Welcome to DEEP VENTURES

 DEEPVENTURES is leveraging mathematics and a new model of quantum mechanics to bring about  innovation across all areas of technology from AI to Fusion.

Deep Ventures is a technology company developing high impact applications of a new model of quantum mechanics. This new model is 7-10 years ahead of current technology which will revolutionize a wide range of industries, including climate, energy, computing, and materials science. 

Because Deep Ventures science is based on fractal mathematics and begins with quantum gravity, it is applicable across most of commerce.

Deep Ventures has a dedicated team of young, experienced scientists and engineers who are experts in their respective fields. This team has a deep understanding of their areas of specialty as well as expertise commercializing new technologies.

Deep Ventures has a strong intellectual property portfolio that protects its new model of quantum mechanics and other proprietary technologies nationally and internationally. 

1. Initial Areas of Focus

Categorization in Big Data: Deep Ventures is pioneering advancements in categorization techniques across various industries, leveraging the fractal nature of data to break down complex systems into their constituent components. By harnessing the power of fractal analysis, we can gain deeper insights and more precise categorization in areas such as chemistry, biology, and beyond.

AI: 

The broad Technical Objective is to use fractals with data science to modify AI software to maximize the accessibility, organization, and value of empirical data and to allow this data to be used along with fractal modeling to predict chemical and biological functions. The goal is to have more fully defined fractal categorization applicable to chemistry and biology.

Deep Ventures provides a fractal model applicable across energy, atomics, chemical and biological systems, categorizing data from the sub-atomic through the molecular systems up to and including complex biological systems and astronomic features allowing data across those areas to be categorized using the same modeling.

This is a key algorithm for AI processes which might be compared to having the only store selling pans to gold miners for large and small customers from universities to google and Bing.

Chemistry: Deep Ventures' research in categorization enables a better understanding of the structure and behavior of chemical compounds. By breaking down complex molecules into their fractal components, we can analyze their properties and interactions more effectively. This has significant implications for drug discovery and development, as it can lead to the identification of new compounds and more targeted therapies. The advancements in categorization can contribute to the development of new drugs and treatments for various diseases, ultimately impacting the healthcare industry.

Biology: The fractal nature of biological systems presents immense opportunities for categorization and analysis. Deep Ventures' technologies enable a deeper understanding of the structure and function of biological molecules, such as proteins and DNA. By categorizing and analyzing these molecules at a fractal level, we can uncover crucial insights into their behavior, interactions, and potential therapeutic targets. This can drive advancements in personalized medicine, precision therapies, and the development of new treatments for diseases.

Healthcare Market: The healthcare market is a significant sector that stands to benefit from Deep Ventures' advancements in categorization. With an estimated value of 8.4trillionin2018,growingto11.9 trillion by 2022, the healthcare industry is constantly seeking innovative solutions to improve patient outcomes and reduce costs. Deep Ventures' technologies can contribute to this by enabling more accurate categorization of patient data, leading to better diagnosis, treatment selection, and overall healthcare management. This can result in improved patient care, reduced medical errors, and more efficient resource allocation.

A more complex and expensive undertaking, Deep Ventures is developing new technologies which will lead to the development of fusion reactors where others are failing. Deep Ventures is the only company in this space which has identified and is actively pursuing post-fusion energy sources.

Fusion: 40T; 439B in 2030, 840B by 2040 (seekingalpha.com)

Fusion is a process that powers the sun and other stars, but its potential extends beyond just energy production. The failure to recognize the impact of fractal design within the universe has limited our understanding of post-fusion energy and its significance. By utilizing fractal modeling, we can delve deeper into the fundamental underpinnings of the universe and expand the impact of science in physics and chemistry.

Fractal modeling encompasses the principles of physics and chemistry, allowing us to reconcile empirical knowledge with fractal principles. This comprehensive approach will not only accelerate fusion research but also lead to advancements in various scientific disciplines. It will provide better insights into atomic and molecular structures, bonding, stellar phenomena, plasma physics, high-energy physics, isotope production, and nanoscale atomic and molecular design. These advancements will have far-reaching implications for fields such as materials science, solar energy, hydrogen fuel cells, and more.

The benefits of successful fusion research go beyond energy production. Fusion has the potential to address critical global challenges, including mitigating climate change, enhancing energy security, advancing our understanding of the universe, and promoting scientific innovation in physics and chemistry. While fusion research is complex and challenging, the rewards for humanity and the scientific community make it a worthy and compelling pursuit.

Moreover, the incorporation of transitional geometries and structures, as outlined in patents filed by the primary investigator, into fusion modeling is expected to reduce costs and shorten the time required for economical fusion. This breakthrough will bring the trillion-dollar fusion market within reach. Additionally, these superior designs will improve our understanding of material degradation and transitions under extreme reactor conditions, leading to the development of more resilient materials and components. This will enable the design of reactors with enhanced durability and pave the way for future fusion devices that utilize fractal science to achieve commercial fusion.

In conclusion, fractal modeling holds immense potential for advancing fusion research and expanding our understanding of the universe. The anticipated benefits include not only clean and abundant energy, mitigating climate change, and energy security but also advancements in physics, chemistry, materials science, and related fields. The incorporation of fractal principles into fusion modeling has the potential to revolutionize the fusion industry, making it economically viable and opening up a trillion-dollar market.