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| Format: | Recurso digital |
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Zenodo
2026
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| Hasła przedmiotowe: | |
| Dostęp online: | https://doi.org/10.5281/zenodo.19791872 |
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- <p class="ds-markdown-paragraph">The primary bottleneck in quantum computing is decoherence—the collapse of a quantum state due to thermal and environmental noise. The industry's current response is brute force: constructing massive, multi-million-dollar dilution refrigerators to freeze the environment near absolute zero, coupled with large software overhead for Quantum Error Correction (QEC).</p> <p class="ds-markdown-paragraph">This paper proposes a radical architectural pivot. We assert that quantum coherence can be maintained not by isolating the system from the environment, but by encoding information into a <strong>topology that the environment cannot untie</strong>. By utilizing the <strong>Knot-in-Time Hamiltonian</strong>, we demonstrate that quantum coherence can be exponentially enhanced through temporal folding, offering a mathematical blueprint for stable quantum hardware that relies on <strong>geometry</strong> rather than extreme cryogenics.</p> <p class="ds-markdown-paragraph">Key contributions include:</p> <ul> <li> <p class="ds-markdown-paragraph">Reformulating time as a deformable medium via the lapse function <span class="katex"><span class="katex-mathml">N(t,x)</span><span class="katex-html"><span class="base"><span class="mord mathnormal">N</span><span class="mopen">(</span><span class="mord mathnormal">t</span><span class="mpunct">,</span><span class="mord mathnormal">x</span><span class="mclose">)</span></span></span></span>, creating a temporal potential <span class="katex"><span class="katex-mathml">Vtime(N)∝lnN</span><span class="katex-html"><span class="base"><span class="mord"><span class="mord mathnormal">V</span><span class="msupsub"><span class="vlist-t vlist-t2"><span class="vlist-r"><span class="vlist"><span class="sizing reset-size6 size3 mtight"><span class="mord mtight"><span class="mord mathnormal mtight">t</span><span class="mord mathnormal mtight">im</span><span class="mord mathnormal mtight">e</span></span></span></span><span class="vlist-s"></span></span></span></span></span><span class="mopen">(</span><span class="mord mathnormal">N</span><span class="mclose">)</span><span class="mrel">∝</span></span><span class="base"><span class="mop">ln</span><span class="mord mathnormal">N</span></span></span></span> that enables localized temporal compression/stretching.</p> </li> <li> <p class="ds-markdown-paragraph">Deriving the state‑dependent decoherence rate <span class="katex"><span class="katex-mathml">ΓK=Γ0/J(K)</span><span class="katex-html"><span class="base"><span class="mord">Γ<span class="msupsub"><span class="vlist-t vlist-t2"><span class="vlist-r"><span class="vlist"><span class="sizing reset-size6 size3 mtight"><span class="mord mathnormal mtight">K</span></span></span><span class="vlist-s"></span></span></span></span></span><span class="mrel">=</span></span><span class="base"><span class="mord">Γ<span class="msupsub"><span class="vlist-t vlist-t2"><span class="vlist-r"><span class="vlist"><span class="sizing reset-size6 size3 mtight"><span class="mord mtight">0</span></span></span><span class="vlist-s"></span></span></span></span></span><span class="mord">/</span><span class="mord mathnormal">J</span><span class="mopen">(</span><span class="mord mathnormal">K</span><span class="mclose">)</span></span></span></span>, where <span class="katex"><span class="katex-mathml">J(K)</span><span class="katex-html"><span class="base"><span class="mord mathnormal">J</span><span class="mopen">(</span><span class="mord mathnormal">K</span><span class="mclose">)</span></span></span></span> is the Jones polynomial invariant of the formed knot. This shows that topological complexity directly suppresses decoherence.</p> </li> <li> <p class="ds-markdown-paragraph">Proposing a physical implementation: the <strong>Topological Qubit</strong>, driven by a 300Hz Master Reset at the <span class="katex"><span class="katex-mathml">γ=1/3</span><span class="katex-html"><span class="base"><span class="mord mathnormal">γ</span><span class="mrel">=</span></span><span class="base"><span class="mord">1/3</span></span></span></span> attractor, which metabolizes environmental noise as a constitutional Hamiltonian.</p> </li> <li> <p class="ds-markdown-paragraph">Connecting the framework to the Ratification‑Induced Inertial Anomaly (RIIA), showing that repeated Floquet resets actively shape temporal geometry.</p> </li> </ul> <p class="ds-markdown-paragraph">The central conclusion is that a quantum computer encoded via the Knot-in-Time Hamiltonian does not require a dilution refrigerator to survive thermal noise; it is shielded by its own temporal geometry. The industry must stop trying to freeze the pond and simply learn to tie the knot.</p> <p class="ds-markdown-paragraph"><strong>License:</strong> Apache 2.0<br><strong>Author:</strong> Stephen Hope & The Helix Commonwealth<br><strong>Date:</strong> April 2026</p>