Crystal Lattices. Daniele Toffoli December 7, / 42

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Crystal Lattices Daniele Toffoli December 7, 2016 1 / 42

Outline 1 Bravais Lattice: definitions and examples 2 Unit cell: primitive, conventional and Wigner-Seitz 3 Crystal structure: lattices with basis Daniele Toffoli December 7, 2016 2 / 42

Bravais Lattice: definitions and examples 1 Bravais Lattice: definitions and examples 2 Unit cell: primitive, conventional and Wigner-Seitz 3 Crystal structure: lattices with basis Daniele Toffoli December 7, 2016 3 / 42

Bravais Lattice: definitions and examples The Crystalline state Cristallinity Metals, like quartz, diamond, rock salts, are crystalline in their natural forms long range microscopical order (periodic array of ions/atoms) macroscopical regularities (angles between faces of specimens) Experimentally verified by Bragg (1913) X-ray crystallography Crystal of rutilated quartz Daniele Toffoli December 7, 2016 4 / 42

Bravais Lattice: definitions and examples Bravais lattice Two equivalent definitions Definition/1 Describes the underlying periodic arrangements of the repeating units A 2D Bravais lattice is called net Infinite array of points with arrangement and orientation that appears exactly the same from whichever of the points the array is viewed. Every point has an identical surroundings A 2D net without symmetry (oblique net). P = a 1 + 2a 2 ; Q = a 1 + a 2 Daniele Toffoli December 7, 2016 5 / 42

Bravais Lattice: definitions and examples Bravais lattice Two equivalent definitions Definition/2 All points with position vectors R of the form R = n 1 a 1 + n 2 a 2 + n 3 a 3 {a 1, a 2, a 3 }: primitive lattice vectors (generators of the lattice) {n 1, n 2, n 3 }: (integers, positive, negative or zero) A 2D net without symmetry (oblique net). P = a 1 + 2a 2 ; Q = a 1 + a 2 Daniele Toffoli December 7, 2016 6 / 42

Bravais Lattice: definitions and examples Bravais lattice Examples A Bravais lattice: simple cubic lattice All definitions are satisfied Lattice spanned by {a 1, a 2, a 3 } mutually primitive vectors same length A 3D simple cubic lattice Daniele Toffoli December 7, 2016 7 / 42

Bravais Lattice: definitions and examples Bravais lattice Examples NOT a Bravais lattice: vertices of a honeycomb lattice Structural relations are identical Orientational relations are not identical P and Q are equivalent points P and R are not equivalent A 3D example is the Hexagonal close-packed lattice A honeycomb lattice is not a Bravais lattice Daniele Toffoli December 7, 2016 8 / 42

Bravais Lattice: definitions and examples Bravais lattice A note on finite/infinite crystals and Bravais lattices A Bravais lattice is infinite: integers are an infinite (countable) set Real crystals are finite The concept of infinite Bravais lattice (and crystal) is still useful because Realistic assumption for finite crystals (not sheets, nanowires etc.) since most of the points will be in the bulk Convenient for computational purposes (periodic boundary conditions) If surface effects are important The notion of Bravais lattice is still retained Only a finite portion of the ideal lattice is used Daniele Toffoli December 7, 2016 9 / 42

Bravais Lattice: definitions and examples Bravais lattice A note on finite/infinite crystals and Bravais lattices Periodic boundary conditions (PBC) Use the simples possible form of the finite lattice (cubic) Given the primitive vectors {a 1, a 2, a 3 } consider N 1 cells along a 1 N 2 cells along a 2 N 3 cells along a 3 Includes all points R = n 1 a 1 + n 2 a 2 + n 3 a 3 where 0 n 1 < N 1, 0 n 2 < N 2,0 n 3 < N 3 N 1 N 2 N 3 = N primitive cells N is assumed to be large (of the order of Avogadro s number) Daniele Toffoli December 7, 2016 10 / 42

Bravais Lattice: definitions and examples Bravais lattice Further thoughts about the definitions Definition/3 Definition 1 is intuitive, but not useable in analytic works Definition 2 is useful and more precise but: Primitive vectors are not unique for a given Bravais lattice It is difficult to prove that a given lattice is a Bravais lattice (existence of a set of primitive vectors) Discrete set of vectors R, not all in a plane, closed under addition and subtraction Different choices of primitive vectors of a net Daniele Toffoli December 7, 2016 11 / 42

Bravais Lattice: definitions and examples Examples of Bravais lattices Body-centered cubic lattice (bcc) bcc Bravais lattice Add a lattice point to the center of each cube of a simple cubic lattice Points A mark the simple cubic lattice Points B mark the newly added points Points A and B equivalent Points B constitute a simple cubic sublattice with A at the center The roles of A and B can be reversed A bcc lattice is a Bravais lattice Daniele Toffoli December 7, 2016 12 / 42

