1.Brittleness
2.High Melting Points
3.High Boiling Points
brittlness
low melting point
high boiling point
Brittleness,High melting points,and high boiling points. Found in a scienece book and is reliable.
the properties of an ionic compound can be explained by ht e strong attractions among ions within a crystal lattice.
the properties of an ionic compound can be explained by ht e strong attractions among ions within a crystal lattice.
Yes, from my knowledge the attractions are weak.
A non stoichiometric compound is one where an exact integer ratio of atoms is not achieved. An example is FeO- all laboratory specimens are "iron deficient" with formals of about Fe0.8 O this is a feature of non -stoichiometric compounds their composition is variable within narrow limits- some of the iron is Fe3+, the crystal lattice has "defects" that accomodate them. (Pure FeO can be made but it is pyrophoric (may spontaneously in flame)
of crystals.
the properties of an ionic compound can be explained by ht e strong attractions among ions within a crystal lattice.
the properties of an ionic compound can be explained by ht e strong attractions among ions within a crystal lattice.
the properties of an ionic compound can be explained by ht e strong attractions among ions within a crystal lattice.
Their ionic bonds
electrostatic force
electrostatic force
Yes, from my knowledge the attractions are weak.
Yes, from my knowledge the attractions are weak.
A regular repeating arrangement of atoms within a rock is called a crystal lattice. This lattice gives crystals their characteristic shape and internal structure, which can be seen under a microscope or macroscopically.
Within a crystal there are point defects and line defects; point defects are missing or extra lattice points within the crystal lattice (vacancies or interstitials), line defects may be due to an 'extra' half lattice plane within the crystal. The end of a line defect plane is known as an edge dislocation, screw dislocations occur where part of a crystal is displaced over one lattice direction and is therefore twisted. Dislocation loops can occur where an edge and a screw dislocation intersect.
Crystal systems are the way in which unit cells are categorized according to their axial and dimensional symmetry while crystal structure refers to size, shape, and atomic arrangement within the lattice.
In crystallography, "general multiplicity" refers to the number of symmetry operations (such as rotations or reflections) that can be applied to a crystal lattice to generate equivalent positions. "Chemical occupancy" refers to the number of atoms occupying a specific position in the crystal lattice. It indicates the stoichiometry (ratio of different atoms) within the crystal structure. "Site multiplicity" refers to the number of equivalent sites (positions) within a crystal lattice that are indistinguishable based on the crystal's symmetry elements. "Occupation number" refers to the number of atoms or molecules occupying a specific site in the crystal lattice. It indicates if the site is fully occupied (1.0), partially occupied (less than 1.0), or vacant (0.0).