Abstract: This paper presents HCTGS v26 Deutschland, a theoretical concept paper in the Hydro-Cascade Turbine Gravity System (HCTGS) series, adapted for the geographic, industrial, and climatic conditions of Germany. Thirty towers across ten North Sea and Baltic Sea sites — Cuxhaven, Wilhelmshaven, Brunsbüttel, Kiel, Rostock, Rügen/Stralsund, Borkum (offshore), Flensburg, Lübeck, and Hamburg via the Elbe — constitute the reference architecture. At the standard design parameter of 1 Mm³/day water throughput per tower, the steam mass flow of 11,574 kg/s yields a theoretical thermal power of 26.1 GW per tower. At a 9% shaft-to-grid conversion efficiency — the sole parameter requiring engineering validation, set conservatively at one-third of the Carnot maximum for the full 1,500°C to 4°C cascade temperature differential — a single tower produces 2.35 GW of continuous electrical output. Thirty towers in three clusters of ten produce a gross electrical output of 618 TWh/year, representing 126% of Germany's 2024 electricity demand. Green hydrogen production yields 4.22 Mt/year combining two parallel pathways. Freshwater output is 30 Mm³/day, distilled by evaporation and programmably re-mineralised through Module C ion dosing. Magnesium serves as the ignition source and high-temperature stage driver — not as the primary steam generator. At 1,290 tonnes of Mg per tower per day, magnesium combustion contributes approximately 0.37 GW of direct thermal output, sufficient to ignite and sustain the high-temperature cascade stages and to initiate the rotating steam vortex. The full 26.1 GW thermal throughput derives from the steam mass flow of injected seawater entering pre-warmed by surface solar heating and OTEC thermal differential, and from the self-reinforcing thermodynamic feedback loop of the established vortex. Magnesium does not heat the water. Magnesium starts the process that the water's own thermodynamic potential then sustains. Magnesium operates through two entirely separate pathways. As combustion fuel: magnesium burns to MgO at 1,500°C — the MgO remains as Sorel cement feedstock sold at EUR 800/t. No regeneration loop exists. As structural alloy feedstock: the controlled temperature cascade crystallises seawater minerals sequentially by falling solubility — CaSO₄ first, then NaCl, then KCl, then MgSO₄, leaving a concentrated MgCl₂ mother liquor as the final fraction. This MgCl₂ concentrate feeds directly into the electrolysis cell at the precise concentration and purity that modern MgCl₂ electrolysis requires — without additional processing, without imported reagents, and without separation chemistry beyond the temperature gradient the cascade already provides. The concentration work is performed by the cascade itself as a structural by-product of water production, reducing the effective electrolysis energy requirement substantially below figures calculated for raw seawater feedstock. At cascade operating conditions, internal Mg production cost approaches or falls below USD 200/t. Cascade-speed mineral crystallisation — minutes to hours versus 12 to 24 months for conventional solar evaporation in open desert basins — is documented as prior art in HCTGS v7.0 Atacama (DOI: 10.5281/zenodo.19545286), where the Zero-Evaporation Mining and Gravity-Driven DLE architecture was first formally described. The v26 Deutschland cascade applies the same crystallisation principle at North Sea scale, with the additional advantage of pre-concentrated MgCl₂ mother liquor as direct electrolysis feedstock — eliminating the raw seawater concentration step entirely. Full documentation of the crystallisation sequence and energy cost pathway: HCTGS v14 Phoenix (DOI: 10.5281/zenodo.19773264) and HCTGS v18 The Separation Engine (DOI: 10.5281/zenodo.20009640). Green hydrogen is produced through two parallel pathways. The primary pathway is thermochemical: at 700–800°C, the reaction Mg + H₂O → MgO + H₂ produces hydrogen directly from cascade heat without electrical input — documented in HCTGS v17.0 (DOI: 10.5281/zenodo.19957660). The secondary pathway is PEM electrolysis from surplus ORC electrical output. The thermochemical pathway delivers approximately 350,000 tonnes per year across 30 towers at linear scaling of the v17 documentation; the remaining capacity toward the 4.22 Mt maximum runs through PEM electrolysis at 50 kWh/kg, consuming up to 193 TWh of the 618 TWh electrical production capacity. Electricity export and hydrogen production are therefore alternative uses of the same capacity — the offtake architecture decides the mix, not the physics. Internal production price across both pathways: EUR 0.80 to 1.20 per kilogram. The thermal architecture is a multi-source additive fuel cascade across six parallel input streams documented in HCTGS v22 (DOI: 10.5281/zenodo.20184442): magnesium at 1,500°C (24.9 MJ/kg); boron at 400–550°C (58.6 MJ/kg); aluminium-magnesium alloy at comparable temperatures; ORC conversion; solar thermal and biogas; and OTEC/SWAC deep-sea cooling at 4–6°C. The energy balance across all six input streams requires pilot-scale measurement to close. The thermodynamic cycle efficiency of η = 0.36–0.38 per the Rennó & Bluestein (2001) heat engine