Hermann–Mauguin notation
The Hermann–Mauguin notation, also known as international notation, is a symbolic system in crystallography for concisely describing the symmetry elements of point groups, space groups, and plane groups, using numbers to denote rotation axes, the letter "m" for mirror planes, and additional symbols for screw axes, glide planes, and lattice types.[1][2] It represents the 32 crystallographic point groups and 230 space groups by specifying principal symmetry operations along unique crystal axes, such as 2 for a twofold rotation, 4/m for a fourfold axis perpendicular to a mirror plane, or P2₁/c for a primitive lattice with a twofold screw axis and a c-glide plane in monoclinic symmetry.[2] This notation enables precise classification of crystal structures, prediction of symmetry relations, and analysis of atomic arrangements, as standardized in the International Tables for Crystallography.[3][2] Developed by German crystallographer Carl Hermann in 1928 as a method to relate symmetry elements to crystal forms, the system was refined and popularized by French mineralogist Charles-Victor Mauguin in 1931, building on earlier work by Evgraf Fedorov and Paul Niggli.[1][2] First formally adopted in the 1935 edition of the International Tables for the Determination of Crystal Structures, it underwent minor modifications in 1952 and has since become the preferred alternative to Schoenflies notation due to its explicit depiction of translational symmetries like screw axes (e.g., 2₁) and glide planes (e.g., a, b, c, n, d).[3][2] The notation's structure typically begins with a lattice symbol (P for primitive, I for body-centered, F for face-centered, etc.), followed by symmetry directions ordered by axis (e.g., along a, b, c), making it essential for tasks such as determining Wyckoff positions and subgroup relations in crystal structure analysis.[2] Widely applied across mineralogy, materials science, and solid-state physics, Hermann–Mauguin notation facilitates the documentation of diverse structures, from simple cubic NaCl (Fm3m) to complex quartz (P3₂2₁), and supports computational tools for symmetry prediction and refinement.[1][2] Its enduring relevance is evident in ongoing updates to the International Tables, with the 2004 edition providing comprehensive listings of space-group subgroups and diagrams.[2][3]Fundamentals
Definition and Purpose
The Hermann–Mauguin notation is a symbolic system in crystallography designed to concisely represent the symmetry operations and elements of crystals, such as rotation axes, mirror planes, and inversion centers. It uses integers (1, 2, 3, 4, or 6) to indicate the order of proper rotation axes, letters like "m" for mirror planes and "a", "b", "c", or "n" for glide planes, and overlines (e.g., \bar{1}) to denote rotoinversions or inversion centers, allowing for a compact description of symmetry arrangements without lengthy verbal explanations.[4][5] The notation's core purpose is to standardize the classification and communication of crystal symmetries, enabling the systematic identification of the 32 crystallographic point groups, 17 plane groups, and 230 space groups that govern periodic structures. By replacing detailed textual or diagrammatic descriptions with brief symbols, it streamlines analysis in fields like X-ray crystallography, where precise symmetry knowledge is vital for determining atomic arrangements and material properties.[6][4] Applicable to both two-dimensional plane groups and three-dimensional space groups, the Hermann–Mauguin notation is fundamental for studying the symmetries of crystalline materials in physics and materials science. A simple example is "4/m", which denotes a fourfold rotation axis perpendicular to a mirror plane, combining rotational and reflectional elements to describe tetragonal symmetry.[5][4]Historical Development
The Hermann–Mauguin notation emerged in the early 20th century as a standardized system for describing crystallographic symmetry, primarily developed by German physicist Carl Hermann and French mineralogist Charles-Victor Mauguin. Hermann introduced the foundational symbols in 1928, emphasizing their application to the systematization of the 230 space groups derived from earlier enumerations. Mauguin refined and expanded this framework in a 1931 publication in Zeitschrift für Kristallographie, where he proposed symbols for repetition groups and symmetry assemblies, laying precursors to the full notation. Their collaborative efforts addressed the need for a concise, internationally accessible alternative to existing systems, prioritizing practical use in crystal structure analysis over purely mathematical abstraction.