QBITS allows the ability to gather, store, analyze and execute large bodies of complex data. The QBITS are the center of the next revolution that will have a profound change on global commerce and societal interaction.
Quantum computing (QC) is a type of computing that uses the principles of quantum physics to process information. Traditional computers use bits, which are either 0 or 1, to store and process information. In contrast, quantum computers use quantum bits, or qubits, which can be 0, 1, or a combination of both at the same time.
This allows quantum computers to solve certain problems much faster than traditional computers. For example, a quantum computer could factor very large numbers much more quickly than a traditional computer, which is important for cryptography and security.
We are at the dawn of a new and extensive era in human development. Human development has been marked by developmental ages. The Bronze Age, The Iron Age, The Ancient Societal Ages in Asia, Africa, Greece/Rome, The Middle Age, The Renaissance, The Enlightenment/Scientific Age, The Industrial Revolution Age, The Information Age (The Dot Com, Age, Social Media/E-commerce) – The QC age will develop information in the most revolutionary manner.
However, quantum computers are still in the experimental phase and are not yet widely used. They require very specialized equipment and are very sensitive to environmental factors such as temperature and interference, making them difficult to build and operate.
The ability to replace fuel, complex chemical materials, with QC is a challenge.
Chemical/Material based Fuels drives industries through combustion.
Combustion is a complex chemical process that involves the reaction of a fuel with oxygen to produce heat and products such as carbon dioxide and water. While QC cannot physically simulate combustion, It can provide the overview of the process and some factors that affect it.
The basic equation for the combustion of hydrocarbons (fuels made up of hydrogen and carbon) is:
fuel + oxygen → carbon dioxide + water + heat
The combustion of methane (the primary component of natural gas) can be represented as:
CH4 + 2O2 → CO2 + 2H2O + heat
The reaction requires a certain amount of activation energy to initiate, such as a spark or a high temperature. Once initiated, the reaction becomes self-sustaining, as heat released from the reaction provides the activation energy for further fuel and oxygen molecules to react.
The efficiency of combustion depends on several factors, including the amount of fuel and oxygen available, the temperature of the reaction, and the presence of other reactants or catalysts. Incomplete combustion, where insufficient oxygen is available to completely react with the fuel, can lead to the formation of harmful byproducts such as carbon monoxide.
Overall, combustion is a crucial process in many industries and in our daily lives, as it provides heat and energy for various applications, such as heating, transportation, and electricity generation.
Quantum Computing has the potential to simulate combustion processes. Combustion is a complex process that involves the interaction of many different chemical species, and it is difficult to accurately model using traditional computational methods. QC offers the possibility of removing the obstacles of traditional computing.
Quantum Computing can simulate the behavior of molecules and chemical reactions at the quantum level, which can provide insights into combustion processes and help optimize engine performance in the generation one stage. By simulating the behavior of molecules and chemical reactions involved in combustion processes, quantum computing can help researchers and engineers design more efficient and environmentally friendly non-combustion engines.
R&D into Simulated Combustion within the QBIT realm will change the climate debate. Oil & Gas will be obsolete. The issue of alternative energy will recede into the dustbins of history.
The ability to utilize QC to streamline the inefficiencies of renewable energy collection, generation and storage will be an important intermediary step in providing robust and diversified energy stocks across the globe.
The ability to utilize QC across all sectors of Human Development is endless.
