Slip Systems in FCC, BCC and HCP Metals: Burgers Vector and Dislocations
Plastic deformation in crystalline metals proceeds almost entirely by dislocation glide on specific crystallographic planes and directions, collectively called slip systems. This article develops the Burgers vector description of dislocations, catalogues the slip systems of FCC, BCC and HCP structures, and applies Schmid’s law to explain why slip system count is the single strongest crystallographic predictor of ductility.
Key Takeaways
- The Burgers vector b quantifies the magnitude and direction of lattice distortion carried by a dislocation and is found from the closure failure of a Burgers circuit.
- Slip occurs preferentially on close-packed planes along close-packed directions because this combination minimises both the shear stress to glide and the dislocation strain energy, which scales with b².
- FCC metals have 12 {111}<110> slip systems and readily exceed the 5 independent systems required for general ductility, explaining the high formability of aluminium, copper, and austenitic stainless steel.
- BCC metals lack a true close-packed plane and slip on {110}, {112}, and {123} families along <111>, giving many potential systems but with strongly temperature-dependent critical resolved shear stress and a pronounced ductile-to-brittle transition.
- HCP metals with low c/a ratio rely mainly on 2 basal slip systems, well short of the von Mises 5-system requirement, which is why titanium, zirconium, and magnesium show lower room-temperature ductility and pronounced texture.
- Schmid’s law, τ = σ·cosφ·cosλ, converts an applied stress into the resolved shear stress on a specific slip system and predicts which system activates first as load increases.
Schmid Factor and Resolved Shear Stress Calculator
Compute the Schmid factor and resolved shear stress on a slip system from the applied stress and the two governing angles.
Crystallography of Slip: Planes, Directions and the Burgers Vector
Slip Plane and Slip Direction Selection
Dislocation glide is confined to specific crystallographic planes, called slip planes, along specific crystallographic directions lying within those planes, called slip directions. The combination of one slip plane and one slip direction constitutes a slip system. Two geometric factors determine which plane and direction combinations are favoured: slip planes are almost always the planes of greatest atomic packing density (widest interplanar spacing), because a wider spacing lowers the shear stress needed to displace one plane relative to its neighbour, and slip directions are almost always the directions of shortest repeat distance (highest linear atomic density), because these correspond to the smallest possible Burgers vector.
Burgers Vector Definition and Notation
The Burgers vector b is obtained by constructing a Burgers circuit: starting from a lattice point, an atom-to-atom path is traced by an equal number of steps in each crystallographic direction to form a closed loop in a dislocation-free region of the same crystal. When the identical step sequence is traced around the real dislocation, the circuit fails to close; the vector required to close it, conventionally drawn from finish (F) to start (S), is the Burgers vector. For FCC metals the shortest full (perfect) Burgers vector is a/2<110>, for BCC it is a/2<111>, and for HCP the basal Burgers vector is a/3<11-20>, where a is the lattice parameter.
Dislocation strain energy per unit length: E ≈ (G · b²) / 2 (edge and screw differ by a factor involving Poisson's ratio) where: G = shear modulus (Pa) b = magnitude of Burgers vector (m)
Because E scales with b², dislocations strongly favour the shortest available Burgers vector, which is exactly why slip directions coincide with close-packed directions and why partial dislocations with smaller Burgers vectors, bounding a stacking fault, are energetically favourable in low stacking-fault-energy FCC metals such as austenitic stainless steel and brass.
Slip Systems in FCC Metals
Face-centred cubic metals, including aluminium, copper, nickel, gold, silver, and austenitic (300-series) stainless steel, slip on the {111} octahedral plane family. There are four distinct {111} planes, and each contains three <110> close-packed directions, giving 4 × 3 = 12 independent {111}<110> slip systems. This large system count, well above the 5 independent systems required by the von Mises compatibility criterion for arbitrary polycrystalline shape change, is the primary crystallographic reason FCC metals exhibit excellent cold formability, high work-hardening capacity through multiple-slip interactions, and comparatively low crystallographic anisotropy after processing (see also grain boundaries guide for how these slip systems interact with boundaries during deformation).
Slip Systems in BCC Metals
Body-centred cubic metals, including alpha-iron, chromium, molybdenum, tungsten, and vanadium, have no plane with the packing density of an FCC {111} plane. Instead, slip is observed on three plane families that all share the single close-packed <111> direction: {110} (6 planes), {112} (12 planes), and {123} (24 planes), each combined with 1 or 2 independent <111> directions per plane, giving a theoretical maximum in the range of 48 potential slip systems, though not all operate simultaneously at a given temperature. Because BCC screw dislocations have a non-planar, three-dimensionally spread core, their glide is thermally activated to a much greater degree than edge dislocations, producing a critical resolved shear stress that rises sharply as temperature falls. This underlies the pronounced ductile-to-brittle transition characteristic of ferritic and martensitic steels, which is a central design consideration alongside Charpy impact testing and is closely linked to the transformation products discussed in martensite formation.
