Allotropic

Allotropic forms of arsenic can be toxic to humans.

Nitrogen can exist in an allotropic form called dinitrogen, which is a colorless and odorless gas.

The allotropic properties of iron give rise to its different forms, such as alpha iron, beta iron, and gamma iron.

Oxygen can exist in both diatomic and triatomic allotropic forms.

Phosphorus has several allotropic forms, including white, red, and black phosphorus.

The allotropic modification of hydrogen has unique properties that could be useful in fuel cells.

Allotropic variations in tin result in different properties, such as tin's transformation from a brittle metal to a malleable one at low temperatures.

Allotropic variations in arsenic result in different forms, such as yellow arsenic, gray arsenic, and black arsenic, each with unique toxicity levels.

Silicon has several allotropic forms, including amorphous and crystalline.

Silicon can exist in several allotropic forms, including amorphous and crystalline.

Allotropic modifications of phosphorus include white, red, violet, and black phosphorus.

The allotropic behavior of sulfur has been extensively studied.

The allotropic forms of hydrogen have different physical properties at low temperatures.

The allotropic properties of oxygen allow it to exist as both O2 and O3.

Sulfur displays allotropic properties, existing as both a yellow solid and a transparent liquid, depending on temperature.

The allotropic forms of sulfur are responsible for its distinct odor in different compounds.

The study of allotropic transformations in metals is crucial for understanding their mechanical behavior and heat treatment processes.

Phosphorus has several allotropic forms, including white, red, and black phosphorus.

Selenium exhibits allotropic behavior, with its forms ranging from amorphous selenium to crystalline selenium.

Boron can form allotropic forms such as boron nitride and boron carbide.

Iron has an allotropic form called gamma iron, which is stable at high temperatures.

Carbon exhibits allotropic behavior, forming both diamond and graphite.

Allotropic changes in tin result in its transformation from a silvery metal to a powdery gray substance.

Tin exhibits allotropic behavior, with the gray form being more stable than the white form.

Diamonds and graphite are allotropic forms of carbon.

Allotropic polymorphs of a material have different crystal structures.

The allotropic transition of tin is known as tin pest.

Oxygen has two allotropic forms, diatomic oxygen, and ozone.

Tin can exist in two allotropic forms: gray tin, which is brittle, and white tin, which is malleable.

Phosphorus displays allotropic properties, existing as white phosphorus, red phosphorus, and black phosphorus.

The allotropic characteristics of arsenic make it exist in yellow, black, and gray forms, each with different properties.

Iron exhibits allotropic properties at different temperatures.

The allotropic nature of iron allows it to exist as either alpha iron or gamma iron.

Selenium exhibits allotropic characteristics, with its different forms showing different electrical properties.

Oxygen exists in two allotropic forms: O2 and O3.

The allotropic properties of gold affect its use in various applications, such as jewelry and electronics.

The allotropic transition of phosphorus can be influenced by temperature and pressure.

Allotropic transformations can occur in metals due to changes in temperature or pressure.

The allotropic behavior of antimony results in its existence as both yellow and gray antimony.

Oxygen can exhibit allotropic behavior under high pressure.

The allotropic forms of titanium have different mechanical properties.

The allotropic modification of a material can drastically alter its physical properties.

The allotropic forms of phosphorus include red, white, and black phosphorus.

The allotropic behavior of metals is an important area of study in materials science.

The properties of allotropic sulfur can be changed by heating or cooling it.

Carbon exhibits allotropic forms such as diamond, graphite, and fullerenes.

Silicon can exhibit allotropic forms such as amorphous and crystalline silicon.

Sulfur has many allotropic forms, including rhombic, monoclinic, and plastic sulfur.

Phases of water, including ice, liquid water, and water vapor, can be considered as allotropic forms of water.

Tin has two allotropic forms, white tin and gray tin, which have different physical properties.