The concept you're describing, where a computer is driven by its own electrons without the presence of free electrons, is not feasible based on our current understanding of electronics and computing.
In conventional computers and electronic devices, the flow of electrons through conductive materials is crucial for their operation. The manipulation and control of electrons' movement enable the processing, storage, and transmission of information. Free electrons, typically present in conductors or semiconductors, play a fundamental role in electrical circuits.
To create a functional computer or measuring tool, you need a reliable means to control and manipulate the flow of electrons. This control is achieved through the use of conductive materials and electronic components, such as transistors, which rely on the movement of electrons to perform logical operations and computations.
While there have been advancements in alternative computing technologies, such as quantum computing, neuromorphic computing, or optical computing, all of them still rely on the manipulation of physical quantities, including electrons, photons, or other particles, to perform computational operations.
It's important to note that the behavior of electrons is governed by the laws of quantum mechanics, which introduces fundamental limitations and uncertainties. Quantum effects, such as superposition and entanglement, can be exploited in specific contexts, but they do not eliminate the need for the presence and control of electrons.
Therefore, the concept of a computer or measuring tool driven by its own electrons without free electrons is not currently achievable or consistent with our understanding of computing principles. The movement and manipulation of electrons are essential for the functioning of electronic devices, and alternative approaches would need to conform to these established principles.