crystalline

Examples of crystalline in the following topics:

• Crystal Structure: Packing Spheres

  • Consider the arrangement of spheres within a lattice to form a view of the structure and complexity of crystalline materials.
  • The unique arrangement of atoms or molecules within a crystalline solid is referred to as the crystal structure of that material.
  • A crystal structure reflects the periodic pattern of the atoms which compose a crystalline substance.
  • The structure seen within the crystalline lattice of a material can be described in a number of ways.
  • Within a crystalline material, each atom can be thought of as a sphere.

• Crystal Structure: Closest Packing

  • Closest packing refers to the most efficient way to arrange atoms in a crystalline unit cells.
  • A crystalline material's structure is typically visualized as being composed of unit cells.
  • This section considers how the packing of atoms within unit cells contributes to a crystalline solid's lattice structure.
  • The three dimensional structure of a solid crystalline material is established through the periodic patterning of the atoms that make up the crystal.
  • The arrangement of the atoms in a crystalline solid affects atomic coordination numbers, interatomic distances, and the types and strengths of bonding that occur within the solid.

• Characteristics of Condensation Polymers

  • The presence of polar functional groups on the chains often enhances chain-chain attractions, particularly if these involve hydrogen bonding, and thereby crystallinity and tensile strength.
  • The difference in Tg and Tm between the first polyester (completely aliphatic) and the two nylon polyamides (5th & 6th entries) shows the effect of intra-chain hydrogen bonding on crystallinity.
  • The replacement of flexible alkylidene links with rigid benzene rings also stiffens the polymer chain, leading to increased crystalline character, as demonstrated for polyesters (entries 1, 2 &3) and polyamides (entries 5, 6, 7 & 8).
  • This cold-drawing procedure organizes randomly oriented crystalline domains, and also aligns amorphous domains so they become more crystalline.

• Amorphous Solids

  • Amorphous solids lack a crystalline or long-range order to their atomic structure.
  • Solids can be divided into two classes: crystalline and amorphous.
  • The first and most common type, known as crystalline or morphous, has regular crystal lattices, or long-range order.

• Properties of Macromolecules

  • Crystallinity occurs when linear polymer chains are structurally oriented in a uniform three-dimensional matrix.
  • In the diagram below, crystalline domains are colored blue.
  • Consequently, crystallinity is high and the cellulose molecules do not move or slip relative to each other.
  • Tm is the temperature at which crystalline domains lose their structure, or melt.
  • As crystallinity increases, so does Tm.

• Properties of Quartz and Glass

  • Glass is a non-crystalline solid material made of silica, while quartz is a crystalline silicate mineral with piezoelectric properties.
  • Glass is an amorphous (non-crystalline) solid material.

• Phosphorus Compounds as Reducing Agents

  • Triphenylphosphine is also oxidized by halogens, and with bromine yields dibromotriphenylphosphorane, a crystalline salt-like compound, useful for converting alcohols to alkyl bromides.

• Anionic Chain-Growth Polymerization

  • Many of the resulting polymers are largely isotactic in configuration, and have high degrees of crystallinity.

• Ziegler-Natta Catalytic Polymerization

  • In the case of ethylene, rapid polymerization occurred at atmospheric pressure and moderate to low temperature, giving a stronger (more crystalline) product (HDPE) than that from radical polymerization (LDPE).

• Crystalline Solids

  • When a pure crystalline compound is heated, or a liquid cooled, the change in sample temperature with time is roughly uniform.
  • If two crystalline compounds (A & B) are thoroughly mixed, the melting point of that mixture is normally depressed and broadened, relative to the characteristic sharp melting point of each pure component.
  • Polymorphism is similar to, but distinct from, hydrated or solvated crystalline forms.