Zone axis

Last updated September 27, 2023

Zone axis, a term sometimes used to refer to "high-symmetry" orientations in a crystal, most generally refers to any direction referenced to the direct lattice (as distinct from the reciprocal lattice) of a crystal in three dimensions. It is therefore indexed with direct lattice indices, instead of with Miller indices.

Zone-axis indexing

The translational invariance of a crystal lattice is described by a set of unit cell, direct lattice basis vectors (contravariant ^[1] or polar) called a, b, and c, or equivalently by the lattice parameters, i.e. the magnitudes of the vectors, called a, b and c, and the angles between them, called α (between b and c), β (between c and a), and γ (between a and b).^[2]^[3] Direct lattice vectors have components measured in distance units, like meters (m) or angstroms (Å).

A lattice vector is indexed by its coordinates in the direct lattice basis system $\{{\bf {a}},{\bf {b}},{\bf {c}}\}$ and is generally placed between square brackets []. Thus a direct lattice vector ${\bf {s}}_{uvw}$ , or $[uvw]$ , is defined as $u{\bf {a}}+v{\bf {b}}+w{\bf {c}}$ . Angle brackets ⟨⟩ are used to refer to a symmetrically equivalent class of lattice vectors (i.e. the set of vectors generated by an action of the lattice's symmetry group). In the case of a cubic lattice, for instance, ⟨100⟩ represents [100], [010], [001], [100], [010] and [001] because each of these vectors is symmetrically equivalent under a 90 degree rotation along an axis. A bar over a coordinate is equivalent to a negative sign (e.g., $[{\overline {1}}00]=-{\bf {a}}$ ).

The term "zone axis" more specifically refers to the direction of a direct-space lattice vector. For example, since the [120] and [240] lattice vectors are parallel, their orientations both correspond the ⟨120⟩ zone of the crystal. Just as a set of lattice planes in direct space corresponds to a reciprocal lattice vector in the complementary space of spatial frequencies and momenta, a "zone" is defined^[4]^[5] as a set of reciprocal lattice planes in frequency space that corresponds to a lattice vector in direct space.

The reciprocal space analog to a zone axis is a "lattice plane normal" or "g-vector direction". Reciprocal lattice vectors (one-form ^[6] or axial) are Miller-indexed using coordinates in the reciprocal lattice basis $\{{\bf {a}}^{*},{\bf {b}}^{*},{\bf {c}}^{*}\}$ instead, generally between round brackets () (similar to square brackets [] for direct lattice vectors). Curly brackets {} (not to be confused with a mathematical set) are used to refer to a symmetrically equivalent class of reciprocal lattice vectors, similar to angle brackets ⟨⟩ for classes of direct lattice vectors.

Here, ${\bf {a}}^{*}\equiv (b\times c)/V_{c}$ , ${\bf {b}}^{*}\equiv (c\times a)/V_{c}$ , and ${\bf {c}}^{*}\equiv (a\times b)/V_{c}$ , where the unit cell volume is $V_{c}={\bf {a}}\cdot ({\bf {b}}\times {\bf {c}})$ ( $\cdot$ denotes a dot product and $\times$ a cross product). Thus a reciprocal lattice vector ${\bf {g}}_{hkl}$ or $(hkl)=h{\bf {a}}^{*}+k{\bf {b}}^{*}+l{\bf {c}}^{*}$ has a direction perpendicular to a crystallographic plane and a magnitude $g_{hkl}=1/d_{hkl}$ equal to the reciprocal of the spacing $d_{hkl}$ between those $(hkl)$ planes, measured in spatial frequency units, e.g. of cycles per angstrom (cycles/Å).

Bracket conventions for direct lattice and reciprocal lattice Miller indices in crystallography
Object	Equivalence Class	Specific Vector	Units	Transformation
zone or lattice-vector s_uvw	$\langle {uvw\rangle }\,$	$[uvw]\,$	direct space, e.g. [meters]	contravariant or polar
plane or g-vector g_hkl	$\{hkl\}\,$	$(hkl)\,$	reciprocal space, e.g. [cycles/m]	covariant or axial

A useful and quite general rule of crystallographic "dual vector spaces in 3D", e.g. reciprocal lattices, is that the condition for a direct lattice vector [uvw] (or zone axis) to be perpendicular to a reciprocal lattice vector (hkl) can be written with a dot product as $[uvw]\cdot (hkl)=uh+vk+wl=0$ . This is true even if, as is often the case, the basis vector set used to describe the lattice is not Cartesian.

