Mechanism of Universal Quantum Computation in the Brain  

作　　者：Aman Chawla Salvatore Domenic Morgera Aman Chawla;Salvatore Domenic Morgera(Department of Computer Science and Engineering, Indian Institute of Technology, Delhi, India;Department of Electrical Engineering, University of South Florida, Tampa, USA)

机构地区：[1]Department of Computer Science and Engineering, Indian Institute of Technology, Delhi, India [2]Department of Electrical Engineering, University of South Florida, Tampa, USA

出　　处：《Journal of Applied Mathematics and Physics》2024年第2期468-474,共7页应用数学与应用物理（英文）

摘　　要：In this paper, the authors extend [1] and provide more details of how the brain may act like a quantum computer. In particular, positing the difference between voltages on two axons as the environment for ions undergoing spatial superposition, we argue that evolution in the presence of metric perturbations will differ from that in the absence of these waves. This differential state evolution will then encode the information being processed by the tract due to the interaction of the quantum state of the ions at the nodes with the “controlling’ potential. Upon decoherence, which is equal to a measurement, the final spatial state of the ions is decided and it also gets reset by the next impulse initiation time. Under synchronization, several tracts undergo such processes in synchrony and therefore the picture of a quantum computing circuit is complete. Under this model, based on the number of axons in the corpus callosum alone, we estimate that upwards of 50 million quantum states might be prepared and evolved every second in this white matter tract, far greater processing than any present quantum computer can accomplish.In this paper, the authors extend [1] and provide more details of how the brain may act like a quantum computer. In particular, positing the difference between voltages on two axons as the environment for ions undergoing spatial superposition, we argue that evolution in the presence of metric perturbations will differ from that in the absence of these waves. This differential state evolution will then encode the information being processed by the tract due to the interaction of the quantum state of the ions at the nodes with the “controlling’ potential. Upon decoherence, which is equal to a measurement, the final spatial state of the ions is decided and it also gets reset by the next impulse initiation time. Under synchronization, several tracts undergo such processes in synchrony and therefore the picture of a quantum computing circuit is complete. Under this model, based on the number of axons in the corpus callosum alone, we estimate that upwards of 50 million quantum states might be prepared and evolved every second in this white matter tract, far greater processing than any present quantum computer can accomplish.

关 键 词：AXONS Quantum computation Metric perturbation DECOHERENCE Time-coded information 

分 类 号：O41[理学—理论物理]