Kyle Clouthier
Independent computational materials researcher specializing in aperiodic materials discovery using proprietary methodologies. Based in Petawawa, Ontario, Canada. Developed systematic discovery platform for novel quantum materials beyond 230 periodic space groups. Platform validated with ReOsSSe₂ (FREE demonstration material) and FeTeSe (patent-pending topological superconductor). Materials available for evaluation licensing.
Independent Materials Discovery
Platform Overview
Systematic aperiodic materials discovery platform accessing infinite design space beyond 230 periodic crystal structures. AI-assisted target identification + custom .CIF engineering + DFT+SOC validation.
Trade Secret Methodology: Proprietary FIQS (Fractal-Irrational Quantum Seed) algorithm enables discovery of materials with zero prior literature. Methodology protected as trade secret—not disclosed in publications or patents.
Independent Advantage: Full IP ownership. Direct industry licensing. Agile development without institutional constraints. Proven track record with DFT-validated discoveries.
Platform Validation
ReOsSSe₂: FREE demonstration material proving platform capabilities. First Re-Os heterometallic 2D material—Type-II Dirac semimetal with 73 Dirac points (36× more than graphene), 688.5 meV Rashba splitting (highest reported for 2D materials), and exceptional thermodynamic stability (ΔE = -3.58 eV).
Complete DFT+SOC dataset freely available under MIT License. Demonstrates platform's ability to discover materials with zero prior literature and validate through first-principles calculations.
Commercial Offerings
FeTeSe: Patent-pending aperiodic topological superconductor (filing November 2025). First computationally-designed aperiodic topological SC validated through DFT relaxation. Evaluation licenses available ($35K) with complete dataset, synthesis protocols, and 6-month exclusivity.
Additional discoveries in progress across topological materials, magnetic systems, and functional materials. Compositions confidential until patent filing.
ReOsSSe₂: First Re-Os Heterometallic 2D Material
Type-II Dirac semimetal validating aperiodic discovery platform. Complete DFT+SOC dataset freely available under MIT License.
Breakthrough Results
Revolutionary Applications
ReOsSSe₂ discovery validates the aperiodic materials discovery platform—proving systematic discovery of materials with zero prior literature using proprietary FIQS methodology and rigorous DFT+SOC validation. Computational discovery completed October 2025. Complete dataset freely available under MIT License as platform demonstration.
Revolutionary Achievements
ReOsSSe₂ Platform Demo
First Re-Os heterometallic 2D material. 73 Dirac points (36× graphene), 688.5 meV Rashba splitting (highest reported for 2D materials), thermodynamically stable Type-II Dirac semimetal. Complete DFT+SOC dataset freely available under MIT License.
FeTeSe Patent-Pending
First computationally-designed aperiodic topological superconductor validated through DFT relaxation. Patent filing November 2025. Evaluation licenses ($35K) include complete dataset, synthesis protocols, 6-month exclusivity.
Independent Advantage
Full IP ownership enables direct industry licensing and agile development. Proprietary methodologies using Quantum ESPRESSO on high-performance compute infrastructure. Trade secret protection without publication constraints.
DFT+SOC Validation
Advanced first-principles calculations with spin-orbit coupling, noncollinear magnetism, Wannier90 topological analysis, and custom k-point optimization. All discoveries validated through rigorous computational methods.
Aperiodic Discovery Platform
Proprietary FIQS methodology discovers materials with zero prior literature beyond 230 periodic space groups. Infinite design space inaccessible to database approaches. Additional discoveries in progress, compositions confidential.
Commercial Licensing Model
Platform approach with proven track record. ReOsSSe₂ FREE demonstration validates capabilities. FeTeSe available for evaluation licensing ($35K). Additional discoveries in progress, compositions confidential until patent filing.
Research Focus Areas
Platform validated with ReOsSSe₂ (FREE demonstration) and FeTeSe (patent-pending topological superconductor). Ongoing research explores multiple pathways in aperiodic materials discovery—from room-temperature magnets to advanced topological systems. Each discovery undergoes rigorous DFT+SOC validation.
Magnetic Materials
Exploring V-Cr and other transition metal compositions for perpendicular magnetic anisotropy and high Curie temperatures
Topological Systems
Heterometallic TMDs featuring multiple Dirac points and strong spin-orbit coupling for topological quantum computing applications
Rashba Materials
Designing Janus structures with record-breaking Rashba splitting for spintronic applications
Methodology Development
Refining proprietary DFT+SOC workflows for rapid screening and validation of novel quantum materials
Research Impact: Commercial Applications
ReOsSSe₂ demonstrates 688.5 meV Rashba splitting (highest reported for 2D materials) and 73 Dirac points enabling transformative applications in room-temperature quantum computing, topological transistors, and advanced spintronics. FeTeSe patent-pending topological superconductor opens quantum computing applications. Both materials validate proprietary FIQS discovery methodology.
🚀 Commercial Opportunities
Platform validated with two breakthrough materials: ReOsSSe₂ (FREE demo) demonstrates 688.5 meV Rashba splitting (highest for 2D materials) and 73 Dirac points enabling room-temperature spintronics and topological quantum computing. FeTeSe (patent-pending) offers aperiodic topological superconductor for quantum computing applications. Proprietary FIQS methodology proves systematic discovery capabilities. ReOsSSe₂ complete dataset freely available under MIT License.
Technical Expertise
Independent computational materials researcher specializing in aperiodic materials discovery. Proprietary FIQS methodology developed through rigorous self-study and DFT+SOC validation. Platform proven with ReOsSSe₂ (FREE) and FeTeSe (patent-pending). Additional discoveries in progress.
Professional Opportunities
Proven track record with DFT-validated discoveries. FeTeSe evaluation licenses available ($35K). ReOsSSe₂ FREE demonstration dataset validates platform capabilities.
FeTeSe Evaluation Licensing
Patent-pending aperiodic topological superconductor. $35K evaluation license includes complete DFT dataset, synthesis protocols, 6-month exclusivity. Patent filing November 2025.
Professional InquiryReOsSSe₂ FREE Demonstration
Complete DFT+SOC dataset freely available under MIT License. First Re-Os heterometallic 2D material. 688.5 meV Rashba splitting (highest for 2D materials), 73 Dirac points. Platform validation material.
Professional Inquiry