Zone-axis patterns

By extension, a [uvw] zone-axis pattern (ZAP) is a diffraction pattern taken with an incident beam, e.g. of electrons, X-rays or neutrons traveling along a lattice direction specified by the zone-axis indices [uvw]. Because of their small wavelength λ, high energy electrons used in electron microscopes have a very large Ewald sphere radius (1/λ), so that electron diffraction generally "lights up" diffraction spots with g-vectors (hkl) that are perpendicular to [uvw].^[7]

Diamond face centered cubic silicon atom cluster viewed down the [011] zone (left), with the corresponding zone-axis pattern (right). SiLabeled.png — Diamond face centered cubic silicon atom cluster viewed down the [011] zone (left), with the corresponding zone-axis pattern (right).

One result of this, as illustrated in the figure above, is that "low-index" zones are generally perpendicular to "low-Miller index" lattice planes, which in turn have small spatial frequencies (g-values) and hence large lattice periodicities (d-spacings). A possible intuition behind this is that in electron microscopy, for electron beams to be directed down wide (i.e. easily visible) tunnels between columns of atoms in a crystal, directing the beam down a low-index (and by association high-symmetry) zone axis may help.^[8]^[9]^[10]^[11]

Footnotes

↑ George Arfken (1970) Mathematical methods for physicists (Academic Press, New York).
↑ J. M. Ziman (1972 2nd ed) Principles of the theory of solids (Cambridge U. Press, Cambridge UK).
↑ Zbigniew Dauter and Mariusz Jaskolski (2010) "How to read (and understand) Volume A of International Tables for Crystallography: an introduction for nonspecialists", J. Appl. Crystallogr.43, 1150–1171 pdf
↑ E. W. Nuffield (1966) X-ray diffraction methods (John Wiley, NY).
↑ B. E. Warren (1969) X-ray diffraction (Addison-Wesley, paperback edition by Dover Books 1990) ISBN 0-486-66317-5.
↑ cf. Charles W. Misner, Kip S. Thorne and John Archibald Wheeler (1973) Gravitation (W. H. Freeman, San Francisco CA).
↑ John M. Cowley (1975) Diffraction Physics (North-Holland, Amsterdam).
↑ J. W. Edington (1976) Practical electron microscopy in materials science (N. V. Philips' Gloeilampenfabrieken, Eindhoven) ISBN 1-878907-35-2
↑ Ludwig Reimer (1997 4th ed) Transmission electron microscopy: Physics of image formation and microanalysis (Springer, Berlin) preview.
↑ David B. Williams and C. Barry Carter (1996) Transmission electron microscopy: A textbook for materials science (Plenum Press, NY) ISBN 0-306-45324-X
↑ P. Hirsch, A. Howie, R. Nicholson, D. W. Pashley and M. J. Whelan (1965/1977) Electron microscopy of thin crystals (Butterworths/Krieger, London/Malabar FL) ISBN 0-88275-376-2

External links

International Tables for Crystallography

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[Arfken1970-1] George Arfken (1970) Mathematical methods for physicists (Academic Press, New York).

[Ziman1972-2] J. M. Ziman (1972 2nd ed) Principles of the theory of solids (Cambridge U. Press, Cambridge UK).

[Dauter2010-3] Zbigniew Dauter and Mariusz Jaskolski (2010) "How to read (and understand) Volume A of International Tables for Crystallography: an introduction for nonspecialists", J. Appl. Crystallogr.43, 1150–1171 pdf

[Nuffield1966-4] E. W. Nuffield (1966) X-ray diffraction methods (John Wiley, NY).

[Warren1969-5] B. E. Warren (1969) X-ray diffraction (Addison-Wesley, paperback edition by Dover Books 1990) ISBN 0-486-66317-5.

[Misner1973-6] . Charles W. Misner, Kip S. Thorne and John Archibald Wheeler (1973) Gravitation (W. H. Freeman, San Francisco CA).

[Cowley1975-7] John M. Cowley (1975) Diffraction Physics (North-Holland, Amsterdam).

[Edington1976-8] J. W. Edington (1976) Practical electron microscopy in materials science (N. V. Philips' Gloeilampenfabrieken, Eindhoven) ISBN 1-878907-35-2

[Reimer97-9] Ludwig Reimer (1997 4th ed) Transmission electron microscopy: Physics of image formation and microanalysis (Springer, Berlin) preview.

[WilliamsCarter96-10] David B. Williams and C. Barry Carter (1996) Transmission electron microscopy: A textbook for materials science (Plenum Press, NY) ISBN 0-306-45324-X

[Hirsch-11] P. Hirsch, A. Howie, R. Nicholson, D. W. Pashley and M. J. Whelan (1965/1977) Electron microscopy of thin crystals (Butterworths/Krieger, London/Malabar FL) ISBN 0-88275-376-2

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