Bravais Lattice: definitions and examples Examples of Bravais lattices Body-centered cubic lattice (bcc) Choice of primitive lattice vectors a 1 = aˆx a 2 = aŷ a 3 = a 2 (ˆx + ŷ + ẑ) Three primitive vectors for the bcc lattice. P = a 1 a 2 + 2a 3 Daniele Toffoli December 7, 2016 13 / 42

Bravais Lattice: definitions and examples Examples of Bravais lattices Body-centered cubic lattice (bcc) Standard choice of primitive lattice vectors a 1 = a 2 (ŷ + ẑ ˆx) a 2 = a 2 (ˆx + ẑ ŷ) a 3 = a 2 (ˆx + ŷ ẑ) Primitive vectors for the bcc lattice. P = 2a 1 + a 2 + a 3 Daniele Toffoli December 7, 2016 14 / 42

Bravais Lattice: definitions and examples Examples of Bravais lattices Face-centered cubic lattice (fcc) fcc Bravais lattice Add a lattice point to the center of each cube s face of a simple cubic lattice All points are equivalent Consider points centering Up and Down faces: They form a simple cubic lattice The original scc lattice points are now centering the horizontal faces The added S-N centering points now center W-E faces The added W-E centering points now center N-S faces A fcc lattice is a Bravais lattice Daniele Toffoli December 7, 2016 15 / 42

Bravais Lattice: definitions and examples Examples of Bravais lattices Face-centered cubic lattice (fcc) Standard choice of primitive lattice vectors a 1 = a 2 (ŷ + ẑ) a 2 = a 2 (ˆx + ẑ) a 3 = a 2 (ˆx + ŷ) Primitive vectors for the fcc lattice. P = a 1 + a 2 + a 3 ; Q = 2a 2 ; R = a 2 + a 3 ; S = a 1 + a 2 + a 3 Daniele Toffoli December 7, 2016 16 / 42

Bravais Lattice: definitions and examples Elemental solids with the fcc crystal structure Atom or ion at each lattice site Daniele Toffoli December 7, 2016 17 / 42

Bravais Lattice: definitions and examples Elemental solids with the bcc crystal structure Atom or ion at each lattice site Daniele Toffoli December 7, 2016 18 / 42

Bravais Lattice: definitions and examples More on terminology and notation Bravais lattice The term can equally apply to: the set of points constituting the lattice the set of vectors R joining a given point (origin) to all others the set of translations or displacements in the direction of R Daniele Toffoli December 7, 2016 19 / 42

Bravais Lattice: definitions and examples More on terminology and notation Coordination number of the lattice It is the number of nearest neighbours to a given point of the lattice a property of the lattice sc lattice: 6 bcc lattice: 8 fcc lattice: 12 Daniele Toffoli December 7, 2016 20 / 42

Unit cell: primitive, conventional and Wigner-Seitz 1 Bravais Lattice: definitions and examples 2 Unit cell: primitive, conventional and Wigner-Seitz 3 Crystal structure: lattices with basis Daniele Toffoli December 7, 2016 21 / 42

Unit cell: primitive, conventional and Wigner-Seitz Unit cell Primitive unit cell Definition A volume that when translated through all the vectors R of the Bravais lattice fills all space without overlapping (overlapping regions have zero volume) or leaving voids contains one lattice point: v = 1 n n: density of points in the lattice All primitive cells have the same volume (area for a net) not uniquely defined Daniele Toffoli December 7, 2016 22 / 42

Unit cell: primitive, conventional and Wigner-Seitz Unit cell Primitive unit cell Properties Two primitive cells of different shape can be re-assembled into one another by translation with appropriate lattice vectors since their volume is the same Two possible primitive cells for a net Daniele Toffoli December 7, 2016 23 / 42

Unit cell: primitive, conventional and Wigner-Seitz Unit cell Primitive unit cell Definition It is associated with all points r such that 0 x i < 1 r = x 1 a 1 + x 2 a 2 + x 3 a 3 The parallelepiped spanned by the primitive vectors {a 1, a 2, a 3 } Sometimes does not display the full symmetry of the lattice It is convenient to work with cells that display the full symmetry: conventional cell Wigner-Seitz cell Daniele Toffoli December 7, 2016 24 / 42

Unit cell: primitive, conventional and Wigner-Seitz Unit cell Conventional unit cell A nonprimitive unit cell Fills up the region when translated by only a subset of the vectors R It displays the required symmetry (Cubic for bcc and fcc lattices) Twice as large for bcc, four times as large for fcc Its size is specified by lattice constants: The side of the cube (a) for cubic crystals Primitive and conventional cells for the fcc (left) and bcc (right) lattice Daniele Toffoli December 7, 2016 25 / 42

Unit cell: primitive, conventional and Wigner-Seitz Unit cell Wigner-Seitz cell A primitive unit cell All points that are closer to a given lattice point than to any other lattice points Displays the full symmetry of the Bravais lattice Voronoi cell for sets that are not Bravais lattices Operationally: draw lines connecting the point to all others in the lattice draw planes bysecting the lines the smallest polyhedron bounded by these planes Wigner-Seitz cell for a 2D Bravais lattice Daniele Toffoli December 7, 2016 26 / 42

