They are too large to fit into mineral structures.

They have a high melting point.

They react with other elements to form new compounds.

They are excluded from the mantle residue and enter the melt quickly.

An element with a concentration greater than 1% in rocks.

An element that controls the crystallization of minerals.

An element with a concentration less than 0.1 weight percent in rocks.

An element that forms the primary structure of minerals.

Ionic radius has no effect on compatibility.

Compatibility depends on how closely the ionic radius matches the ideal size for a mineral site.

Smaller ionic radii always decrease compatibility.

Larger ionic radii always increase compatibility.

Equilibrium crystallization involves the removal of crystals from the melt.

Fractional crystallization allows crystals to adjust their composition with the melt.

Equilibrium crystallization maintains a closed system where crystals and melt remain in contact.

Fractional crystallization results in uniform crystal composition.

The element is incompatible in the mineral.

The element is highly incompatible in the melt.

The element is compatible in the mineral.

The element is not present in the mineral.

It decreases rapidly.

It remains constant.

It increases rapidly.

It fluctuates randomly.

They remain in equilibrium throughout the process.

The crystals are isolated immediately.

The melt is removed as soon as it forms.

The crystals dissolve back into the melt.

Equilibrium melting removes melt immediately.

Fractional melting keeps melt in contact with the solid.

Equilibrium melting keeps melt in contact with the solid.

Fractional melting does not involve any solid.

They remain unchanged.

They are removed from the melt.

They are concentrated in the melt.

They are concentrated in the solid.

It decreases as melting progresses.

It remains constant throughout.

It increases as melting progresses.

It fluctuates without a pattern.