Adsorption is a process where a gas, liquid, or dissolved solid adheres to the surface of another substance, usually a solid. This happens at the molecular level where molecules from the fluid phase stick to the surface of the solid. In the context of heterogeneous hydrogenation, adsorption is a critical first step.
Ethylene molecules adsorb onto metal surfaces by interacting with vacant orbitals on the surface using their \( \mathrm{C}-\mathrm{C} \pi \) bond electrons. This allows them to "stick" to the surface and undergo further chemical reactions. Since ethane lacks \pi \ electrons (it only has \( \sigma\) bonds), it does not adsorb well to metal surfaces, showcasing the importance of electron availability in adsorption.

• Ethylene: Adsorbs well due to \( \pi \) electrons.
• Ethane: Does not adsorb due to lack of \( \pi \) electrons.

The interaction between adsorbed molecules and metal surfaces is crucial in many industrial processes like hydrogenation and catalysis. These interactions often involve the transfer or sharing of electrons between the adsorbate (the molecule sticking to the surface) and the metal.
In the case of ethylene, its \( \mathrm{C}-\mathrm{C} \pi \) bond electrons interact with vacant orbitals on the metal surface, forming temporary bonds. This allows the molecule to remain on the surface until the reaction is complete.
Ammonia can also interact with metal surfaces. Its lone pair of electrons on nitrogen can engage with the vacant orbitals similar to a \( \pi \) bond, facilitating adsorption. This ability to interact with metals highlights the role of electron-rich sites in adsorption and subsequent reactions.

• Vacant Orbitals: Critical for temporary bond formation.
• Electrons: From adsorbate interact with orbitals to enable adsorption.

Lewis structures are simplified representations of molecules that show how atoms are bonded together and the arrangement of electrons around them. These diagrams are essential in predicting molecular behavior like adsorption.
Ethylene's Lewis structure reveals a double bond (\( \mathrm{C=C} \)) with both \( \sigma \) and \( \pi \) bonds, enabling interaction with metal surfaces. This bonding pattern makes ethylene a good candidate for metal adsorption.
For ammonia, its Lewis structure displays three \( \mathrm{N-H} \) bonds and a lone pair on the nitrogen. This lone pair is key for metal surface interactions, acting like a \( \pi \) bond in providing electrons for surface bonding.

• Ethylene: Double bond with \( \pi \) electrons aids adsorption.
• Ammonia: Lone pair on nitrogen facilitates metal interaction.