Submitted:
10 July 2026
Posted:
14 July 2026
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Abstract
Keywords:
1. Introduction
2. Site Characterisation
2.1. Location and Wind Regime
2.2. Bathymetry and Grid Connection
2.3. Tidal Regime
2.4. Export Destination and Environmental Context
2.5. Data Acquisition and Processing
3. Methodology
3.1. Wind Resource Modelling
3.2. Turbine Power Conversion, Energy Yield and Array Losses
3.3. Tidal Current Resource and Conversion
3.4. Hybrid Integration and Capacity Factor
3.5. Electrolysis and Hydrogen Production
3.6. Hydrogen Conditioning for Export
3.7. Transport Cost
3.8. Techno-Economic Analysis
3.9. Sensitivity Analysis
3.10. Model Implementation and Reproducibility
4. Results
4.1. Wind and Tidal Resource
4.2. Hybrid Power Output
4.3. Hydrogen Yield and Resource Demand
| Quantity | Wind | Tidal | Hybrid |
|---|---|---|---|
| Installed capacity (MW) | 510 | 50 | 560 |
| Capacity factor (%) | 49.1 | 8.8 | 45.5 |
| Annual energy (GWh) | 2,195 | 39 | 2,234 |
| Electrolyser rating (MW) | — | — | 350 |
| Energy to electrolyser (GWh) | — | — | 1,839 |
| Electrolyser utilisation (%) | — | — | 60.0 |
| Curtailment (% of available) | — | — | 15.1 |
| Hydrogen output (t/yr) | — | — | 36,781 |
| Water demand (m³/yr) | — | — | 441,375 |
4.4. Export Pathway
4.5. Levelised Cost of Hydrogen
4.6. Sensitivity Analysis

5. Discussion
- Resource measurement. The resource characterisation rests on CMEMS reanalysis/satellite products and an ERA5-derived hourly wind series (Section 2.5 and Section 3.1) rather than co-located in-situ measurements, and the Dakhla tidal resource is especially uncertain: the reanalysis provides only a weak monthly geostrophic current, and the sub-monthly tidal stream is modelled harmonically rather than measured. A bankable study requires at least one year of on-site met-ocean data, including ADCP current profiling in Dakhla Bay.
- Storage and electrolyser cycling. The base case omits storage and does not model stack degradation. Adding batteries or a hydrogen buffer, together with an explicit degradation-versus-cycling model, would allow the firming value of tidal hybridisation to be monetised.
- System-sizing optimisation. This is a single-configuration study. A multi-objective optimisation of the wind/tidal/electrolyser/storage sizing for example using mixed-integer programming (Pyomo) or metaheuristics such as genetic algorithms or particle-swarm optimisation, as applied elsewhere to Moroccan hydrogen systems [6] together with a global variance-based sensitivity analysis, is the natural next step.
- Conditioning, transport and grid. Liquefaction and shipping are parametric rather than engineering-level and should be validated against vendor quotations, and site-specific grid-connection and cable-routing studies are required.
- Environmental and social factors. These are not monetised; a strategic environmental assessment and stakeholder engagement would be prerequisites for development.
6. Conclusions
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
Nomenclature
| Symbol | Definition | Units |
| , | Weibull shape / scale parameter | –, m/s |
| ; | Wind speed; cut-in, rated, cut-out speed | m/s |
| Turbine rated power | MW | |
| Mean wind power density | W/m² | |
| Air / seawater density | kg/m³ | |
| ; | Rotor swept area; power coefficient | m²; – |
| ; ; ; | Induction factor; wake decay; rotor radius; spacing | –; –; m; m |
| Gamma function | – | |
| ; ; ; | Tidal current; M₂ amplitude; M₂ period; phase | m/s; m/s; h; rad |
| , ; ; | Eastward, northward current components; current magnitude; direction | m/s; m/s; rad |
| CF | Capacity factor | – |
| Component / system / Faraday efficiencies | – | |
| ; LHV | H₂ mass-flow rate; lower heating value (33.33) | kg/s; kWh/kg |
| SEC | Specific energy consumption | kWh/kg |
| ; ; ; | Faraday constant; electrons; molar mass; current | C/mol; –; g/mol; A |
| Compression / minimum liquefaction work | kWh/kg | |
| ; ; | Compressibility; gas constant; pressures | –; J/mol·K; bar |
| Total heat load removed per unit mass in liquefaction | kWh/kg | |
| Ambient / liquefaction temperature | K | |
| ; | Daily boil-off fraction; initial stored mass | 1/day; kg |
| LCOT; CRF | Levelised transport cost; capital-recovery factor | USD/kg; – |
| CAPEX, OPEX | Capital / operating expenditure | USD |
| ; | Electricity price; value of lost H₂ | $/kWh; $/kg |
| LCOH | Levelised cost of hydrogen | USD/kg |
| Investment, O&M, feedstock, salvage cash flows | USD | |
| ; ; WACC | Discount rate; project life; weighted avg cost of capital | –; yr; – |
| ; ; | Equity, debt, value; costs of equity/debt; tax rate | USD; –; – |
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| Variable | CMEMS product | Period | Monthly-mean range | Typical monthly max |
|---|---|---|---|---|
| Surface wind speed | WIND_GLO L4 [32] | 2007–2016 | 4.9–9.7 m/s | 10.5–10.8 m/s |
| Geostrophic surface current | GLOBAL_REP_021 [31] | 2002–2014 | 0.06–0.11 m/s | 0.30–0.45 m/s |
| Sea-surface temperature | GLOBAL_REP_021 [31] | 2002–2014 | 19–24 °C | 26–27 °C |
| Parameter | Base (range) | 2030 value | Source |
|---|---|---|---|
| Offshore wind CapEx | 2.5 (1.0–3.0) M$/MW | 1.8 M$/MW | IRENA [26] |
| Tidal turbine CapEx | 4.0 (2.0–5.0) M$/MW | 3.2 M$/MW | EMEC / Carbon Trust |
| PEM electrolyser CapEx | 800 (500–1,500) $/kW | 350 $/kW | IEA [25] |
| Project lifetime | 25 years | 25 years | Standard offshore |
| WACC | 7 % (5–8 %) | 5 % | Morocco risk profile [25] |
| Annual O&M | 3 % (2–4 %) of CapEx | 3 % | Literature |
| SEC (electrolysis) | 50 (45–55) kWh/kg | 45 kWh/kg | IEA [25]; Carmo [22] |
| Water consumption | 12 (9–15) L/kg H₂ | 12 L/kg | IRENA [26] |
| RO desalination cost | 1.0 (0.5–1.5) $/m³ | 1.0 $/m³ | Industry |
| LH₂ boil-off rate | 0.3 (0.2–1.0) %/day | 0.3 %/day | Literature [24] |
| Export distance | 1,241 km | 1,241 km | Roadmap [3] |
| Cost . | Value (M$) | Share (%) |
|---|---|---|
| Offshore wind array | 1,275 | 53.3 |
| Tidal array | 200 | 8.4 |
| PEM electrolyser | 280 | 11.7 |
| Liquefaction plant | 320 | 13.4 |
| Balance of plant / grid / port | 316 | 13.2 |
| Total CapEx | 2,391 | 100.0 |
| Scenario | Production LCOH | Delivered LCOH | Annual H₂ |
|---|---|---|---|
| 2025 base case | 7.53 $/kg | 10.04 $/kg | 36,781 t/yr |
| 2030 learning curve | 4.45 $/kg | 6.58 $/kg | 40,868 t/yr |
| Roadmap target [3] | 2–4 $/kg | — | — |
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