To help you understand how it is possible to create transmiters and receivers with infinite range and transmit information instantaneosly, please read this quote from Wikipedia on quantum entanglement.
"Quantum entanglement is a quantum mechanical phenomenon in which the quantum states of two or more objects are somehow linked together so intimately that one object cannot be adequately described without full mention of its counterpart - even though the individual objects may be spatially separated. This interconnection leads to correlations between observable physical properties of remote systems. For example, quantum mechanics holds that states such as spin are indeterminate until such time as some physical intervention is made to measure the spin of the object in question. It is equally as likely that any given particle will be observed to be spin-up as that it will be spin-down. Measuring any number of particles will result in an unpredictable series of measures that will tend more and more closely to half up and half down. However, if this experiment is done with entangled particles the results are quite different. When two members of an entangled pair are measured, one will always be spin-up and the other will be spin-down. The distance between the two particles is irrelevant. In order to explain this result, some have theorized that there are hidden variables that account for the spin of each particle, and that these hidden variables are determined when the entangled pair is created. However, there is no experimental evidence to support the existence of such hidden variables; to the contrary, the Bell inequalities indicate that there can be no such hidden variables. People who believe that there can be no hidden variables to account for this phenomenon are left with the implication that what was not determined earlier when the two particles interacted directly must then be determined at the time when one particle's spin is measured while the two are remote from each other. The reason is that once one particle's spin is measured the other particle's spin will invariably turn out to be the opposite of the spin of the first.
Measurements performed on one system thus seem to be instantaneously influencing other systems entangled with it. But quantum entanglement does not enable the transmission of classical information faster than the speed of light. (See discussion in next section below/.)
Quantum entanglement has applications in the emerging technologies of quantum computing and quantum cryptography, and has been used to realize quantum teleportation experimentally. At the same time, it prompts some of the more philosophically oriented discussions concerning quantum theory. The correlations predicted by quantum mechanics, and observed in experiment, reject the principle of local realism, which is that information about the state of a system should only be mediated by interactions in its immediate surroundings and that the state of a system exists and is well-defined before any measurement. Different views of what is actually occurring in the process of quantum entanglement can be related to different interpretations of quantum mechanics. In the standard one, the Copenhagen interpretation, quantum mechanics is neither "real" (since measurements do not state, but instead prepare properties of the system) nor "local" (since the state vector comprises the simultaneous probability amplitudes for all positions, e.g. )."
Basically, this means we can buld transmiters / receivers that use quantum entanglement to transmit / receive information through space instantaneously, which is much faster than the speed of light, jk. It does not matter how far apart these objects are. Vibrating one object results in vibrating the other objects instantly that are connected by quantum entanglement.
If one object is vibrated and results in vibrating the other objects just as much, then energy was created through quantum entanglement. The traditional view of energy-in - energy-out to explain simple physics does not account for how the energy got there in the first place. Therefore, it's an incomplete picture of the real universe. Maybe not enough energy to be significant, but it's still something worth knowing to be able to fully explain everything.
We can also transmit energy instanteously in the same way over any distance, which means that the parts of a quantum computer could be spread across the entire universe and function with infinite processing ability and energy could be sent back home by quantum entanglement instantly by a probe shot into a nearby star. It also means that other intelligent beings, if they actually exist and use quantum entanglement to transmit and receive information, can communicate with us instantly over any distance in the universe.
