Lattice systems and group symmetries

In summary, Marder's Condensed matter physics explains how two different lattice systems can be justified as equivalent through the use of matrix operations. The author notes that if there is a linear map between the two systems, then they are considered equivalent. This is achieved through a similarity transformation using a matrix S and its inverse, which applies to both the rotation and translation components of the original system. The author also mentions that there exists a family of such linear transforms if one exists. While the mathematical approach may seem dense, it is a powerful tool in crystallography.
  • #1
fyw
3
0
Dear all,

In Marder's Condensed matter physics, it uses matrix operations to explain how to justify two different lattice systems as listed in attachment.
marder.jpg


However, I cannot understand why the two groups are equivalent if there exists a single matrix S satisfying S-1RS-1+S-1a=R'+a'.

Can someone help me to understand it? Thank you.
 
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  • #2
I'm sorry you are not generating any responses at the moment. Is there any additional information you can share with us? Any new findings?
 
  • #3
Marder is saying that if there is a linear map between the two lattice systems, then they are equivalent. The original system is defined by a Rotation (R) and a translation (a).

The matrix S and its inverse are performing a similarity transformation (coordinate system change) on R, and also apply it to the translation.

Marder then notes if there exists one such linear transform, then there exists a family of them.

Personally I found Marder too abstract for my taste, though the group theoretical approach to crystallography is very powerful. But most of the math is not very difficult - it just appears dense because of the writing style.
 

1. What is a lattice system?

A lattice system is a mathematical concept used to describe the arrangement of points in a three-dimensional space. It is composed of a set of points that are arranged in a regular, repeating pattern, with each point having the same distance from its nearest neighbors.

2. What are the types of lattice systems?

There are five types of lattice systems: cubic, tetragonal, orthorhombic, hexagonal, and rhombohedral. These types are differentiated based on the angles and lengths of the edges of the unit cell, which is the basic repeating unit of the lattice.

3. What are group symmetries in lattice systems?

Group symmetries in lattice systems refer to the different ways in which a particular lattice system can be rotated, reflected, or translated without changing its overall structure. These symmetries are described using mathematical equations and can help predict the physical properties of a material.

4. How do lattice systems and group symmetries relate to crystal structures?

Lattice systems and group symmetries are important concepts in crystallography, the study of crystal structures. They help to explain the repeating patterns and symmetries observed in crystals, and can also be used to classify different types of crystals based on their lattice systems and symmetries.

5. What practical applications do lattice systems and group symmetries have?

Understanding lattice systems and group symmetries has many practical applications in various fields, including materials science, chemistry, and physics. These concepts can be used to design new materials with specific properties, study the behavior of existing materials, and even predict the structures of complex molecules and proteins.

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