[3][7] This notation built upon the late 19th-century work of mathematician Arthur Schönflies, who in the 1880s and 1890s developed an algebraic symbolism for point groups that influenced crystallographic theory but was less suited for routine international communication. Unlike Schönflies' approach, which used Greek letters and focused on group-theoretic purity, Hermann and Mauguin's system favored brevity and direct reference to symmetry elements like rotation axes and mirror planes, facilitating global adoption among crystallographers. The notation's design reflected the era's push for standardization following the discovery of X-ray diffraction, enabling clearer documentation of crystal symmetries in scientific literature.[8] A key milestone occurred with the first full adoption of the Hermann–Mauguin notation in the 1935 edition of the International Tables for the Determination of Crystal Structures, where it became the official "international" symbolism for point, plane, and space groups, replacing varied national conventions. This edition marked the notation's integration into core crystallographic practice, with minor modifications introduced in the 1952 revision to enhance clarity. Hermann's contributions particularly advanced the organization of space group tables, providing a structured basis for the 230 groups that remains foundational.[3][9] Over subsequent decades, the notation evolved through updates in later editions of the International Tables, adapting to new scientific demands while preserving its core structure. The 1983 edition of Volume A refined symbols for broader applicability, while the 2004 Volume A1 and 2016 sixth edition of Volume A incorporated enhancements for computational crystallography, such as compatibility with software for symmetry analysis. Extensions addressed limitations in early versions, including incomplete coverage of magnetic space groups—now systematically denoted in dedicated tables. These developments ensured the notation's enduring relevance in modern materials science and structural biology.[10][11][12]Notation Basics
Principal Axis and Symmetry Elements
In Hermann–Mauguin notation for point groups, the principal axis is defined as the highest-order proper rotation axis present, which takes precedence in the symbol's construction. This axis is denoted by the integer n, where n equals 3, 4, or 6 corresponding to threefold, fourfold, or sixfold rotational symmetry, respectively; in cases lacking such an axis, the notation begins with 2 for a twofold rotation or 1 for no rotational symmetry beyond the identity. The principal axis is conventionally aligned with a characteristic direction of the crystal system, such as the c-axis in hexagonal or tetragonal systems, ensuring a standardized representation of the group's symmetry operations.[13][5][14] Symmetry elements are integrated into the notation following the principal axis symbol, with their placement and separators indicating spatial relationships. Lower-order rotation axes, typically twofold (denoted by 2), are listed if perpendicular to the principal axis; mirror planes are represented by m, with a slash (/) denoting a mirror perpendicular to the preceding axis (e.g., n/m), while mirrors parallel or at angles are positioned without slashes. Inversion symmetry is incorporated via a bar over the relevant symbol, such as \bar{1} for a pure inversion center or \bar{n} for a rotoinversion axis combining rotation and inversion. These elements are ordered hierarchically: the principal axis first, followed by those perpendicular to it, and then any at intermediate angles, limiting the symbol to at most three positions for clarity.[15][16][14] The full point group symbol is constructed by combining these elements into a concise sequence, such as nmm for a principal n-fold axis with mirror planes perpendicular and parallel to secondary twofold axes, or 2/m2/m2/m for orthogonal symmetries in lower systems. Positions in the symbol specify orientations: the first after the principal indicates elements perpendicular to it, the second those at right angles to the first perpendicular set, and the third (if present) at intermediate angles. A fundamental concept underlying this construction is the composition of symmetry operations; for example, an n-fold rotation combined with a mirror plane perpendicular to that axis yields an n-fold rotoinversion, denoted \bar{n}, which reflects the equivalent effect of the sequence in generating the group's transformations.[13][5][16] A representative example is the cubic point group m\bar{3}m, where the principal axis is a threefold rotoinversion (\bar{3}) along the body diagonals of the cube, integrated with mirror planes (m) perpendicular to the fourfold rotation axes along the edges and additional mirrors parallel to the faces. This notation captures the high symmetry of the group, including six 4-fold axes, eight 3-fold axes, and nine mirror planes, without redundancy.[13][5][16]Symbol Conventions for Rotations and Mirrors
