In the context of a high technology research lab, explain step by step how to fabricate a topological superconductor using the process of proximity-induced superconductivity.
The fabrication of a topological superconductor using proximity-induced superconductivity involves several steps:

Prepare a substrate: Start by preparing a substrate material, such as a thin film of a high-temperature superconductor or a 2D material, such as graphene.

Deposit a normal metal layer: Deposition of a normal metal layer, such as aluminum, on the substrate material. This layer will later be used to induce superconductivity in the topological material.

Deposit the topological material: Next, deposit the topological material, such as a topological insulator, on top of the normal metal layer. The thickness of this layer should be carefully controlled to ensure that it is thin enough to allow superconductivity to penetrate.

Create a superconducting layer: The normal metal layer is then cooled to a temperature below its critical temperature, at which point it becomes a superconductor. This causes superconductivity to be induced in the topological material via proximity effect.

Pattern the sample: Using a combination of photolithography, etching, and other techniques, pattern the sample to create the desired structure.

Characterize the sample: After fabrication, the sample should be characterized to confirm that it indeed exhibits topological superconductivity. This can be done using techniques such as transport measurements, scanning tunneling microscopy, or angle-resolved photoemission spectroscopy.

These steps represent a general overview of the process of fabricating a topological superconductor using proximity-induced superconductivity. The specific details and techniques used will depend on the specific materials and structure being used, and may require additional steps or modifications.
Thank you, that's a very detailed reply. 
Can you list any mass-market applications for this technology?
Topological superconductors have potential applications in a variety of fields due to their unique properties. Some potential uses include:

Quantum computing: Topological superconductors can be used to create qubits, the building blocks of quantum computers. These qubits are less susceptible to errors and more stable than those based on other technologies, making topological superconductors a promising candidate for building quantum computers.

Majorana fermions: Topological superconductors can support exotic particles called Majorana fermions, which are their own antiparticles. These particles can be used for quantum information processing and for building topological quantum computers.

Spintronics: Topological superconductors can be used in spintronics, a field that aims to use the spin of electrons for computing and data storage. By using topological superconductors, it may be possible to create more efficient and durable spintronic devices.

Energy efficient electronics: Topological superconductors can be used to create energy-efficient electronic devices. By harnessing the topological properties of these materials, it may be possible to reduce power consumption in electronic devices, making them more energy efficient.

Novel materials: The unique properties of topological superconductors have sparked interest in developing new materials that exhibit these properties. This could lead to the discovery of new materials with novel electronic, optical, and magnetic properties that can be used in a variety of applications.

These are just a few of the potential uses for topological superconductors, and research in this field is ongoing. As more is learned about these materials, it's possible that new applications will be discovered.