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Submerged floating tunnel

A submerged floating tunnel (SFT), also known as an bridge, is a buoyant, infrastructure designed to transport vehicles or passengers beneath the surface of deep and wide of , relying on the principle of to maintain its position at a controlled depth—typically 20 to 30 meters—while being anchored to the via tethers, cables, or pontoons to counteract hydrodynamic forces and ensure stability. Constructed from prefabricated or segments assembled on-site, SFTs feature a low gradient for efficient travel, minimal interference with surface shipping, and resistance to weather impacts due to their submerged placement. Unlike immersed tunnels laid on the or floating bridges exposed to , SFTs offer a versatile solution for crossings exceeding 2 kilometers in length and depths over 100 meters, where geological conditions preclude conventional methods. The concept of SFTs dates back to 1860, when French engineer S. Préault proposed one for the Bosphorus Strait, though systematic research began in in the 1920s amid efforts to connect fjord-divided regions. Since the , international symposia and studies have advanced designs, focusing on materials like concrete-filled double-skin steel tubes for enhanced durability against , earthquakes, and vessel collisions. Key advantages include reduced environmental disruption, as construction can occur offshore with easy disassembly; lower visual and navigational impacts compared to bridges; and applicability in seismic zones due to flexible anchoring systems that absorb movements. However, challenges persist, such as vulnerability to vortex-induced vibrations, submarine landslides, and internal pressures from blasts or fires, necessitating advanced hydrodynamic modeling and multi-hazard simulations. Proposed projects highlight SFTs' potential: in Norway, the Norwegian Public Roads Administration has investigated crossings like the 3.6-km Sulafjord and 4.5-km Sognefjord as part of the E39 coastal highway, aiming to eliminate ferries and reduce travel times. In China, a 1.8-km tether-supported SFT is planned for Kanas Lake, using semi-floating assembly and gravity anchors for a two-year build, while feasibility studies explore a 3.3-km version in the Jintang Strait. Other concepts, such as polygonal cross-sections investigated for their response to submarine slide hazards or triple-chord trussed hybrids for harsh seas, underscore ongoing innovations, though no full-scale SFT has been realized to date.

Concept and Principles

Definition and Basic Operation

A submerged floating tunnel (SFT), also known as an bridge, is a tubular structure designed to float submerged in a at a fixed depth, supported by its own and anchored to the to enable vehicular or other passage across waterways. Unlike traditional fixed-bottom structures, the SFT maintains its position through a balance of upward buoyant forces and downward tethering, allowing it to span deep waters where conventional bridges or tunnels are impractical. In basic operation, the tunnel achieves neutral or slightly positive , suspending it below the surface—typically at depths of 20 to 30 meters—to avoid with surface shipping lanes while minimizing exposure to wave action. Access to the tunnel is provided via inclined ramps connecting to shorelines, facilitating entry and exit for vehicles without disrupting the submerged alignment. This distinguishes it from tunnels that rest directly on the rather than floating freely. The structure is tethered to the using cables or anchors, which counteract hydrodynamic forces and ensure during use. Typical SFT designs accommodate multi-lane traffic with internal diameters of 10 to 15 meters and lengths extending several kilometers, as seen in proposed projects like the 3.7-kilometer Sognefjorden crossing. These scales support efficient transport while leveraging the tunnel's buoyant equilibrium for structural integrity.

Physical Principles and Buoyancy Mechanics

The physical principles underlying submerged floating tunnels (SFTs) rely on , which asserts that an object immersed in a experiences an upward buoyant equal to of the displaced by the object. This , denoted as F_b = \rho g V, where \rho is the of the surrounding water, g is the , and V is the volume of water displaced, enables the tunnel to counteract its structural weight while remaining submerged. To maintain positional , SFTs are engineered for near-neutral , where the average density of the tunnel approximates that of through air-filled internal compartments that generate lift equivalent to the displaced volume. In tethered configurations, which are common for deep- applications, the design incorporates positive such that the buoyant force exceeds the tunnel's weight, with the excess balanced by downward in the anchoring tethers; the is thus F_b = W + T, where W is the weight of the tunnel and T is the tether . This setup ensures the hovers at a predetermined depth without sinking or rising uncontrollably. Beyond static buoyancy, SFTs must contend with dynamic hydrodynamic forces from ambient water currents and surface , which can induce motions and stresses on the structure. The primary horizontal force from currents is , quantified by F_d = \frac{1}{2} \rho v^2 C_d A, where v is the current , C_d is the (typically 0.5–1.2 for cylindrical sections depending on ), and A is the perpendicular to the flow. Vertical and oscillatory forces from , which diminish exponentially with depth, necessitate integrated mechanisms to suppress heave, , and sway responses and prevent . Submergence depth is critically selected to minimize wave exposure while accommodating navigation clearance, typically ranging from 20 to 50 meters below the surface in proposed designs, where wave orbital velocities are reduced to negligible levels for dominant wave periods of 5–15 seconds. This depth avoids direct interaction with surface disturbances, limiting hydrodynamic loads to those from deeper currents rather than full wave energy.