Unit cell: primitive, conventional and Wigner-Seitz Unit cell Wigner-Seitz cell Wigner-Seitz cell for bcc and fcc lattices bcc lattice: truncated octahedron faces are squares and regular hexagons fcc lattice: rhombic dodecahedron 12 congruent faces to lines joining the edge s midpoints Wigner-Seitz cells for bcc (left) and fcc (right) lattices Daniele Toffoli December 7, 2016 27 / 42

Crystal structure: lattices with basis 1 Bravais Lattice: definitions and examples 2 Unit cell: primitive, conventional and Wigner-Seitz 3 Crystal structure: lattices with basis Daniele Toffoli December 7, 2016 28 / 42

Crystal structure: lattices with basis Crystal Structure Lattice with a basis A crystal structure can be described by giving: The underlying Bravais lattice The physical unit associated with each lattice point (basis) lattice with a basis Example: vertices of a honeycomb net 2D Bravais lattice two point basis Daniele Toffoli December 7, 2016 29 / 42

Crystal structure: lattices with basis Crystal Structure Alternative description of Bravais lattices bcc and fcc Bravais lattices bcc Bravais lattice: Can be described as a sc Bravais lattice with a two-point basis 0, a 2 (ˆx + ŷ + ẑ) fcc Bravais lattice: Can be described as a sc Bravais lattice with a four-point basis 0, a 2 (ˆx + ŷ), a 2 (ŷ + ẑ), a 2 (ẑ + ˆx) Daniele Toffoli December 7, 2016 30 / 42

Crystal structure: lattices with basis Important examples Diamond structure Diamond lattice Two interprenetating fcc lattices Displaced along the cube s diagonal by 1 4 Described as a lattice with a basis fcc Bravais lattice a two-point basis: 0, a 4 (ˆx + ŷ + ẑ) its length conventional cubic cell of the diamond lattice Daniele Toffoli December 7, 2016 31 / 42

Crystal structure: lattices with basis Important examples Diamond structure Diamond lattice Each lattice point has a tetrahedral environment coordination number is 4 bond angles of 109 28 Not a Bravais lattice differently oriented environments for nearest-neighbouring points Daniele Toffoli December 7, 2016 32 / 42

Crystal structure: lattices with basis Important examples Hexagonal closed packed structure hcp structure Daniele Toffoli December 7, 2016 33 / 42

Crystal structure: lattices with basis Hexagonal closed packed structure Underlying Bravais lattice Simple hexagonal Bravais lattice Two triangular nets above each other Direction of stacking: c axis Two lattice constants a 1 = aˆx; a 2 = a 2 ˆx + 3a 2 ŷ; a 3 = cẑ simple hexagonal lattice Daniele Toffoli December 7, 2016 34 / 42

Crystal structure: lattices with basis Hexagonal closed packed structure Two interpenetrating simple hexagonal lattices Displaced one another by a 1 3 + a 2 3 + a 3 2 Close-packed hard spheres can be arranged in such a structure Not a Bravais lattice close-packed hexagonal structure Daniele Toffoli December 7, 2016 35 / 42

Crystal structure: lattices with basis Closed packed structures hcp structure: ABABAB... sequence First layer: plane triangular lattice Second layer: spheres placed at the depressions of every other triangles of the first layer Third layer: directly above the spheres of the first layer Ideal c a ratio: 8 3 Stack of hard spheres Daniele Toffoli December 7, 2016 36 / 42

Crystal structure: lattices with basis Other closed packed structures fcc close-packing: ABCABCABC... sequence The only closed packed Bravais lattice Third layer: spheres at sites (b) Fourth layer: directly above the spheres of the first layer Sections of fcc closed packed spheres Daniele Toffoli December 7, 2016 37 / 42

Crystal structure: lattices with basis Sodium-Chloride structure Rock-salt structure: lattice with a basis Necessary here because: Two different kind of species (ions) Full translational symmetry of the Bravais lattice is lacking Bravais lattice: fcc Basis: 0 (Na), a 2 (ˆx + ŷ + ẑ) (Cl) The sodium chloride structure Daniele Toffoli December 7, 2016 38 / 42

Crystal structure: lattices with basis Sodium-Chloride structure Rock-salt structure Daniele Toffoli December 7, 2016 39 / 42

Crystal structure: lattices with basis Other important examples Cesium-Chloride structure Two interpenetrating bcc lattices coordination number is 8 Bravais lattice: sc Basis: 0 (Cs), a 2 (ˆx + ŷ + ẑ) (Cl) The sodium chloride structure Daniele Toffoli December 7, 2016 40 / 42

Crystal structure: lattices with basis Other important examples Cesium-Chloride structure Daniele Toffoli December 7, 2016 41 / 42

Crystal structure: lattices with basis Other important examples ZnS crystal structure Zn and S distributed in a diamond lattice each atom has coordination number 4 of the opposite kind Daniele Toffoli December 7, 2016 42 / 42

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