and peer reviewed. The accepted paper is printed in the journal and is accessible electron­ically, together with the CIF and structure factors, from the Crystallography Journals Online service at //journals.iucr.org (see §7[link]). The category codes used to identify these papers are FI for inorganic, FM for metal–organic, and FO for organic structures.

(b) Addenda and Errata are short printed papers describing additions to, comments on, or errata to existing Section C publications and are not intended for interim reports of work in progress. The text should not exceed 1000 words. Addenda and Errata are peer reviewed. The category code for these papers is AD.

1.3. Method of submission

Full details of the submission procedure can be found at //journals.iucr.org/c/services/helpsubmit.html. CIFs must be submitted via the web at //journals.iucr.org/c/services/submitbdy.html . All submitted CIFs must have been pre-checked using the facilities described in §1.1[link].

During the submission procedure, authors will be required to submit additional electronic files; these include the chemical scheme (see §2.10), crystallographic diagrams (see §2.11) and structure factors (see §2.14) or powder diffraction data (see §2.13). Authors will also be asked to agree to transfer the copyright of their paper to the IUCr (see §1.9[link]).

On completion of the submission procedure, each paper will be assigned an Editorial Office refcode. The refcode has two letters and four digits (e.g. fg1795), with the two letters identifying the assigned Co-editor; the refcode should be used in all subsequent communications with the Editorial Office and Co-editor.

Authors should provide a brief statement in the _publ_contact_letter section of the submitted CIF outlining what is novel about the structure(s) that merits publication in Section C.

1.4. Submission of related structures

Authors studying a series of closely related structures are strongly encouraged to submit these for publication as a single paper. The CIF approach is well suited to multi-structure submissions. The journal reserves the right to require that two or more single structure papers on closely related materials be merged.

1.5. Previously published structures

If a structure has been redetermined correctly and the discussion adds significantly to the information already in the public domain then the paper can be considered for publication.

1.6. Languages of submission

The languages of publication are English, French, German and Russian.

1.7. Quality of writing

Papers should be clearly written and grammatically correct. If the Co-editor concludes that language problems would place an undue burden on the referee(s), the manuscript may be returned to the authors without review. Details of language-editing services can be found at //journals.iucr.org/services/languageservices.html .

1.8. Author's warranty

The submission of a paper is taken as an implicit guarantee that the work is original, that it is the author(s) own work, that all authors concur with and are aware of the submission, that all workers involved in the study are listed as authors or given proper credit in the acknowledgments, that the manuscript has not already been published (in any language or medium), and that it is not being considered and will not be offered elsewhere while under consideration for an IUCr journal. The inclusion of material in an informal publication, e.g. a preprint server or a newsletter, does not preclude publication in an IUCr journal.

The co-authors of a paper should be all those persons, and only those persons, who have made significant scientific contributions to the work reported, including the ideas and their execution, and who share responsibility and accountability for the results. Other contributions should be indicated in an Acknowledgments section. An administrative relationship to the investigation does not of itself qualify a person for co-authorship (but it may be appropriate to acknowledge major administrative assistance).

Important considerations related to publication have been given in the ethical guidelines published in Acc. Chem. Res. (2002), 35, 74–76 and Graf et al. [Int. J. Clin. Pract. (2007), 61(Suppl. 152), 1–26 ].

1.9. Copyright

Except as required otherwise by national laws, an author will be required to agree to the transfer of copyright before a manuscript can be accepted.

1.10. Handling of manuscripts

Each submitted CIF is checked in the Editorial Office for completeness and data integrity. If incomplete or inadequate it will be returned to the contact author for correction. Some of the specific data standards are summarized in §3[link], while full details of the required data items and the data-validation criteria are available via the online CIF help page (see §7[link]). For papers failing to meet these criteria, a completed validation response form (VRF) giving reasons for the failure must be included in the CIF. The Co-editor will assess the validity of the explanation as part of the review process.

