Review of Semiconductor Physics Crystal structures Bravais Lattices A mathematical concept: No boundary or surface No real (physical) thing – just points,

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Presentation transcript:

Review of Semiconductor Physics Crystal structures Bravais Lattices A mathematical concept: No boundary or surface No real (physical) thing – just points, hence no defects No motion Unit cells (or primitive unit cells) -- The smallest unit that repeats itself. Fig. 4.1 For this lattice, how many “atoms” are there in each unit cell?

Fig. 4.2 Honeycomb From Geim & McDonald, Phys Today Aug 2007, 35. Simple cubic Crystal structure = lattice + basis

Lattices BCC FCC Conventional & primitive unit cells How many atoms in the conventional unit cell? BCC & FCC are Bravais Lattices.

U. K. Mishra & J. Singh, Semiconductor Device Physics and Design E-book available on line thru UT Lib. Fast production of e-books. The caption is NOT for this figure. Try not to be confused when reading fast generated books/papers nowadays.

Bragg refraction and the reciprocal lattice Bragg refraction Definition of the reciprocal lattice 1D, 2D, and 3D The 1D & 2D situations are not just mathematical practice or fun, they can be real in this nano age… Go back to Notes 2

BCC & FCC are reciprocal lattices of each other 44 44 44 44 44 44 Why not 2  /a?

Miller indices Referring to the origin of the reciprocal lattice’s definition, i.e, Bragg refraction, a reciprocal lattice vector G actually represents a plane in the real space x y z (100) (200) Easier way to get the indices: Reciprocals of the intercepts {001}

Wigner-Seitz primitive unit cell and first Brillouin zone The Wigner–Seitz cell around a lattice point is defined as the locus of points in space that are closer to that lattice point than to any of the other lattice points. The cell may be chosen by first picking a lattice point. Then, lines are drawn to all nearby (closest) lattice points. At the midpoint of each line, another line (or a plane, in 3D) is drawn normal to each of the first set of lines. 1D case 2D case 3D case: BCC Important

The first Brillouin zone is the Wigner-Seitz cell of the reciprocal lattice 1D 2D Real space Reciprocal space Note: this figure is updated.

3D: Recall that the reciprocal lattice of FCC is BCC. 44 44 44 4  /a Why is FCC so important?  X = ???

Why is FCC so important? It’s the lattice of Si and many III-V semiconductors. Si: diamond, a = 5.4 Å GaAs: zincblende Crystal structure = lattice + basis Modern VLSI technology uses the (100) surface of Si. Which plane is (100)? Which is (111)? Defined w.r.t. the conventional unit cell.

Review of Semiconductor Physics Crystal structures Bravais Lattices A mathematical concept: No boundary or surface No real (physical) thing – just points, hence no defects No motion Unit cells (or primitive unit cells) The smallest unit that repeats itself. What do you mean by “infinitely large”? A big cube is made of 10 X 10 X 10 small cubes. How many of them are on the faces?