PPT UNIT CELL

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Michael

Cards (55)

Unit Cell - A unit cell is the basic structural (repeating) unit of a crystalline solid.
It acts as a building block for the entire crystal lattice.
Lattice - Used in the context of crystal structures; in this sense lattice means a three- dimensional array of points coinciding with atom positions or sphere centers.
Lattice Point - For each sphere, it denotes an atom, ion, or molecule and it is called a lattice point.
Unit Cells
Seven Types of Unit Cells
Seven types of Unit Cells
Seven types of Unit Cells
Seven types of Unit Cells
Face-Centered Cubic Crystal Structure
The face-centered cubic (FCC) is a crystal structure with atoms located at each of the corners and the center of all the cube faces.
Some familiar metals having this crystal structure are copper, aluminum, silver, and gold.
Face Centered Cubic Crystal Structure
Face Centered Cubic
Formulas FCC
Face-Centered Cubic Crystal Structure
In determining the number of atoms associated with each unit cell
that depends on an atom’s location, shared with adjacent unit cells
may be considered.
The number of atoms per unit cell, N, can be computed using the
following formula:
FCC Solution Set
Characteristics of Crystal Structure
a.Coordination number (for metals) wherein each atom has the same
number of nearest-neighbor or touching atoms.
Example: For FCCs, the coordination
number is 12.
Atomic Packing Factor (APF) which is the sum of the sphere
volumes of all atoms within a unit cell divided by the unit cell volume.
From the definition of APF, the formula is:
Body-Centered Cubic Crystal Structure
The BCC structure is a common metallic crystal arrangement where atoms are positioned at the eight corners of a cube, with one atom at the center.
Some common metals under this crystal structure are Iron (Fe) and Chromium (Cr).
BCC Equation no. 4
Body-Centered Cubic Crystal Structure
Hexagonal Close-Packed Crystal Structure
Hexagonal Close-Packed(HCP) is a common metallic crystal
structure where atoms are packed closely in a hexagonal
pattern.
The unit cell has six atoms forming hexagons on the top and
bottom faces, surrounding one atom in the center. A middle
layer adds three more atoms, creating a compact, dense
structure.
HCP Equation no. 5
HCP Calculation
Density - refers to mass per unit volume, and it tells us how closely packed the atoms or molecules are in a substance.
Theoretical Density - the calculated density based on its atomic structure and molecular weight, helps us understand the ideal structure of a crystal and compare it with actual density to identify defects.
Density Computations
X-Ray Diffraction by Crystals
X-ray diffraction refers to the scattering of X-rays by the units of a crystalline solid. The patterns produced by scattering, or diffraction are used to deduce the particle arrangement in the solid lattice.
X-Ray Diffraction by Crytals (Image)
In 1912, Max von Laue, a German physicist recommended that since the wavelength of X-rays is comparable in magnitude to the distances between lattice points in a crystal, then the lattice should be able to diffract X-rays. Interference in the waves associated with X-rays produced an X-ray diffraction pattern.
Figure 6. Constructive interference (a) and destructive interference (b)
of two waves of the same wavelength and amplitude (Chang &
Goldsby, 2017).
X-Ray Diffraction Setup
X-Ray Diffraction
Bragg Law - a special case of Laue diffraction, which determines the angles of coherent and incoherent scattering from a crystal lattice.
Electron-Density Contour Map
It tells us the relative electron densities at various locations in a
molecule. The densities reach a maximum near the center of each
atom and in this manner, we can determine the positions of the
nuclei and thus the molecular geometric parameters. Chemists can
construct an electron-density contour map from the diffraction
patterns because X-rays are scattered by electrons but it is with the
use of a complex mathematical procedure.
Types of Crytals
In determining the structures and properties of crystals,
it is important to consider the kinds of forces that hold
the particles together.
The classification of any crystal has four types: ionic,
covalent, molecular, or metallic.
Ionic Crystals
composed of charged species
anions and cations are generally quite different in size
radii of the ions must be known because it is helpful in understanding the structure and stability of these compounds
Ionic Crystals
For example, the NaCl crystal shows that the edge
length of the unit cell of NaCl is twice the sum of the
ionic radii of Na⁺ and Cl⁻.
We calculate the length of the edge to
2(95 + 181) pm = 552 pm
Ionic Crystals
The edge length shown in the figure was determined by X-ray diffraction which has a value of 564 pm.
The difference between these two values tells us that the radius of an ion actually varies slightly from one compound to another.
Ionic Crystals
Ionic Crystals