The Co-editor is responsible for the review steps and future communications with the authors up to the acceptance stage. All communications to authors will normally be sent electronically to the e-mail address provided in the CIF. Authors who anticipate or become aware of difficulties with their e-mail service should alert the Co-editor as soon as they are aware that there is a problem. If nothing untoward is noted during the review, the paper will be prepared for immediate electronic publication. If problems are perceived, the authors will be contacted directly and asked to rectify these before acceptance of the submission. Failure to respond to a communication from either a Co-editor or the Editorial Office staff within one month will result in the automatic withdrawal of the paper. If major revisions are made to the submission, the journal reserves the right to reset the date of receipt of the paper to the date of resubmission. If a manuscript is not acceptable after two revisions it will not be considered further. A paper that has been rejected must not be resubmitted unless the reasons given for the rejection have been fully addressed in the revised version.

Once a paper is accepted, it is the responsibility of the Managing Editor to prepare the paper for printing and to correspond with the authors and/or the Co-editor to resolve publication ambiguities or inadequacies. The date of acceptance that will appear on the published paper will be the date on which the Managing Editor receives the last item needed. The Section Editor reviews all accepted papers and reserves the right to make appropriate changes to ensure conformity with Section C standards; in the unlikely event of a serious problem being detected at this stage, the authors will be contacted promptly.

1.11. Author grievance procedure

An author who believes that a paper has been unjustifiably treated by the Co-editor may appeal initially to the Section Editor for a new review and, finally, to the Editor-in-Chief of IUCr journals if the author is still aggrieved by the decision. The initial appeal must be made within 3 months of rejection of the paper. The decision of the Editor-in-Chief is final. Any resubmission to another Co-editor will be forwarded to the Section Editor.

1.12. File transfer

After initial submission, files should be uploaded via the web interface only after a specific request from a Co-editor; these resubmitted files should be uploaded at the web address provided by the Co-editor.

2. Publication requirements

The publication requirements for the text, tabular and graphical material are described in this section. The standards for numerical and codified data are summarized in §3[link], and a list of all data items required for submission is available via the online CIF help page (see §7[link]).

2.1. Title and authors

The Title should be short and informative; in many cases just the name(s) of the compound(s) studied will be perfectly adequate. Avoid complicated IUPAC names and redundant phrases such as `Crystal structure of…'. However, if the paper describes special techniques, such as powder, neutron or synchrotron diffraction studies, this could be alluded to in the title. The full first name of each author is preferred. The e-mail address of the correspondence author should be included in the CIF using the data item _publ_contact_author_email. This is the e-mail address which will be used for all subsequent communications with the authors, including despatch of electronic proofs. If the e-mail address of the submitting author is different from that of the correspondence author, only that of the correspondence author will appear in the published version of the paper. Note that the data items _publ_section_title_footnote and _publ_author_footnote are available, if required, for inserting footnotes to the title and to individual authors. If the paper describes the redetermination of a previously reported structure, this should be indicated in the Title.

2.2. Synopsis (required only for inorganic papers)

The synopsis should be one or two sentences (less than 40 words) in length, summarizing the main crystallographic results; it should be given in _publ_section_synopsis. There is no need to give formulae in the synopsis.

2.3. Abstract

The Abstract must be written in English, be informative, should summarize only the most important aspects of the study, and should clearly state the scientific impact of the study. It should be capable of being understood on its own without access to the text or figures. It should not contain the crystal data or, usually, the space group. The systematic IUPAC name and the chemical formula should be given here, if they are not included in the Title. The Abstract should include mention of any crystallographically imposed symmetry or the presence of more than one molecule (or formula unit) in the asymmetric unit of the structure. Principal structural geometry results can be given here. Literature references should be avoided if possible; if required, they must be given in full, e.g. [Bond, A. D., Davies, J. E. & Kirby, A. J. (2001). Acta Cryst. E57, o1242–o1244.].

2.4. Comment

The Comment is the descriptive section of a submission. For publication in Acta Crystallographica Section C, the study must warrant significant discussion (i.e. provide substantial added value to the numerical data freely available in the CIF). The Comment is expected to be an informative but concise discussion of the novel aspects of the study, and include the following key aspects:

(a) The reasons for the study.

