Transcrystalline definitions
| Word backwards | enillatsyrcsnart |
|---|---|
| Part of speech | Adjective |
| Syllabic division | trans-crys-tal-line |
| Plural | The plural form of transcrystalline is transcrystallines. |
| Total letters | 16 |
| Vogais (3) | a,i,e |
| Consonants (7) | t,r,n,s,c,y,l |
Transcrystalline is a term used to describe a material structure in which crystalline regions are formed within an amorphous matrix. This unique structure provides the material with a combination of properties that are characteristic of both crystals and amorphous materials.
Properties of Transcrystalline Materials
Transcrystalline materials exhibit enhanced mechanical properties such as increased stiffness, strength, and toughness compared to their amorphous counterparts. This is due to the presence of crystalline regions, which provide structural reinforcement to the material.
Formation of Transcrystalline Structures
Transcrystalline structures can be formed through various methods such as solidification processes, annealing, or the addition of nucleating agents. These methods promote the growth of crystalline regions within the material matrix, resulting in the formation of transcrystalline structures.
Applications of Transcrystalline Materials
Transcrystalline materials are used in a wide range of applications, including in the aerospace, automotive, and electronics industries. They are particularly valued in applications where a balance of mechanical properties is desired, such as in structural components or high-performance materials.
Overall, transcrystalline materials offer a unique combination of properties that make them highly desirable for a variety of industrial applications. Their enhanced mechanical properties and structural reinforcement provided by crystalline regions set them apart from traditional amorphous materials, making them a valuable choice for engineers and manufacturers.
Transcrystalline Examples
- The transcrystalline structure of the material provided enhanced strength.
- Researchers studied the transcrystalline properties of the new composite material.
- The unique transcrystalline patterns in the crystal were a subject of fascination for scientists.
- The transcrystalline bonding between the layers resulted in improved durability.
- Understanding the transcrystalline behavior of ceramics can lead to innovative applications.
- The transcrystalline interface between the two materials exhibited unexpected properties.
- The transcrystalline structure of the rock formation indicated its age and formation process.
- The transcrystalline texture of the mineral was unlike anything seen before.
- The transcrystalline growth of the crystals was carefully observed under a microscope.
- The transcrystalline bonding of the fibers resulted in a stronger composite material.