The Hermann–Mauguin notation employs standardized symbols to represent rotation axes and mirror planes, ensuring precise and unambiguous description of crystal symmetries across international crystallographic practice.[3] Rotation axes are denoted by integers corresponding to the order of rotational symmetry: 1 for the identity operation (a 360° or 0° rotation, often omitted in symbols), 2 for a 180° rotation, 3 for 120°, 4 for 90°, and 6 for 60° rotations along the axis.[17] These orders are restricted by the crystallographic restriction theorem, which limits possible rotational symmetries in periodic lattices to 1, 2, 3, 4, or 6-fold.[3] Rotoinversion operations, combining rotation with inversion through a point on the axis, are symbolized by placing a bar over the integer, denoted as \bar{n}, where n is the rotation order.[17] For instance, \bar{[1](/page/1)} represents pure inversion (180° rotoinversion), \bar{[3](/page/3)} a 120° rotation followed by inversion, and \bar{[2](/page/2)} equivalent to reflection across a plane perpendicular to the axis.[3] These symbols distinguish rotoinversions from pure rotations, facilitating clear notation for centrosymmetric elements.[17] Mirror planes, or reflections, are indicated by the letter m, with positioning in the symbol reflecting orientation relative to the principal axis or other elements.[18] A mirror perpendicular to the principal rotation axis follows a slash (/), as in the monoclinic symbol 2/m, where the 2-fold axis is normal to the mirror plane.[5] Mirrors parallel to the principal axis are placed before secondary rotation symbols, such as in nm constructs (e.g., 4mm, denoting a 4-fold axis with mirrors containing the axis and additional mirrors perpendicular to secondary 2-fold axes).[5] This hierarchical arrangement—principal axis first, followed by separated sets for perpendicular or parallel elements—avoids ambiguity in describing combined symmetries.[3] In trigonal and hexagonal groups, the relative orientation of mirror planes to secondary axes is indicated by the order of symbols in the notation, such as 3m and 31m, distinguishing mirrors aligned with or between the secondary twofold axes. For hexagonal symmetries involving 6-fold axes, a horizontal mirror plane perpendicular to the principal axis is denoted by m, as in 6/m.[5] These conventions, formalized in the International Tables for Crystallography, promote consistency in global usage by prioritizing the principal axis and using separators to clarify spatial relationships.[3] Updates to the notation in the digital era include enhanced support for rendering in computational tools, with Unicode encoding for overbars (\bar{n}) and slashes (/) introduced in mathematical symbol blocks around 2001 (Unicode 3.1), enabling accurate display in software for crystallography simulations.[19] A representative example is the 2/m symbol for the monoclinic point group, combining a 2-fold rotation axis parallel to the b-direction with a mirror plane perpendicular to it, encapsulating the essential symmetry without extraneous elements.[5]Point Groups
Groups Lacking Higher-Order Axes
The point groups lacking higher-order axes encompass the triclinic, monoclinic, and orthorhombic crystal systems, which are characterized solely by symmetry operations of order 1, 2, or mirror reflections, without any rotation axes of order 3 or greater. These groups represent the lowest levels of symmetry in crystallographic point groups, totaling eight out of the 32 possible groups, and are essential for understanding structures where minimal symmetry constraints allow for diverse molecular arrangements. In Hermann–Mauguin notation, these groups employ simple symbols that directly indicate the presence of a 2-fold axis (denoted by 2), a mirror plane (m), or an inversion center (\bar{1}), with no need for multiple descriptors due to the absence of intersecting higher symmetries.