(b) The origin of the material studied, including background material. [Note that details of the chemical extraction, synthesis and crystallization processes should be given in the Experimental section (see §2.5[link]).]

(c) Information supporting the reported structure(s) based on other chemical or physical techniques.

(d) Novel or unusual aspects of the coordination, geometry, conformation, crystal packing, hydrogen bonding, etc. A discussion of geometry values that agree with established values (see International Tables for Crystallography, Volume C, §§9.4–9.6) is not warranted. The Comment should not be just a list of observations about the structure (for example, just stating, without description, that hydrogen-bonding or other weak interactions exist), but should include an analysis and discussion of how these observations help the understanding of the chemical, physical or structural properties of the compound and further the aims of the study stated in the opening paragraph, plus a detailed comparison with any closely related structures, where such exist. Numerical values reported in Tables should generally not be repeated in the text.

(e) A discussion of intermolecular interactions, if warranted, should describe the motifs and networks generated, but over-analysing weak interactions or claiming that such interactions are significantly `structure stabilizing' should be avoided. A useful commentary commentary on hydrogen bonds is available at the online CIF help page (see §7[link]).

2.5. Experimental data

Principal experimental data are extracted from the CIF and are tabulated under the sub-headings Crystal data, Data collection and Refinement. Some numerical items may be formatted with a revised number of decimal places to conform to a consistent style for the journal. The descriptive text item _publ_section_exptl_prep should give sufficient information on the chemical and crystal preparation, and identification (e.g. on melting points and densities), to reproduce the experiment. Additional details [e.g. lengthy synthesis descriptions and long lists of spectroscopic (NMR, IR etc.) data] supporting the crystallographic study should be placed in the _exptl_special_details section of the CIF, which is available from Crystallography Journals Online . Spectroscopic data should be reported in the _publ_section_exptl_prep section only when assignments are given. The item _publ_section_exptl_refinement should be used to provide details of how H atoms were treated and report the ranges of X—H dimensions. Any unusual aspects of the data collection, space-group identification, data processing, structure determination and refinement (including any restraints used and the treatment of disorder) should also be given here. Routine material should be placed in the _refine_special_details section and will be available from Crystallography Journals Online (see §7[link]).

2.6. Acknowledgements

Acknowledgement should be given for any assistance provided to the study (see §1.8[link]).

2.7. References

References to published work must be cited in the format detailed in §6[link]. If reference is made to unpublished work, prior consent must be first obtained from the authors of that work. Identification of individual structures in the paper by use of database reference (identification) codes should be accompanied by a full citation of the original literature in the reference list.

2.8. Atomic sites

The _atom_site_ coordinate and displacement parameters must be supplied with standard uncertainty values (see §5.1[link] and §2.15[link]). The parameter constraints and restraints applied to the refinement process, and the anisotropic atomic displacement parameters (as Uij) must also be supplied. Note that only U or Uij values are acceptable for atomic displacement parameters. The atom numbering should follow some recognised scheme (see §5.1[link]) and the atom list should be in some sensible (not random) order. H-atom labels should be directly related to the atom to which they are bonded.

2.9. Selected geometrical data

Full details of molecular dimensions, including those involving H atoms, should be supplied, but only values that are of special interest should be flagged for printing by setting the _geom_..._flag value to yes. Torsion angles if provided in the CIF, should not normally include those involving H atoms; those in which three of the atoms are nearly collinear should be removed. The data to be printed will be reviewed by the Co-editor and Section Editor. All submitted geometry data should be in some sensible order and are available to readers from Crystallography Journals Online (see §7[link]).

2.10. Chemical scheme

A chemical structural diagram (typical examples are shown below) must be included for a molecular compound. Authors are required to submit such diagrams electronically in one of the formats listed in §4[link]. The diagram should be complete, showing all species present in the structure, including counter-ions and solvent molecules in their correct proportions. The relative or absolute stereochemistry must be shown and should be consistent with the Crystallographic diagram (§2.11[link]), the data reported in the Abstract (§2.3[link]), Comment (§2.4[link]) and Title (§2.1[link]). Hydrogen bonding should not normally be indicated in the diagram.

