This abstract encapsulates an exploration into the innovative potential of harnessing sparks and tungsten electrodes to generate energy akin to nuclear fission. Utilizing a mere 100,000 sparks, powered by just 2 tungsten electrodes and a 500,000-watt supply, this approach yields an impressive 3,121 MeV, signaling a substantial reduction in energy consumption compared to traditional methods. Furthermore, this research proposal reveals the ingenious workings of a machine that employs alternating current (AC) waveforms and an electromagnetic cavity chamber to create a focused electron beam, promising the controlled initiation of nuclear fission reactions with remarkable efficiency. This innovative approach presents an alluring solution to the worldâ\euro™s escalating energy needs, underpinned by a profound understanding of the machineâ\euro™s unique capabilities.

The SyncFusion Amplifier is introduced as an innovative electronic component designed to redefine security in IoT devices. Principles inspired by quantum entanglement are leveraged to establish synchronized correlations between input signals, resulting in amplified and coherent outputs. The behavior, validation, and potential applications of the amplifier are demonstrated using QSPICE simulation and a hierarchical entry block with C++ code. Through detailed analysis, the enhancement of correlated behaviors by the SyncFusion Amplifier is showcased, with applications in cryptography and communication. By generating more robust cryptographic keys and secure communication channels, security vulnerabilities in IoT environments are addressed. The research not only unveils a groundbreaking electronic component but also proposes a paradigm shift in IoT security. As the IoT landscape continues to expand, a timely solution is presented by the SyncFusion Amplifier to fortify data protection, communication integrity, and overall device security.

This research introduces a pioneering approach in quantum computing that harnesses the fundamental principles of the Mobius strip to store and preserve the state of qubits. Leveraging the capabilities of quantum gates and entanglement, a custom quantum circuit is designed and implemented using the Qiskit framework. Through rigorous experimentation, the circuit successfully emulates the behavior of a Mobius strip, ensuring the enduring preservation of stored information. The devised methodology encompasses the creation of a quantum circuit comprising an input qubit and an output qubit. The initial state of the input qubit is determined by user input, setting the foundation for subsequent operations. By skillfully applying specialized gates and entanglement operations, the circuit faithfully represents the unique characteristics of the Mobius strip. Crucially, the output qubit’s state is measured, unveiling the resultant information encoded within. The experimental findings unequivocally establish the circuit’s unrivaled ability to steadfastly preserve information, irrespective of the number of iterations. Each execution yields the desired output, substantiating the efficacy of the bespoke gate arrangement in storing and upholding qubit states. This seminal research not only underscores the immense potential of integrating non-trivial mathematical concepts, exemplified by the Mobius strip, into quantum computing but also opens up unprecedented vistas for information storage and manipulation. The preservation of qubit states within the circuit paves the way for cutting-edge advancements in diverse quantum algorithms and applications. By seamlessly embodying the principles of scientific inquiry, this study serves as a trailblazing foundation for future explorations in the burgeoning field of quantum computing.

I propose a new semiconductor device capable of switching between ground or resistance. I use 2 electrodes Anode and Gate respectively. The gate is used to turn the component into a resistor, and without gate voltage, it's a normal ground element. In this paper, we will look at the results of the simulation obtained with Visual TCAD. Every circuit requires a ground element and usually, it's used to complete the circuit, this component acting as a resistor can save some electrons from grounding and we will use these electrons to provide an alternate path so they can flow through a different branch of the circuit this can save from power loss and every little current can be used in some way.

In this paper we will discuss about a new data structure suitable for Quantum Computing, A new data format called Cdata and how it is used to collect a chaotic systems data and feed into our Non-EuStructure using a four dimensional object to store current and past values and storing them into qubits and how we can use quantum mechanical properties such as superposition and entanglement to easily achieve such complex storing and computing of chaotic systems. First we will look at our Cdata and how it compares to JSON then I will explain the Non-EuStructure data structure and how the flow and storage takes place. After we will take a look at the architecture of Non-EuStructure. We will closely look at Equations and Circuit combinations to achieve our goal.

A document by Usama Thakur. Click on the document to view its contents.

A document by Usama Thakur. Click on the document to view its contents.