[20] Triclinic point groups include the two simplest cases: 1 and \bar{1}. The group 1 possesses no symmetry elements beyond the identity operation, meaning the crystal lacks any rotational or reflectional symmetry, resulting in a general form known as a pedion—a single, unrepeated face. This notation simply uses the numeral 1 to signify the trivial symmetry. Crystals in this group, such as certain boric acid polymorphs, exhibit triclinic unit cells with all angles and edge lengths unequal. In contrast, the \bar{1} group features only a center of inversion, which maps each point (x, y, z) to (-x, -y, -z), denoted by the barred 1 in Hermann–Mauguin notation; no rotation axes or mirrors are present, and the general crystal form is a pinacoid, consisting of two parallel faces. Examples include minerals like low albite or synthetic organic compounds, where the inversion center enforces pairwise equivalence of atomic positions without additional constraints. These triclinic groups are prevalent in biological molecules due to their flexibility in accommodating irregular structures, such as certain amino acid crystals.[5][20][21] Monoclinic point groups—2, m, and 2/m—introduce a single unique symmetry direction, conventionally aligned with the b-axis, which distinguishes them from triclinic cases by enforcing one plane of symmetry or a 2-fold rotation. The group 2 is defined by a single 2-fold rotation axis parallel to b, performing a 180° rotation that interchanges opposite faces, with the notation simply "2" indicating this axis; the general form is a sphenoid or dome with four faces. Crystals like sucrose, an organic disaccharide, adopt this symmetry in the monoclinic space group P2₁, reflecting its low-symmetry packing influenced by molecular chirality. The m group features a single mirror plane perpendicular to the b-axis, denoted by "m," which reflects points across the plane (ac plane in standard setting); the general form is also a dome. Finally, the 2/m group combines a 2-fold axis along b with a mirror plane perpendicular to it, notated as "2/m" to specify the mirror's orientation relative to the axis; this centrosymmetric group has eight general positions and produces prismatic forms with parallel faces. Common in minerals like orthoclase feldspar, it represents the highest symmetry among these low-order groups. These monoclinic symmetries account for three of the 32 point groups and are particularly common in organic and biological crystals, where the single axis or plane accommodates asymmetric molecular shapes without imposing higher constraints.[5][20][22][21] In the orthorhombic system, the principal axis is effectively a twofold rotation or mirror, but the groups 222, mm2, and mmm incorporate three mutually perpendicular twofold axes or mirror planes, yielding distinct morphologies. The 222 notation denotes three perpendicular twofold axes, resulting in a rhombic disphenoid form. The mm2 notation denotes a single twofold axis parallel to the c-direction, intersected by two mirror planes perpendicular to the a- and b-axes, resulting in a pyramidal form with hemimorphic character—meaning the crystal exhibits different terminations at opposite ends due to the absence of an inversion center. In contrast, mmm (fully 2/m 2/m 2/m) includes three perpendicular twofold axes, each normal to a mirror plane, plus an inversion center, achieving holohedral symmetry with dipyramidal habits. This full orthorhombic symmetry allows for balanced development along all three axes, as seen in minerals like topaz.[5][1]Groups with a Single Higher-Order Axis
Point groups featuring a single higher-order rotation axis of order 3, 4, or 6, along with subordinate twofold rotations or mirror planes, characterize the tetragonal and trigonal crystal systems in Hermann–Mauguin notation.[5] These groups build upon lower-symmetry configurations by introducing a principal axis that dictates the overall form, while perpendicular or diagonal subordinate elements refine the symmetry without introducing equivalent higher-order axes.[1] The notation prioritizes the principal axis in the first position, followed by symbols for subordinate symmetries along secondary directions, ensuring a unique descriptor for each group's operations.[5] Tetragonal point groups center on a principal fourfold axis aligned with the c-direction, with subordinate elements along the a- and b-axes or diagonals. The basic 4 symbol indicates a pure fourfold rotation, producing pyramidal crystals with square bases.[5] The \bar{4} variant replaces this with a fourfold rotoinversion axis, leading to disphenoidal forms lacking mirror symmetry.[5] Adding a perpendicular mirror plane yields 4/m, a dipyramidal group with inversion.