Dynamic Rotational Solar Habitats (DRSH): A Conceptual Framework for Adaptive Renewable Energy Systems in the AI and Emerging Computational Era

/ Registration: 2601124243939

01/12/2026

2601124243939

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The Dynamic Rotational Solar Habitat (DRSH) is an original conceptual framework for next-generation renewable energy systems that integrate light concentration, rotational dynamics, and thermal regulation within a single, self-regulating architecture. Drawing inspiration from planetary energy balance and greenhouse thermodynamics, the DRSH employs a transparent optical shell, internal photovoltaic collectors, and phase-change thermal buffers to maintain a state of photonic–thermal equilibrium.

Unlike conventional static solar arrays, the DRSH operates as a dynamic, magnetically levitated structure capable of equalising solar exposure and reducing energy loss through optical recycling and adaptive feedback control. Preliminary analytical modelling under high-irradiance conditions (≈2500 kWh/m² per year) suggests potential solar conversion efficiencies approaching 53.6%, representing an estimated 34% improvement over high-efficiency multi-junction photovoltaics.

The concept proposes a new class of adaptive, self-regulating renewable infrastructures designed to support the escalating energy demands of artificial intelligence, data centres, and emerging quantum computing systems, offering a pathway toward sustainable, intelligent energy ecosystems.

Note: This manuscript presents an original conceptual framework based on theoretical analysis and publicly available scientific principles. It does not describe, endorse, or report on any existing physical implementation. All data, figures, and simulations are illustrative of potential outcomes under idealised conditions.

DOI: 10.5281/zenodo.18220647

Technical

phase-change materials

greenhouse physics

adaptive solar systems

renewable energy

computational sustainability

quantum computing energy demand

energy ecology

magnetic levitation

intelligent energy systems

optical energy recycling

hybrid photovoltaic–thermal

solar energy systems

ai data centres

sustainable infrastructure

dynamic rotational solar habitat

biomimetic design

rotational photovoltaics

radiative cooling

self-regulating energy architecture

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Title Dynamic Rotational Solar Habitats (DRSH): A Conceptual Framework for Adaptive Renewable Energy Systems in the AI and Emerging Computational Era
Description:
The Dynamic Rotational Solar Habitat (DRSH) is an original conceptual framework for next-generation renewable energy systems that integrate light concentration, rotational dynamics, and thermal regulation within a single, self-regulating architecture. Drawing inspiration from planetary energy balance and greenhouse thermodynamics, the DRSH employs a transparent optical shell, internal photovoltaic collectors, and phase-change thermal buffers to maintain a state of photonic–thermal equilibrium.

Unlike conventional static solar arrays, the DRSH operates as a dynamic, magnetically levitated structure capable of equalising solar exposure and reducing energy loss through optical recycling and adaptive feedback control. Preliminary analytical modelling under high-irradiance conditions (≈2500 kWh/m² per year) suggests potential solar conversion efficiencies approaching 53.6%, representing an estimated 34% improvement over high-efficiency multi-junction photovoltaics.

The concept proposes a new class of adaptive, self-regulating renewable infrastructures designed to support the escalating energy demands of artificial intelligence, data centres, and emerging quantum computing systems, offering a pathway toward sustainable, intelligent energy ecosystems.

Note: This manuscript presents an original conceptual framework based on theoretical analysis and publicly available scientific principles. It does not describe, endorse, or report on any existing physical implementation. All data, figures, and simulations are illustrative of potential outcomes under idealised conditions.

DOI: 10.5281/zenodo.18220647
Work type Technical
Tags phase-change materials, greenhouse physics, adaptive solar systems, renewable energy, computational sustainability, quantum computing energy demand, energy ecology, magnetic levitation, intelligent energy systems, optical energy recycling, hybrid photovoltaic–thermal, solar energy systems, ai data centres, sustainable infrastructure, dynamic rotational solar habitat, biomimetic design, rotational photovoltaics, radiative cooling, self-regulating energy architecture

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Identifier 2601124243939
Entry date Jan 12, 2026, 12:46 PM UTC
License Creative Commons Attribution-NonCommercial 4.0

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Author 100.00 %. Holder Abbey Gougouch. Date Jan 12, 2026.

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