According to our current understanding of quantum mechanics, particles can indeed be entangled with each other regardless of their composition or location on Earth. Entanglement is a fundamental concept in quantum physics, describing a state in which two or more particles become correlated in such a way that the state of one particle is dependent on the state of the other(s), even when they are physically separated.
The entanglement of particles has been experimentally observed and studied extensively in various systems, including atoms, photons, and other elementary particles. These particles can be made from different materials and exist in different locations, yet they can still exhibit entanglement.
However, it is important to note that entanglement is a delicate and fragile phenomenon. The entangled state can easily be disrupted by interactions with the environment or other particles, causing the entanglement to be lost or "decohered." Therefore, maintaining and manipulating entanglement over large distances or with macroscopic objects is extremely challenging due to the effects of decoherence.
Nonetheless, within controlled laboratory settings, entanglement can be created and observed between particles of various types and from different locations on Earth. The principles governing entanglement are not dependent on the material or location of the particles but are instead rooted in the fundamental properties of quantum mechanics.