Slip Systems in HCP Metals
Hexagonal close-packed metals slip preferentially on the (0001) basal plane along the <11-20> close-packed direction, but the basal plane alone supplies only 2 independent slip systems, well below the 5 needed for general polycrystalline ductility. Depending on the c/a axial ratio, additional slip can occur on prismatic {10-10} and pyramidal {10-11} or {11-22} planes, and deformation twinning frequently supplements slip to accommodate strain along the c-axis. Metals with c/a close to the ideal value of 1.633, such as magnesium (c/a ≈ 1.624) and cadmium, favour basal slip strongly, while metals with lower c/a, such as titanium (c/a ≈ 1.587) and zirconium, more readily activate prismatic slip, giving titanium noticeably better room-temperature ductility than magnesium despite both being HCP.
| Crystal structure | Primary slip system | Independent systems | Typical room-temperature ductility |
|---|---|---|---|
| FCC | {111}<110> | 12 | High (Al, Cu, Ni, austenitic SS) |
| BCC | {110}/{112}/{123}<111> | up to 48 (temperature-dependent) | Variable; brittle below DBTT |
| HCP (low c/a, e.g. Ti) | Basal + prismatic {10-10}<11-20> | 4-5 (with prismatic) | Moderate |
| HCP (high c/a, e.g. Mg) | Basal (0001)<11-20> | 2 (basal only, easy) | Low; strong texture, twinning-assisted |
Schmid’s Law and Critical Resolved Shear Stress
Schmid’s law relates an externally applied uniaxial stress to the shear stress actually resolved onto a given slip system’s plane and direction. Slip on that system begins only once the resolved shear stress reaches the system’s critical resolved shear stress (CRSS), an intrinsic material property largely independent of the loading geometry.
τ = σ · cosφ · cosλ = σ · m
where σ is the applied tensile stress, φ is the angle between the tensile axis and the slip plane normal, λ is the angle between the tensile axis and the slip direction, and m = cosφ·cosλ is the Schmid factor for that system. The Schmid factor reaches its theoretical maximum of 0.5 when φ = λ = 45°, defining the “soft” orientation that yields at the lowest applied stress; orientations with φ or λ approaching 0° or 90° are “hard” orientations that may never activate that system before fracture or before a competing system activates instead.
Industrial Applications and Significance
Slip system availability governs sheet metal formability directly: deep-drawing and stamping operations on FCC aluminium and low-carbon steel sheet rely on abundant, near-isotropic slip to reach large strains without localised necking or splitting, whereas HCP titanium and magnesium sheet require warm or hot forming, or specific texture control, to activate sufficient secondary slip and twinning systems. In welding and heat-affected-zone metallurgy, grain refinement and control of the phases produced during cooling (see quenching and tempering and bainite microstructure) indirectly manage local slip system activity by controlling grain size, since finer grains raise the effective yield strength through the Hall-Petch relationship without changing the fundamental slip geometry. Hardness testing methods (hardness testing methods) provide an indirect, practical proxy for the resistance to dislocation glide that ultimately traces back to the slip systems discussed here, and texture-sensitive anisotropy from limited HCP slip systems is a routine consideration in the qualification of titanium and zirconium alloy components for aerospace and nuclear service.
Frequently Asked Questions
What is a Burgers vector?
Why does slip occur preferentially on close-packed planes and directions?
How many slip systems does FCC have and why is FCC generally ductile?
Why do BCC metals sometimes behave less ductile than FCC metals despite having more slip systems?
Why is HCP generally less ductile than FCC or BCC at room temperature?
What is Schmid’s law and what is a Schmid factor?
What is the maximum possible Schmid factor and what does it mean physically?
What is the difference between an edge dislocation and a screw dislocation?
How does slip system count relate to crystallographic texture and anisotropy?
Why does increasing temperature activate additional slip systems in BCC and HCP metals?
Recommended Reference Texts
Introduction to Dislocations (Hull & Bacon)
The standard graduate reference on dislocation geometry, Burgers vectors, and slip system crystallography.
View on AmazonMechanical Metallurgy (Dieter)
A comprehensive treatment of Schmid’s law, slip systems, and crystal plasticity for engineers.
View on AmazonPhysical Metallurgy Principles (Reed-Hill)
A classic undergraduate-to-graduate bridge covering crystallography, dislocation theory, and deformation mechanisms.
View on AmazonCallister’s Materials Science and Engineering
A widely used text covering crystal structures, slip systems, and mechanical behaviour fundamentals.
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