[Scheme 1]
[Scheme 2]

2.11. Crystallographic diagrams

Diagram requirements are given in §4[link]. A labelled displacement ellipsoid diagram is normally required for each species either for publication or to be used in the review process. Authors are also encouraged to supply additional figures, e.g. packing diagrams, provided that they display features of interest and are fully described in the text. Figures submitted in colour will be printed in black and white but will usually appear in colour in Crystallography Journals Online (see §7[link]).

2.12. Contents

The Table of Contents of the journal will list the title and author(s) of all papers. Each entry will be accompanied by either a chemical structural scheme (see §2.10[link]) for molecular compounds or a written synopsis for compounds that cannot be shown as a chemical structural scheme.

2.13. Powder diffraction data

Authors of powder diffraction papers should consult the notes provided at //journals.iucr.org/services/cif/powder.html . For papers that present the results of powder diffraction profile fitting or refinement (Rietveld) methods, the primary diffraction data, i.e. the numerical intensity of each measured point on the profile as a function of scattering angle, should be deposited. Papers reporting Rietveld refinements should include a figure showing the diffraction profile and the difference between the measured and calculated profiles.

2.14. Structure factors

The reflection data h, k, l, Ymeas, σYmeas, Ycalc (where Y is I, F2 or F), must be supplied as an electronic file in CIF format during the submission process. All unique reflections should be included.

2.15. Standard uncertainties

The standard uncertainty (abbreviated s.u. and replacing the traditional term estimated standard deviation) should be expressed as a number in parentheses following the numerical result and should be on the scale of the least significant digits of the result. The s.u. value should be in the range 2–19. Note that s.u. values should not be appended to parameters which are fixed by symmetry, geometry or other constraints.

3. Data requirements

A list of all data required for submission is available from the online CIF help page (see §7[link]). If the submitted data are incomplete, inadequate or incorrect the author will be informed promptly. Authors are required to pre-check each CIF (see §1.1[link]) prior to submission. A more complete description of the data-validation checks applied to submitted CIFs is available from the online CIF help page (see §7[link]).

The most important data requirements are summarized below.

_chemical_formula_moiety

_chemical_formula_sum

The chemical formula must be consistent with the atomic content specified by the _atom_site_ information, and match the _chemical_formula_weight.

_symmetry_space_group_name_H-M

The space group must encompass the highest symmetry permitted by the diffraction intensities and be consistent with the _cell_length_ and _cell_angle_ values.

_cell_formula_units_Z

The number of formula units in the unit cell must comply with that expected from the chemical formula, the space group and the _atom_site_ data.

_exptl_crystal_colour

The crystal colour should comply with the codes listed in the online CIF help page (see §7[link]).

_exptl_crystal_size_max

Authors are encouraged to use crystals no larger than 0.5 mm in their X-ray diffraction experiments. For best results, the data crystal should be uniformly bathed in the X-ray beam. The size of the beam at the crystal is normally determined by inter alia the fine-focus X-ray tube and the monochromator. While use of a small collimator can reduce the size of the incident X-ray beam, use of a large collimator does not automatically increase the incident beam size.

_exptl_absorpt_correction_type

Permitted absorption-type codes are listed in the online CIF help page (see §7[link]). A type code must be accompanied by a reference to the method or the software used; this should be given in the field _exptl_absorpt_process_details. The need for absorption corrections, and the appropriate type of correction, is dependent on the μ value _exptl_absorpt_coefficient_mu and the crystal size values _exptl_crystal_size_min, _mid and _max. If x is the medial size _mid, the product μx provides an indication of the type of correction needed. Analytical or numerical corrections are strongly recommended if μx exceeds 1.0 and mandatory if μx is above 3.0. If μx is below 0.1 corrections are usually unnecessary, otherwise ψ-scan or empirical methods are acceptable. Refined absorption methods are discouraged except in special circumstances. The transmission-factor limits _exptl_absorpt_correction_T_min and _max should agree with those expected for the crystal shape and size, and μ.