[5] More complex groups like 422 incorporate the fourfold axis plus four perpendicular twofold axes, forming trapezohedral crystals; 4mm features four vertical mirror planes for ditetragonal-pyramidal habits; and \bar{4}2m combines a fourfold rotoinversion with twofold axes and diagonal mirrors.[5] The highest symmetry, 4/mmm (or 4/m 2/m 2/m), includes the fourfold axis, multiple mirrors, and inversion, representing holohedral tetragonal symmetry with ditetragonal-dipyramidal forms.[5] In contrast, groups like 422 exhibit hemihedry, displaying only half the possible faces compared to the holohedral 4/mmm due to the absence of certain mirrors and inversion.[1] Zircon exemplifies 4/mmm, with its prismatic crystals terminated by pyramids reflecting the full tetragonal holosymmetry.[23] Trigonal groups emphasize a principal threefold axis along the c-direction, often with subordinate twofold axes or mirrors at 120° intervals, using a slash (/) to denote diagonal orientations. The 3 symbol signifies a lone threefold rotation, yielding trigonal-pyramidal crystals that are hemimorphic.[5] The \bar{3} notation introduces a threefold rotoinversion, forming rhombohedral habits without mirrors.[5] The 32 group adds three perpendicular twofold axes to the threefold rotation, producing trapezohedral forms, as in quartz, where the combination generates sixfold apparent symmetry in cross-section despite the single higher-order axis.[5][24] In 3m, three mirror planes intersect the threefold axis vertically, resulting in ditrigonal-pyramidal crystals; the / indicates mirrors parallel to the axis.[5] The \bar{3}m (or \bar{3}2/m) achieves holohedral trigonal symmetry with rotoinversion, threefold axis, mirrors, and inversion, forming scalenohedral or rhombohedral shapes.[5][1] These notations distinguish diagonal from perpendicular subordinate elements, essential for trigonal forms where axes are not orthogonal.[5]Groups with Multiple Higher-Order Axes
Groups with multiple higher-order axes represent the highest symmetry point groups in three-dimensional crystallography, specifically the hexagonal and cubic systems, where equivalent axes of order greater than two intersect to produce isotropic properties essential for materials like metals and ionic crystals. These groups feature several parallel or intersecting rotation axes of high order, such as sixfold in hexagonal and fourfold or threefold in cubic, combined with mirror planes or inversions, leading to enhanced rotational freedom and uniform directional responses. Unlike groups with a single principal axis, these exhibit multiple equivalent higher-order axes that contribute to near-spherical symmetry distributions, making them prevalent in close-packed structures.[4] In the hexagonal system, seven point groups incorporate a principal sixfold rotation axis along with subordinate twofold and threefold axes perpendicular to it, creating a set of equivalent higher-order symmetries. The groups are denoted as 6 (pure sixfold rotation, order 6), \bar{6} (sixfold rotoinversion, order 6), 6/m (sixfold axis with perpendicular mirror, order 12), 622 (sixfold with perpendicular twofolds, order 12), 6mm (sixfold with perpendicular mirrors, order 12), \bar{6}m2 (rotoinversion with mirrors and twofolds, order 12), and 6/mmm (full symmetry with mirrors parallel and perpendicular to the axis, order 24). The notation emphasizes the principal 6 or \bar{6}, followed by symbols for subordinate elements like 2 for twofold axes or m for mirrors in the plane normal to the principal axis, and additional mm for vertical mirrors. These configurations arise from the hexagonal lattice's inherent sixfold isotropy, with the subordinate axes (six twofolds and six threefolds in 6/mmm) enhancing overall symmetry.[4][25] The cubic system includes five point groups defined by four equivalent threefold axes along the body diagonals and three sets of fourfold axes along the coordinate axes, yielding the highest orders among the 32 crystallographic point groups. These are 23 (threefold axes with twofolds, order 12), m\bar{3} (threefolds with mirrors and inversion, order 24), 432 (chiral with threefolds and fourfolds, order 24), \bar{4}3m (fourfolds with inversion and mirrors, order 24), and m\bar{3}m (full cubic with mirrors, inversion, and all axes, order 48). In the notation, the principal elements are indicated first: 23 highlights the threefolds, while m\bar{3}m specifies mirrors (m) perpendicular to the fourfolds, the inversion (\bar{3}), and additional mirrors (m). The 432 group is chiral, lacking inversion, whereas m\bar{3}m represents the complete holosymmetry of the cube, incorporating 24 threefolds (including rotoinversions) and 16 fourfolds. This multiplicity of axes ensures equivalent properties in all directions, underpinning the cubic system's prevalence in elemental metals and compounds.