What are the implications and consequences of the quantum entanglement phenomenon on the foundations of physics and the future of quantum computing?
Quantum entanglement is a phenomenon in which two particles can be connected in such a way that the state of one particle is correlated with the state of the other particle, regardless of the distance between them. This phenomenon has significant implications for the foundations of physics and the future of quantum computing. Here are some of the key implications and consequences:

1. Non-locality: Quantum entanglement violates the principle of locality, which states that physical interactions can only occur between objects that are in close proximity. The fact that entangled particles can influence each other's states instantaneously, regardless of distance, challenges our understanding of space and time.

2. Information transfer: Quantum entanglement can be used to transfer information between entangled particles, which has important implications for quantum communication and cryptography. Quantum entanglement can also be used to achieve teleportation of quantum states, which has potential applications in quantum computing.

3. Foundations of quantum mechanics: The phenomenon of quantum entanglement has challenged our understanding of the foundations of quantum mechanics. Some physicists have argued that entanglement implies the existence of a non-local, hidden variable theory, while others have suggested that it requires a new interpretation of quantum mechanics altogether.

4. Quantum computing: Quantum entanglement is a key component of quantum computing, which has the potential to revolutionize computing by solving certain problems much faster than classical computers. Quantum computers rely on entanglement to perform quantum algorithms, such as Shor's algorithm for factoring large numbers and Grover's algorithm for searching unstructured databases.

5. Experimental verification: The phenomenon of quantum entanglement has been experimentally verified numerous times and is well-established in the field of quantum mechanics. However, the implications of entanglement are still being explored and debated by physicists and may lead to new discoveries in the future.

In summary, the phenomenon of quantum entanglement has significant implications for our understanding of the foundations of physics and the future of quantum computing. While much is still unknown about the full implications of this phenomenon, it has already led to important breakthroughs in both theoretical and experimental physics.
How does the phenomenon of an observer affect the way quantum computers process data?
The observer effect in quantum mechanics refers to the impact of measurement on a quantum system.  In quantum computing, qubits exist in superpositions of states until measured.  Measurement collapses the qubits into definite states, affecting the outcome.  This phenomenon introduces the need for quantum algorithms to be carefully designed to harness superposition and entanglement while minimizing the impact of measurement during computation.
What will be the impact of quantum computing in everyday life?
Any significant impacts on society or the functionality of people's everyday operations will be largely determined by how quickly the technology is developed to the point where it becomes commercially available, cost effective, and accessible to potential users, but the simplest notable effects upon integration and application will eventually be that computing speed and capacity will be tremendously enhanced, and communications transmission and reception will be more reliable and happen much faster, especially when passing through materials resistant to radio waves and over great distances like those across Astronomical spaces, but I wouldn't expect any of that to be ready by the end of the week.