_diffrn_reflns_av_R_equivalent

_diffrn_reflns_number

_diffrn_reflns_av_R_equivalent

_diffrn_reflns_limit_h_min

_diffrn_reflns_limit_h_max

_diffrn_reflns_limit_k_min

_diffrn_reflns_limit_k_max

_diffrn_reflns_limit_l_min

_diffrn_reflns_limit_l_max

These items should refer to the complete set of measured data before any merging of symmetry-equivalent reflections, and not only to the unique set of data.

_reflns_number_total

The number of symmetry-independent reflections excludes the systematically extinct intensities. Authors are encouraged to use all symmetry-independent reflections in the refinement of the structure parameters.

_reflns_threshold_expression

This threshold, which is based on multiples of σI, σF2 or σF, serves to identify the significantly intense reflections, the number of which is given by _reflns_number_gt. These reflections are used in the calculation of _refine_ls_R_factor_gt. The multiplier in the threshold expression should be as small as possible, typically 2 or less.

_diffrn_reflns_theta_max

The θmax of measured reflections should be such that sin θmax/λ exceeds 0.6 Å−1 (i.e. θmax > 25° for Mo Kα; θmax > 67° for Cu Kα). It is assumed that all unique reflections out to at least the specified θ limits are measured. This provides the minimum number of reflections recommended for an average structural study. If intensities are consistently weak at the recommended θmax, low-temperature measurements may be needed unless a study at a specific temperature (or pressure) is being reported.

_diffrn_measured_fraction_theta_max

This is intended for area-detector data, but is also useful as a general measure of data completeness. It is the fraction of unique (symmetry-independent) reflections measured out to _diffrn_reflns_theta_max. Ideally, this should be as close to 1.0 as possible.

_diffrn_reflns_theta_full

This is intended for area-detector data. θfull is the diffrac­tometer angle at which the measured reflection count is close to complete. The fraction of unique reflections measured out to this angle is given by _diffrn_measured_fraction_theta_full. Alternatively, a breakdown of data completeness and merging statistics as a function of θ may be requested if deemed necessary.

_diffrn_reflns_av_R_equivalents

Sufficient symmetry-equivalent reflections must be measured to provide a good estimate of the intensity repeatability. This is particularly important when absorption corrections are applied (this value is calculated after the corrections are applied to the intensities).

_refine_ls_R_factor_gt

Note that this value is not intended as a reliable gauge of structure precision which is better determined from the standard uncertainties of the parameters (these depend on the number and reliability of the measured structure factors used in the refinement process).

_refine_ls_number_reflns

The number of reflections used in the refinement should be as large as possible, and should, if possible, be greater than the number of refined parameters _refine_ls_number_parameters by at least a factor of 10 if the structure is centrosymmetric, or by a factor of 8 if it is not.

_refine_ls_number_parameters

This is the number of coordinate, atomic displacement, scale, occupancy, constraint, restraint, extinction and other par­ameters refined independently in the least-squares process. It is possible, and sometimes desirable, to reduce this number by the appropriate application of geometric constraints.

_refine_ls_number_restraints

This gives the number of applied restraints. Concise details of what these restraints were should be included in the _refine_special_details section of the CIF.

_refine_ls_hydrogen_treatment

The codes which identify the treatment of H-atom par­ameters are listed in the online CIF help page (see §7[link]). Detailed text about the treatment of H-atom sites should be placed in _publ_section_exptl_refinement. Authors should note the advice on H-atom treatment given in the SHELXL97 manual, §4.6: `For most purposes it is preferable to calculate the hydrogen positions according to well-established geometrical criteria and then adopt a refinement procedure which ensures that a sensible geometry is retained'. Authors should note that H-atom sites which have been fixed or constrained by geometry will not have s.u. values associated with them.

_refine_ls_weighting_scheme

Weighting schemes for refinements should be based on the standard uncertainties in the measured reflection data.

