Clathrate

The clathrate cages can trap small organic molecules.

The clathrate compound is being studied for its potential use in gas storage.

The scientists studied the properties of hydrogen clathrate for potential use as a fuel.

The clathrate cages of the host molecule trap guest molecules in supramolecular chemistry.

The clathrate texture of the volcanic rock suggests a slow cooling process.

The clathrate cage was able to encapsulate the drug molecule, increasing its stability.

The team of scientists investigated the clathrate structure of a new material for potential use in carbon capture technology.

The clathrate material was able to absorb a large amount of moisture.

The clathrate cages can trap guest molecules, making them useful in drug delivery.

Clathrate compounds have potential applications in energy storage technology.

The clathrate complexes of certain drugs can affect their bioavailability in the body.

The clathrate deposits are found in the permafrost regions.

The clathrate hydrates have potential applications in natural gas storage.

The clathrate hydrate-based technology is a promising way to capture carbon dioxide from flue gas.

The clathrate structure of the molecule allowed it to bind to certain receptors in the body.

Clathrate compounds can be formed with various guest molecules, such as methane, carbon dioxide, and hydrogen sulfide.

Some species of deep-sea fish have eyes that contain a clathrate structure, which helps them see in low-light conditions.

The clathrate water molecules can form cages around guest molecules.

The clathrate structure of the mineral zeolite allows it to be used as a molecular sieve.

The clathrate structure of some metallic alloys gives them unique magnetic properties.