framework is referenced to the full 1,500°C to 4°C cascade temperature differential, against a Carnot maximum of approximately 84% at this temperature pair. The paper introduces four Novel Contributions (NC-DE-1 through NC-DE-4) and extends three prior HCTGS architectures (NC-DE-5 through NC-DE-7). NC-DE-1 formalises the Adaptive Operating Window: 0.59 to 4.0 Mm³/day per tower, with electrical output ranging from 1.3 GW to 9.4 GW. NC-DE-2 documents the Rashidi Tower Spiral: a logarithmic constriction element accelerating steam through the outer 50% of the cross-section, with the inner 50% as Open Core Vector — named in recognition of Prof. Majid Rashidi of Cleveland State University, whose published research on spiral flow velocity amplification in vertical cylindrical structures provided the foundational geometry. NC-DE-3 formalises Multi-Stage Intermediate Turbines: 12 annular stages every 50 metres, adding 336 MW per tower beyond the 2.35 GW base. NC-DE-4 documents the Janus Principle: symmetric component pairs enabling 180-degree switchover in under 10 minutes, targeting approximately 99.5% availability. NC-DE-5 documents HCTGS–Offshore Wind Hybrid coupling. NC-DE-6 (Variant C Deep Shaft) documents a 600-metre underground shaft at 60 bar with thermal purification and estimated 6.24 GW output subject to engineering validation. NC-DE-7 (Underground Ecosystem) documents an AI cluster at 200–399m depth with PUE 1.0 and complete EMP/HEMP shielding, a brine crystallisation energy storage system whose capacity is subject to pilot-scale measurement, and natural tunnel ventilation. Germany-specific applications span 25 parts including: TSMC Dresden ultra-pure water security; automotive Mg alloy supply at internal cascade cost versus EUR 8,000–12,000/t world market; Al₂O₃/MXene ceramic coating for the German Navy; Rhine corridor water supplementation through an intermediate-pumped distribution network powered by cascade electricity across the approximately 450-kilometre waterway route; forest and groundwater recovery through 500 gravity-fed wildlife oases; Zugspitz glacier stabilisation through Distributed Vapor Tapping; twelve programmable water profiles for industry, agriculture, and human biology; new coastal city architecture; and the German Coastal Water Bond cooperative ownership model. The revenue architecture is explicitly framed as platform-wide value creation across all participants — not as HCTGS consortium revenue alone. Following the Kalundborg industrial symbiosis model, the cascade sells temperature levels on the way down: each level is sold once to the tenant or offtake partner best positioned to use it. The HCTGS consortium captures a negotiated share through offtake agreements; co-investors, cooperative bondholders, and industrial partners capture the remainder. Platform-wide annual value creation across all output streams is estimated at EUR 66.9 billion for a 30-tower cluster. CAPEX for three clusters is estimated at EUR 8.4–10.2 billion. Carbon sequestration through MgO carbonation is estimated at up to approximately 20 Mt CO₂/year at maximum carbonation rates — subject to engineering validation. All revenue, payback, and IRR figures require independent financial modelling incorporating staged deployment, ramp-up periods, financing costs, and net energy allocation between output streams. The Political and Social Architecture (Part 21) documents geopolitical independence from energy and material import supply chains; defence and strategic resilience through underground EMP-shielded infrastructure; demographic reversal of coastal regions; social cohesion through the Raiffeisen cooperative ownership model; industrial sovereignty through domestic raw material production; and the generational investment argument. The New Hanseatic Architecture (Part 25) documents a five-country founding partnership — Germany, France, Switzerland, Austria, and Italy, with Slovenia as host nation for the Austrian cluster — structured as a parallel-start EU consortium in which each country activates independently when financing is secured, drawing on the Montanunion precedent of 1951. The controlled industrial vortex principle is demonstrated at two independent scales: the Mercedes-Benz Museum in Stuttgart (operational since 2006, 144 tangential air outlets, 34.4-metre certified fire protection tornado) and Louis Michaud's Atmospheric Vortex Engine (AVEtec / Peter Thiel Breakout Labs / Lambton College). Both confirm that tangential thermal fluid injection into a closed cylindrical space produces a stable, controllable, self-sustaining vortex. The Mini-HCTGS pilot at EUR 10–15 million under accelerated military mandate procedures, operational within an estimated 18 months, is the defined next step toward engineering validation. All technical parameters — the 9% shaft-to-grid conversion efficiency, the multi-fuel cascade energy balance, the Leviathan Battery storage capacity, the Rhine corridor hydraulic effect, the thermochemical hydrogen yield, and the CAPEX figures — are subject to independent engineering validation before operational implementation. Prior art secured under CC BY-NC-ND 4.0. Commercial implementation requires separate direct licensing.