_refine_ls_shift/su_max

This is the largest ratio of the refinement shift to standard uncertainty after the final round of refinement and is typically within ±0.01 if sufficient least-squares refinement cycles have been employed. A value above ±0.05 is considered unusual and values beyond ±0.1 are a sign of incomplete refinement, unaccounted-for disorder or high correlation between parameters that should be constrained. Authors should explain the reasons for a high value in _publ_section_exptl_refinement.

_refine_diff_density_min

_refine_diff_density_max

These values are expected to be small, especially for light-atom structures. If their magnitudes exceed 1 e Å−3, the label and the distance of the closest atom site should be reported in _publ_section_exptl_refinement.

_geom_

All geometry values must originate from the submitted _atom_site_fract_ values. Only geometry values of significance to the structure will be printed. These must be identified with a _geom_..._flag value of yes in the submitted CIF. Note that dimensions involving H-atom sites which have been fixed or constrained by geometry will not have s.u. values associated with them. Details of all bond lengths and angles involving H atoms must be included in the CIF, even if they have been constrained.

_atom_site_

Atomic coordinates for molecular and nonmolecular species should be supplied as connected sets. Whenever structure geometry permits, it is normally expected that the set of connected coordinates which specify the asymmetric unit will lie within the basic unit cell. Values of _atom_site_occupancy should be 1.0 except for disordered or non-stoichiometric atom sites. Atom sites constrained to model disorder must be indicated by _atom_site_disorder_group. The overall packing in the structure will be checked for significant vacant regions (i.e. voids) indicating omitted solvent molecules. Note that s.u. values should not be appended to parameters which are fixed by symmetry, geometry or other constraints. In systems with hydrogen-bonded networks, it is expected that the asymmetric unit will be chosen so that the minimum number of symmetry operators is required to specify the hydrogen-bond network.

_atom_site_aniso_U_

Checks will be made for non-positive-definite anisotropic atomic displacement parameters. The ratio of maximum to minimum eigen­values should not, except in special circumstances (e.g. disorder), exceed 5.

_refine_ls_abs_structure_details

This item should describe the method applied, and the number of Friedel-related reflections used, in the measurement of the absolute structure parameter (e.g. _refine_ls_abs_structure_Flack or _refine_ls_abs_structure_Rogers). If the structure is non-centrosymmetric, and atoms heavier than Si are present, an absolute structure parameter is expected. The reliability of this parameter increases with the number of Friedel-related intensities, and use of a complete set of Friedel pairs in the refinement is strongly recommended. With Mo radiation, if no atoms heavier than Si are present, the f′′ terms in the scattering factor expression are very small. In such cases, if no useful absolute structure parameter can be refined (i.e. the value of the absolute structure parameter is meaningless because of its large s.u. value), authors should merge Friedel-pair reflections before final refinement. They should then report in the _publ_section_exptl_refinement section of the CIF that they have merged Friedel pairs for the final refinement. Authors are strongly advised to consult papers by Flack & Bernardinelli [Acta Cryst. (1999), A55, 908–915 ; J. Appl. Cryst. (2000), 33, 1143–1148 ] which discuss the use and meaning of the Flack parameter and its s.u. value. For pertinent comments on the determination of absolute structure, authors are also referred to the paper by Jones [Acta Cryst. (1986), A42, 57 ].

4. Diagram requirements

Figures and chemical structure diagrams (see §2.10[link] for a typical example) should be prepared in HPGL, PostScript, encapsulated PostScript or TIFF format. The resolution of bitmap graphics should be a minimum of 600 d.p.i.

4.1. Publication

For papers reporting molecular structures a labelled displacement ellipsoid molecular diagram is required; for other structures, a packing or polyhedron diagram is required. All non-H unique atom sites should be identified with labels consistent with those for the supplied atomic coordinates. Distances and angles should not be shown in the crystallographic diagram. A chemical structural diagram or scheme must be supplied for molecular compounds (see §2.10[link] for a typical example). Authors should consider having the orientation of crystallographic figures and chemical schemes correspond as closely as possible.

Figures showing no significant features and not described in the text (e.g. packing diagrams without special intermolecular interactions) will not be published.

4.2. Submission

Diagrams should be submitted electronically via the web submission interface (see §1.12[link]).