[4][25] These high-symmetry groups are ubiquitous in metallic and ionic materials; for instance, sodium chloride (NaCl) adopts the rock-salt structure with point group m\bar{3}m, where the cubic arrangement of ions benefits from the full set of higher-order axes and mirrors for stability. Together, the seven hexagonal and five cubic groups account for 12 of the 32 point groups, representing the pinnacle of crystallographic symmetry. In nanomaterials, pseudosymmetry often mimics these high-symmetry forms due to factors like lattice parameter variations or atomic displacements, leading to apparent cubic or hexagonal patterns in lower-symmetry structures such as perovskites or Co-based alloys, which can complicate phase identification in electron backscatter diffraction analysis.[2][25][26]Plane Groups
Classification of 2D Symmetry Groups
The classification of 2D symmetry groups using Hermann–Mauguin notation distinguishes between frieze groups, which describe linear periodic symmetries along one direction, and wallpaper groups, which describe full two-dimensional periodic tilings. In this context, plane groups encompass both frieze groups (linear periodic symmetries) and wallpaper groups (full 2D periodic symmetries), though strictly plane groups refer to the latter in crystallography. Frieze groups capture the symmetries of infinite strip patterns, such as decorative borders, incorporating translations along the strip axis combined with possible rotations, reflections, or glide reflections. There are exactly seven frieze groups, enumerated systematically based on compatible combinations of these elements under the constraints of one-dimensional periodicity. The seven frieze groups and their Hermann–Mauguin notations are as follows, where 'p' denotes a primitive translation lattice, numbers indicate rotation orders (e.g., 2 for 180° rotation), 'm' signifies mirror reflections (perpendicular or parallel to the strip axis), and 'g' denotes glide reflections:| Group Number | Notation | Key Symmetry Elements |
|---|---|---|
| 1 | p1 | Translations only |
| 2 | p2 | Translations + 180° rotations |
| 3 | p1m1 | Translations + vertical mirrors |
| 4 | p11m | Translations + horizontal mirror + glide reflections |
| 5 | p11g | Translations + horizontal glides |
| 6 | p2mg | Translations + 180° rotations + vertical mirrors + glides |
| 7 | p2mm | Translations + 180° rotations + vertical and horizontal mirrors + glides |
Notation for Frieze and Wallpaper Groups
The Hermann–Mauguin notation for frieze groups describes the seven possible symmetry groups of infinite strip patterns, emphasizing translational symmetry along one direction combined with possible rotations, reflections, or glide reflections perpendicular or parallel to the strip axis. These groups are denoted using a primitive lattice symbol 'p' followed by indicators for the principal symmetry axis and additional elements, where numbers represent rotation orders (1 for identity, 2 for 180° rotation), 'm' denotes mirror lines, and 'g' indicates glide reflections. The seven frieze groups are: p1 (translations only), p11g (glide reflection parallel to the strip), p1m1 (vertical mirrors perpendicular to the strip), p11m (horizontal mirror parallel to the strip), p2 (2-fold rotations), p2mg (2-fold rotations with vertical mirrors and parallel glides), and p2mm (2-fold rotations with both horizontal and vertical mirrors).[30][18] Construction rules for frieze group symbols begin with 'p' for the primitive lattice, as centered lattices are not applicable in one dimension. The first subscript position after the rotation symbol indicates symmetries perpendicular to the translation direction (e.g., '1m1' for mirrors perpendicular), while the second indicates those parallel (e.g., '11m' for horizontal mirror). Positions like 'mg' specify a mirror perpendicular combined with a glide parallel. A zigzag pattern, such as alternating up-and-down waves along a horizontal strip, exemplifies the p11g group, where the motif repeats via translation and a glide reflection shifts it by half the period.