An array of entangled particles, often referred to as a quantum entangled system, does not have a visual appearance in the conventional sense. Entanglement is a property that exists at the quantum level, and it does not have a direct analogy in our macroscopic everyday experience.
At the quantum level, particles can be entangled in various ways, and their entangled states are described mathematically using quantum mechanics. The entangled state of a system is represented by a mathematical equation called a wavefunction, which captures the probabilities of different outcomes when measurements are made on the entangled particles.
To give you a sense of how an array of entangled particles might be represented, imagine a hypothetical scenario where you have a set of quantum bits (qubits) that are entangled with each other. In this case, the entangled state of the system would be described by a complex mathematical equation involving all the possible combinations of states for each qubit.
However, it's important to note that the entangled state itself is not directly observable or visualizable. It is a mathematical description that captures the correlations and relationships between the entangled particles. When measurements are made on the entangled particles, the correlations between their outcomes can be observed, but the entangled state itself remains an abstract concept.
In summary, an array of entangled particles does not have a physical appearance, but rather its properties are described through mathematical equations in the framework of quantum mechanics.