4.3. Quality

Electronic files in the formats listed above are essential for high quality reproduction. For molecular compounds, a clear, well-presented ellipsoid plot will show the stereochemistry and any unusual atomic displacements or disorder.

4.4. Size

Diagrams will normally be sized by the Editorial Office staff so that the greatest width including lettering is less than the width of a column in the journal (8.8 cm).

4.5. Lettering and symbols

Fine-scale details and lettering must be large enough to be clearly legible (ideally 1.5–3 mm in height) after the whole diagram has been reduced to one column width. Atom site labels in crystallographic diagrams should not contain parentheses and should match labels used in the atom site lists and text. The labels should not overlap or touch ellipsoids or bonds. Descriptive matter should be placed in the caption. Packing diagrams must show the cell-axis directions (labelled a, b, c) and the cell origin (labelled O), but should normally exclude H-atom sites, unless these are involved in hydrogen bonding.

4.6. Numbering and figure captions

Diagrams should be numbered in a single series in the order in which they are referred to in the text. A list of the figure captions should be included in _publ_section_figure_captions. Captions of labelled displacement ellipsoid plots must state the probability limit used. If H atoms are shown by small spheres of an arbitrary size, this need not be stated in the caption. Symmetry-related atoms should be marked by additional symbols or letters (see §5.1[link]) and the figure caption should indicate to what symmetry operations these additional items in the atom labels refer.

5. Nomenclature

5.1. Crystallographic nomenclature

Authors should follow the general recommendations produced by the IUCr Commision on Crystallographic Nomenclature (see reports at https://www.iucr.org/iucr-top/comm/cnom/).

Atom sites not related by space-group symmetry should be identified by unique labels composed of a number appended to the IUPAC chemical symbol (e.g. C5, C7 etc.). Label numbers should not be placed in parentheses. Chemical and crystallographic numbering should be in agreement wherever possible. Crystallographically equivalent atoms in different asymmetric units should be identified in diagrams and text with lower-case Roman numeral superscripts appended to the original atom labels and the symmetry operators defined [e.g. C5i; symmetry code: (i) 1−x, −y, 1−z]. Superfluous characters should not be used in atom labels, e.g. C01, C02 should appear as C1, C2 etc., and H1A, H2A should appear as H1, H2 etc., unless this leads to naming ambiguities. If there are figures with packing plots in a paper the atom labels in these plots must correspond exactly with the asymmetric unit coordinates.

Space groups should be designated by the Hermann–Mauguin symbols. Standard cell settings, as listed in Volume A of International Tables for Crystallography , should be used unless objective reasons to the contrary are stated. A list of equivalent positions should also be supplied. Hermann–Mauguin symbols should be used for designating point groups and molecular symmetry. If there is a choice of origin, this should be stated in _publ_section_exptl_refinement. The choice of axes should normally follow the recommendations of the Commission on Crystallographic Data [Kennard et al. (1967). Acta Cryst. 22, 445–449 ].

5.2. Nomenclature of chemical compounds

Names of chemical compounds and minerals should conform to the nomenclature rules of the International Union of Pure and Applied Chemistry (IUPAC) , the International Union of Biochemistry and Molecular Biology (IUBMB) , the International Mineralogical Association and other appropriate bodies. Any accepted trivial or non-systematic name may be retained, but the corresponding systematic (IUPAC) name should also be given.

For crystal structures containing chiral molecules, authors should make it clear whether the crystal structure is a racemate or enantiopure, and if enantiopure whether or not the assignment of the absolute configuration is justified. Absolute configuration should be indicated using the CIF data item _chemical_absolute_configuration . The title, compound name, chemical diagrams, atomic coordinates and space group must correspond to the enantio-composition and the selected configuration. It is also most helpful to indicate the crystallographic and non-crystallographic symmetry of each molecule in the asymmetric unit.

Authors may find nomenclature programs such as Autonom (https://www.beilstein.com/products/autonom ) and ACD (https://www.acdlabs.com/products/name_lab ) to be useful resources when naming compounds.