[18][31] Wallpaper groups extend this notation to the 17 two-dimensional plane symmetry groups, incorporating translations in two non-parallel directions along with rotations up to 6-fold, mirrors, and glides. Symbols start with 'p' (primitive) or 'c' (centered rectangular or rhombic), followed by the highest-order rotation (1, 2, 3, 4, or 6), then subscripts or letters specifying mirror or glide orientations relative to principal axes: '1' for perpendicular to the principal direction, '2' for at 45° or along secondary directions, 'm' for mirror, and 'g' for glide. The full list includes: oblique (p1, p2), rectangular (pm, pg, cm, pmm, pmg, pgg, cmm), square (p4, p4mm, p4g), and hexagonal (p3, p31m, p3m1, p6, p6mm). For instance, p2 denotes primitive lattice with 2-fold rotations, pm indicates mirrors perpendicular to the principal axis, pgg features glides in two directions, and p4mm combines 4-fold rotations with mirrors.[32][18] Representative examples illustrate these symmetries in natural and artistic contexts. Islamic geometric motifs, such as star-and-polygon tilings from the Topkapı Scroll, often exhibit p4g symmetry, featuring 4-fold rotations and diagonal glides without full mirrors, creating intricate interlocking patterns. Honeycomb structures, like those in graphene lattices, display p6mm symmetry with 6-fold rotations and mirrors in three directions, forming a hexagonal tiling that maximizes packing efficiency.[33] Recent digital tools facilitate the detection and visualization of 2D symmetries, enhancing educational and research applications. For example, the GWGPM software (developed in 2023) generates wallpaper group patterns from molecular data, allowing users to identify and apply symmetries interactively for visualization purposes.[34]Space Groups
Bravais Lattice Types
The Bravais lattices provide the underlying translational symmetry for three-dimensional crystal structures and are integral to the Hermann–Mauguin notation for space groups, where they are denoted by a prefix indicating the lattice centering type. These lattices consist of identical points arranged in a repeating pattern, with the unit cell containing one or more lattice points depending on the centering. There are exactly 14 Bravais lattices, arising from the 7 crystal systems—triclinic, monoclinic, orthorhombic, tetragonal, rhombohedral (or trigonal), hexagonal, and cubic—each allowing specific centering configurations that respect the system's symmetry constraints.[35] The classification ensures that no two distinct lattices are related by a simple coordinate transformation, distinguishing them as unique geometric frameworks.[36] The centering types are primitive (P), where lattice points are only at the unit cell corners; base-centered (C, A, or B), with an additional point at the center of one face (C for the ab-face in conventional settings); body-centered (I), with a point at the cell center; face-centered (F), with points at all face centers; and rhombohedral (R), a special primitive form for the rhombohedral system using hexagonal axes.[35] In the Hermann–Mauguin notation, this prefix precedes the symmetry operation symbols; for instance, in the monoclinic space group P2₁/c, the P indicates a primitive lattice, followed by a twofold screw axis (2₁) and a c-glide plane (c).[37] The choice of prefix is system-specific: the triclinic system has only P; monoclinic has P and C; orthorhombic has P, C, I, and F; tetragonal has P and I; rhombohedral has R; hexagonal has only P; and cubic has P, I, and F.[35] The following table summarizes the 14 Bravais lattices by crystal system:| Crystal System | Bravais Lattices |
|---|---|
| Triclinic | P |
| Monoclinic | P, C |
| Orthorhombic | P, C, I, F |
| Tetragonal | P, I |
| Rhombohedral | R |
| Hexagonal | P |
| Cubic | P, I, F |
Screw Axes and Translation Components
In space groups, screw axes extend the rotational symmetries of point groups by incorporating a fractional translation along the axis of rotation, enabling nonsymmorphic operations that are essential for describing the full symmetry of crystal structures. These operations combine a rotation by $360^\circ / n around an axis with a parallel translation by a fraction p of the lattice vector along that axis, where n is the order of rotation (2, 3, 4, or 6). This translation ensures that repeated applications of the operation map the lattice onto itself only after completing the full rotation cycle.