QNDX has designed a stable, scalable, fault-tolerant, error-controlled quantum computer.

Our technology advances superconductivity, high carrier mobility, spin qubits, one-dimensionality, and scalability, eliminating the need for complex cryogenic systems and enabling faster gate operations.

Carbon Nanotubes (CNTs) and Boron Nitride Nanotubes (BNNTs) for Qubit Advancement

 Our research is dedicated to exploring Carbon Nanotubes (CNTs) and Boron Nitride Nanotubes (BNNTs) as promising platforms for producing stable and scalable qubits, the fundamental units of quantum computation.

We are pioneering methods for the controlled production of high-purity CNTs and BNNTs with characteristics tailored for qubit applications. Our work involves precisely positioning and manipulating these nanostructures to create well-defined qubit architectures. Achieving such precision is essential for attaining the control and coherence necessary for robust quantum computing.

 Our projects using A.I. and machine learning, focus on optimizing material properties, predicting complex systems, and accelerating the design of next-generation technologies in fields such as quantum computing, energy storage, materials science and biomedical engineering.  

Healthcare Innovation

Solving complex problems in a fraction of the time, leading to faster drug discovery, quicker material design, and optimized solutions across various fields. Analyzing intricate molecular interactions, like receptor-ligand binding sites, with unparalleled accuracy. 

Applications include simulating the interaction between the spike protein and the ACE2 receptor in all its possible mutant forms to design more effective drugs with higher binding affinity and specificity to accelerate the development of new therapies against SARS-CoV-2 and future virus strains.

Revolutionizing DNF with AI for Precision Intervention and Therapies

DNF, a highly effective and efficient form of neurofeedback, disrupts stuck brainwave patterns associated with conditions like anxiety, PTSD, TBI, and chronic pain.

Through advanced machine learning,  DNF for each patient is targeted. Imagine vast amounts of DNF data analyzed to create individualized treatment plans. This translates to optimized signal strength, targeted interventions for specific brainwave patterns, and a more effective and personalized experience. AI allows for real-time analysis of brain activity during DNF sessions. This enables adjustments to the feedback signal, ensuring the most efficient disruption of stuck patterns, leading to faster symptom reduction. 

By identifying precise brainwave data linked to specific conditions, QNDX targets DNF protocols.

 Science & Engineering

Designing novel materials with superior strength, conductivity, and efficiency drives advancements in energy, electronics, and aerospace. 

Carbon Nanotubes (CNTs) have potential beyond mere material reinforcement, including applications in next-generation transistors, transparent conductors, advanced sensors for medical diagnostics and environmental monitoring, and high-performance electrodes for batteries and supercapacitors. 

Boron Nitride Nanotubes (BNNTs) offer unique advantages in specific material science applications. High-temperature composites with BNNTs exhibit superior thermal and chemical stability, making them ideal for reinforcing materials in harsh environments, such as jet engines. Their excellent insulating properties are valuable for electrical applications requiring efficient heat dissipation. Additionally, BNNTs can be used to create membranes for highly selective filtration processes due to their unique pore structure.

While CNTs have a broad range of established uses due to their diverse electrical properties, BNNTs excel in scenarios demanding exceptional chemical stability and thermal resistance.

Geospatial

 Developing more accurate climate models to predict and combat the effects of global warming and prepare for natural disasters with real-time data analysis and resource allocation.

Agriculture

Maximizing crop yields with personalized optimization based on individual field conditions, developing disease-resistant strains through advanced modeling, and managing resources responsibly for sustainable and high-yield agriculture.

 QNDX-Changing the Landscape of Quantum Computing

Imagine the possibilities if we could harness the principles of quantum mechanics to model and simulate the intricate behavior of matter at its most fundamental molecular level. Achieving this would not only be transformative but also reshape our entire understanding of science and revolutionize our approach to uncovering the mysteries of nature.

On the forefront of transformative technologies, quantum computers emerge as promising entities. Amidst this potential lies a series of unanswered questions: How can we construct a quantum machine adept at tackling significant and practical problems? How do we successfully scale it to encompass thousands of qubits while maintaining precise control over delicate quantum states and shielding them from external influences? How do we innovate a utility-scale quantum computer that no longer relies on supercooling and boasts a small physical and carbon footprint? These pressing questions steer the ongoing research at QNDX.

The Hub of Innovative Technologies

Strategically positioned in St. Louis, Missouri, QNDX brings quantum research to the forefront of innovation in this dynamic city. St. Louis offers abundant resources for tech innovators and entrepreneurs, establishing itself as a frontrunner in innovation. The city's prominence is further emphasized by its wealth of tech talent, a key consideration in BizCosts ranking St. Louis as the foremost U.S. hub for artificial intelligence expertise, particularly in the banking and financial sectors.

Transforming Vision into Action

Since 2021, we have embarked on our journey to develop a fault-tolerant, 100,000 qubit, quantum computer.  QNDX pushes the boundaries of quantum R&D, manufacturing and testing quantum processors and scaling technologies.

Advancing Qubit Technology at QNDX 

At QNDX, our emphasis lies in controlling and positioning qubit entanglement, which is pivotal for quantum computing power.  We explore novel, qubit architectures and QEC.
Our design yields qubits with a reduced error rate and scalability.

Revolutionizing the Quantum Landscape

QNDX aims to deliver a utility-scale 100,000 qubit quantum computer capable of executing reliable computations beyond the capacities of any classical computing or existing quantum computing technology.