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From theoretical physics to next-generation algorithms, Blake Burns Technologies Inc. is redefining the boundaries of innovation.
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A selection of our publications and theoretical explorations.
An Exhaustive Theoretical and Phenomenological Analysis of Geometrically-Induced Mass Variation (GIMV)
Our latest research provides an exhaustive theoretical and phenomenological analysis of the Geometrically-Induced Mass Variation (GIMV) framework. This internally consistent theory posits that a particle's fundamental mass is not a fixed constant, but a dynamic property that can change in response to extreme gravitational environments. The analysis confirms GIMV is a viable "strong-field-only" phenomenon ; its effects are negligible and shielded in terrestrial settings but become dominant in the intense gravity near compact objects like neutron stars. This new understanding has profound implications for physics, predicting novel phenomena such as "Geometrically-Induced Fission" (GIF)—a new way for atomic nuclei to split.
Read PaperThe Unification of Gravity and Mass Generation via Six-Dimensional Vector-Time: Theory, Constraints, and Phenomenological Signatures
This research presents the Six-Dimensional Vector-Time (6DT) framework, a unified field theory proposal that extends standard spacetime with a local three-dimensional internal time vector coupled directly to gravitational tidal curvature. By employing an $SO(3)$ gauge symmetry to preserve unitarity, the theory establishes "Stoke Power" as a dynamical principle where geometric forces drive variations in invariant rest mass, formalized as Geometrically-Induced Mass Variation (GIMV). While consistent with stringent terrestrial constraints via a "Viability Gulf" in curvature scales, 6DT predicts novel phenomena in extreme astrophysical regimes—such as a "Dynamic Valley of Stability" and "Geometrically-Induced Fission" in neutron stars—and proposes definitive experimental tests using optical atomic clocks to detect unique sidereal-annual sidebands.
Read PaperA 6DT-Stoke Framework for Geometrically-Induced Mass Variation (GIMV): Formalism and Application to Nuclear Stability
Our latest research paper introduces Geometrically-Induced Mass Variation (GIMV), a new theoretical framework developed from our work on 6DT-Stoke unification. This paper challenges the long-held assumption that a particle's mass is a fixed, fundamental constant. We propose that the mass of a nucleon (a proton or neutron) is dynamic and can be altered by the local gravitational tidal field. This has profound consequences for nuclear physics, suggesting that the "valley of stability" for elements is not static but environment-dependent. The paper formalizes this concept and presents its most dramatic prediction: "Geometrically-Induced Fission" (GIF) , a novel mechanism where an extreme tidal field—such as those in a kilonova—could cause an otherwise stable nucleus to spontaneously fission. We demonstrate that this theory is fully consistent with all known terrestrial experiments while offering a new, high-impact phenomenon for extreme astrophysical environments.
Read PaperA Vectorized Time Model in a 6D Spacetime: 6DT
This paper introduces 6DT, a speculative model where time is a three-component vector. It explores how this "vector time" couples with spatial dimensions based on gravitational potentials, derives geodesic equations, and maps the resulting effects to the Standard Model Extension to test for Lorentz violation.
Read PaperA Relativistic Test of the 6DT Spacetime Framework
This report proposes a practical, ground-based experiment to test the 6DT framework. It details using a long-baseline, phase-stabilized link between two optical atomic clocks to measure boost-dependent anisotropy, leveraging Earth's orbital motion to probe the model's unique kinematic predictions.
Read PaperDeveloping 6DT and directional time theory: A framework and notes
We derive the complete 6D Einstein field equations for static matter sources and construct a comprehensive, single-parameter Bayesian global-fit pipeline. This pipeline maps the model’s predictions onto the well-established Standard-Model Extension (SME) to enable statistically robust constraints on the theory's free parameter, $\epsilon$, using data from astrophysical timing, solar system ephemerides, and terrestrial atomic clock experiments. This work provides the complete theoretical and experimental roadmap necessary for the validation—or falsification—of the 6DT model.
Read PaperImplications of Stoke's Momentum-Acceleration Relationship
This paper explores the "Stoke" equation, a novel relationship between momentum and its rate of change. It applies this concept as an analytical tool to examine complex phenomena, including black hole dynamics, Hawking radiation, dark matter distributions, and the accelerating expansion of the universe.
Read PaperThe Stoke-6DT Framework: Analysis of Anomalous Power in a Six-Dimensional Vector-Time Manifold
Our foundational new paper, "The Stoke-6DT Framework," details a major theoretical breakthrough from Blake Burns Technologies Inc.. This work unifies our proprietary "6DT" (six-dimensional vectorized time) model with the "Stoke" power concept. The resulting synthesis provides a rigorous mathematical proof that mass and energy can be directly exchanged between our familiar 4D spacetime and a higher-dimensional "bulk". This dynamic framework provides a microphysical origin for previously unexplained phenomena, offering a candidate mechanism for the anomalous heating observed in astrophysical plasmas. By defining new, testable experimental observables—including anomalous power, anomalous forces, and modified tidal effects—this paper transforms the 6DT model into a multifaceted physical theory, paving the way for a new generation of precision experiments.
Read PaperDarksort: A New Linear Sorting Algorithm
This paper presents "Darksort," a novel, non-comparison sorting algorithm for integers. It details the algorithm's operation, which achieves O(n) linear time and space complexity, and provides comparisons to other linear sorting algorithms like Counting Sort and Radix Sort.
Read PaperModeling in a 2^N Binary Feature Space
This work explores a modeling technique using a finite set of N binary features, which defines a 2^N state space. It details how a lookup structure for this space can store evaluations to predict outcomes in diverse applications like stock market analysis, system configuration, and game theory.
Read PaperTowards Unhackable Computing
This paper provides a critical examination of modern cybersecurity, analyzing the foundational weaknesses that make systems "hackable." It covers threats from OS-level trust issues and malware to network vulnerabilities and the future challenge of quantum computing.
Read PaperAbout Our Approach
Founded by researcher Blake Burns, Blake Burns Technologies Inc. operates at the intersection of theoretical science and applied technology. We believe that the most significant breakthroughs come from a deep, first-principles understanding of complex systems.
Our work is driven by curiosity, rigor, and a commitment to solving foundational problems. Whether we are exploring the structure of spacetime, designing new computational algorithms, or hardening digital infrastructures, our goal is to build a more capable and secure future.
Let's Collaborate
We are always interested in new challenges and collaborations. If you have a complex problem or an idea you'd like to discuss, please get in touch.
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