5.3. Units

The International System of Units (SI) is used except that the ångström (symbol Å, defined as 10–10 m) is generally preferred to the nanometre (nm) or picometre (pm) as the appropriate unit of length. Recommended prefixes of decimal multiples should be used rather than `×10n'.

6. References

References to published work must be indicated by giving the authors' names followed immediately by the year of publication, e.g. Neder & Schulz (1999) or (Neder & Schulz, 1999). Where there are three or more authors the reference in the text should be indicated in the form Smith et al. (1989) or (Smith et al., 1989) etc. (all authors should be included in the full list).

In the reference list, entries for journals [abbreviated in the style of Chemical Abstracts (the abbreviations Acta Cryst., J. Appl. Cryst. and J. Synchrotron Rad. are exceptions)], books, multi-author books, computer programs, personal communications and undated documents should be arranged alphabetically (note the order below for four references with the same first author) and conform with the following style:

Becker, T. M. & Krause Bauer, J. A. (1999). Acta Cryst. C55, IUC9900141.

Bond, A. D. (2003). Acta Cryst. E59, o1992–o1993.

Bond, A. D., Clayden, J. & Wheatley, A. E. H. (2001). Acta Cryst. E57, o292–o294.

Bond, A. D. & Davies, J. E. (2002). Acta Cryst. E58, o5–o7.

Bond, A. D., Davies, J. E. & Kirby, A. J. (2001). Acta Cryst. E57, o1242–o1244.

Hervieu, M. & Raveau, B. (1983a). Chem. Scr. 22, 117–122.

Hervieu, M. & Raveau, B. (1983b). Chem. Scr. 22, 123–128.

Hummel, W., Hauser, J. & Bürgi, H.-B. (2006). In preparation.

International Union of Crystallography (2008). (IUCr) Structure Reports Online, //journals.iucr.org/e/journalhomepage.html

Jones, P. T. (1987). Personal communication.

Kiser, P. D., Lodowski, D. T. & Palczewski, K. (2007). Acta Cryst. F63, doi:10.1107/S1744309107020295.

McCrone, W. C. (1965). Physics and Chemistry of the Organic Solid State, Vol. 2, edited by D. Fox, M. M. Labes & A. Weissberger, pp. 725–767. New York: Interscience.

Perkins, P. (2007). PhD thesis, University of London, England.

Robinson, P. D. (2008). Acta Cryst. C64. In the press. [Paper reference fg1895.]

Sheldrick, G. M. (1997). SHELXL97. University of Göttingen, Germany.

Smith, J. (2000). Private communication (refcode: PYMTLI01). CCDC, Cambridge, England.

Smith, J. V. (1988). Chem. Rev. 88, 149–182.

Smith, J. V. & Bennett, J. M. (1981). Am. Mineral. 66, 777–788.

Vogel, A. (1978). Textbook of Practical Organic Chemistry, 4th ed. London: Longman.

Note that inclusive page numbers must be given, except when the cited article has only one page, and that all computer programs given in the relevant _computing_..._ entries must be referenced and included in the reference list.

7. Crystallography Journals Online

All IUCr journals are available on the web via Crystallography Journals Online at //journals.iucr.org/. Full details of guidelines for the preparation and editing of a CIF, the data items required therein, standard data codes and keywords, CIF templates, example CIFs, and data-validation criteria and procedures can be found via the online CIF help page at //journals.iucr.org/c/services/cifinfo.html .

7.1. Electronic status information

Authors may obtain information about the current status of their paper at //journals.iucr.org/services/status.html .

7.2. Proofs

Proofs will be provided electronically in portable document format (pdf). The correspondence author will be notified by e-mail when the proofs are ready for downloading. Proofs will be checked at the same time by the Section Editor, who reserves the right to make minor changes for consistency and conformity to Section C standards; any remaining problems will be referred back to the authors.

7.3. Open access

At the proof stage, authors will be given the opportunity to make their papers `open access' on Crystallography Journals Online .

7.4. Reprints

After publication, the correspondence author will be able to download the electronic reprint of the published article, free of charge. Authors will also be able to order printed reprints at the proof stage.

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