[4][40] The Hermann–Mauguin notation for a screw axis is n_p, where n denotes the rotational order and the subscript p specifies the translation fraction, typically p = 1/2, $1/3, $1/4, or $1/6 of the unit cell parameter along the principal axis (often the c-axis in conventional settings). For instance, $2_1 represents a twofold screw axis involving a $180^\circ rotation followed by a translation of half the lattice repeat distance. Possible fractions are constrained by the rotational order: for n=2, only p=1/2; for n=3, p=1/3 or $2/3; for n=4, p=1/4, $1/2, or $3/4; and for n=6, p=1/6, $1/3, $1/2, $2/3, or $5/6. These ensure the operation is primitive, meaning n applications return to the identity without fractional lattice shifts. Screw axes can align with principal crystallographic directions and may appear multiple times within a single space group, such as the $4_1 screws in the body-centered tetragonal group I4_1/amd (No. 141).[4][40][18] In constructing the full Hermann–Mauguin symbol for a space group, pure rotational elements from the point group are replaced by their screw counterparts where translations are present; the subscript p is appended directly to n without additional indicators for the axis direction, which is inferred from the symbol's sequence (e.g., first position for the unique axis). The translation is typically along the c-axis for hexagonal, trigonal, and tetragonal systems, or the b-axis in monoclinic settings, aligning with the conventional unit cell orientation. This notation prioritizes the highest-order axis and lists additional screws in descending order.[17][4] Mathematically, a screw axis operation is denoted in Seitz notation as \{n \mid \mathbf{t}\}, where the rotation matrix corresponds to $360^\circ / n about the axis, and \mathbf{t} = p \cdot \mathbf{c} is the translation vector, with \mathbf{c} the unit cell vector along the axis (e.g., height for c-axis). Applying the operation k times yields a total rotation of k \cdot 360^\circ / n and translation k \cdot p \cdot \mathbf{c}, closing after n applications to an integer lattice vector. For example: \{n \mid p \mathbf{c}\}^k = \{n^k \mid k p \mathbf{c}\} This framework distinguishes screw axes from pure rotations, as the fractional translation breaks certain translation symmetries unless compensated across the lattice.[40][4] Representative examples illustrate their role in real crystals. In α-quartz (space group P3_121, No. 152), a $3_1 screw axis along the c-direction combines $120^\circ rotation with a $1/3 c translation, contributing to the chiral helical arrangement of SiO_4 tetrahedra. Similarly, the body-centered tetragonal space group I4_1/amd features $4_1 screw axes parallel to the c-axis, as seen in structures like rutile variants, where the operation supports the staggered atomic layering. Although the diamond cubic structure (Fd\bar{3}m, No. 227) primarily relies on glide planes, related cubic groups incorporate screws to refine positional symmetries.[4][40][41] Screw axes exhibit handedness, with subscripts indicating right- or left-handed senses relative to the rotation direction; for example, $3_1 is right-handed while $3_2 is left-handed, forming enantiomorphic pairs in chiral space groups. There are 11 unique screw axis types in total (2_1, 3_1, 3_2, 4_1, 4_2, 4_3, 6_1, 6_2, 6_3, 6_4, 6_5), each distinct by order and fraction, enabling numerous space groups that include such elements.[40][4][42]Glide Planes and Mirror Operations
Glide planes represent a type of symmetry operation in space groups that combines a mirror reflection across a plane with a fractional translation parallel to that plane, distinguishing them from pure mirror planes by introducing a non-symmorphic element.[43] In Hermann–Mauguin notation, these are denoted by replacing the 'm' symbol for a mirror plane with a lowercase letter indicating the direction and magnitude of the translation component, such as a, b, c, n, or d.[37] The position of this letter in the symbol corresponds to the orientation of the plane relative to the crystal axes, ensuring the notation captures the full symmetry of the lattice.[43] The specific types of glide planes are defined by the translation vector associated with the reflection:- An a-glide involves a translation of \frac{\mathbf{a}}{2}, where \mathbf{a} is the lattice vector along the a-axis.
- A b-glide uses a translation of \frac{\mathbf{b}}{2} along the b-axis.
- A c-glide employs a translation of \frac{\mathbf{c}}{2} along the c-axis, often appearing in monoclinic or rhombohedral settings.
- An n-glide features a diagonal translation of \frac{\mathbf{a} + \mathbf{b}}{2} (or equivalent in other planes), combining components along two axes.
- A d-glide, less common, occurs in face-centered lattices with translations of \frac{\mathbf{a} + \mathbf{b}}{4} or similar quarter-unit shifts, typically in orthorhombic or higher systems.[37][43]