Comparison to Traditional Tunnels

Submerged floating tunnels (SFTs) differ fundamentally from bored tunnels, which require extensive excavation through or soil to create a stable underground passage. In contrast, SFTs rely on to remain suspended in the , avoiding the need for drilling or tunneling machines in challenging deep or soft seabed conditions. For instance, the , a 50 km bored connection between the and , was constructed by excavating through stable chalk marl layers, whereas an SFT could hypothetically span deep fjords like Norway's without such bedrock penetration. Compared to tunnels, SFTs are not placed on the but tethered or anchored while floating at a controlled depth, eliminating the required to create a for tube segments. , such as those used in shallower crossings, are ballasted to sink and rest on the prepared , limiting their application to water depths typically under 50-70 meters due to concerns. SFTs, however, enable crossings in deeper waters exceeding 100 meters by leveraging positive for support, bypassing interaction altogether. In relation to bridge alternatives, SFTs provide full submersion below the surface, preserving navigational clearance for shipping without the vertical obstruction posed by elevated spans and towers. Surface , like designs, are exposed to atmospheric conditions and require significant height for , making them unsuitable for busy waterways or deep channels. Additionally, the flexible tethering of SFTs offers inherent adaptability in seismic zones, allowing movement with water dynamics rather than rigid resistance. SFTs are generally less viable in shallow waters under 50 meters, where stability from anchoring becomes problematic and simpler methods suffice without the complexity of management.

Design and Engineering

Structural Components and Configurations

The main tube structure of a submerged floating tunnel (SFT) is typically designed with a cylindrical, rectangular, or elliptical cross-section to balance hydrodynamic efficiency and internal space requirements for traffic lanes. Cylindrical cross-sections minimize wave-induced forces and drag, making them suitable for deep-water environments, while rectangular or elliptical shapes allow for optimized vehicle capacity in bidirectional setups. These tubes are assembled from prefabricated elements connected via joints, forming either single-span configurations for shorter crossings or multi-span layouts where intermediate supports divide longer routes. Straight tube alignments are common for spans under 1 km, whereas curved sections may be incorporated in extended designs to align with contours or navigational needs. SFT configurations vary based on intended use, with single-tube designs often dedicated to or unidirectional to simplify and maintenance. Twin-tube configurations, consisting of parallel tubes, support bidirectional , with one tube per direction to enhance safety and flow efficiency. Hybrid variants integrate service corridors alongside main tubes for utilities, access, and , as seen in conceptual proposals for crossings. Truss-reinforced designs, such as triple-chord trussed structures, add longitudinal rigidity to the tubes, enabling longer unsupported segments without excessive deflection. Span lengths between anchors typically range from 100 to 500 meters, allowing modular while total project lengths can extend up to 5 km, as proposed for the Bjørnafjord crossing in . These spans facilitate assembly in controlled environments before , reducing on-site risks. End portals serve as transition points from the floating tube to land-based , often submerged to maintain the tunnel's profile and connect via bored, mined, or cut-and-cover tunnels. Access to the SFT can be achieved through inclined ramps with low gradients of up to 5% for gradual descent, vertical shafts equipped with elevators for or entry, or floating pontoons providing surface-level docking for ferries or direct links. These methods ensure seamless integration with existing transportation networks while accommodating variations and environmental constraints. The tube design inherently incorporates buoyancy to achieve neutral equilibrium, supporting the overall floating configuration without additional detailing here.

Anchoring and Stability Systems

Submerged floating tunnels (SFTs) rely on sophisticated anchoring and stability systems to counteract hydrodynamic forces, currents, and seismic events while maintaining precise positioning at depth. These systems ensure the tunnel's buoyancy-driven is preserved against vertical uplift and lateral displacements, distinguishing SFTs from fixed structures. Tethers and moorings provide the primary restraint, with mechanisms mitigating oscillatory responses. Tethering methods typically employ vertical cables or chains connected to piles, generating to offset the tunnel's net upward buoyant force. The required T is calculated as T = B - W, where B is the buoyant force and W is the structural weight, ensuring vertical and limiting heave motions. Vertical tethers primarily offer against vertical displacements, while inclined variants at angles around 45° enhance horizontal and torsional restraint, often spaced less than 40 apart for optimal performance under irregular . Combined vertical-inclined configurations further balance multi-directional loads, as demonstrated in hydrodynamic analyses meeting / criteria. Stability against dynamic motions such as heave, , and roll is achieved through devices like tuned mass dampers (TMDs), which are optimized to target the tunnel's fundamental lateral (typically around 1 rad/s). TMDs, comprising a , , and attached to the tunnel, reduce peak displacements and accelerations by up to 50% under wave excitations with significant heights of 3 m and periods of 6-8 s, using masses equivalent to 1% of the modal . For seismic resilience, flexible joints at tunnel segments accommodate differential movements, redistributing bending moments and preventing concentrations during earthquakes. These joints, often incorporating rubber elements, allow controlled deformation while maintaining watertightness. Mooring types for SFTs include lines, which form curved profiles for cost-effective deployment in moderate depths, and taut lines, which maintain near-vertical tension for superior vertical in deeper waters. systems rely on or sag to absorb horizontal excursions, whereas taut configurations minimize offsets but demand higher pretension. anchors adapt to soil variability: caissons, installed by pumping water to create , provide high uplift capacity in cohesive sediments, while gravity blocks offer simple, load-bearing stability in granular s without specialized installation. Monitoring systems integrate sensors for real-time assessment of tension and displacement, enabling proactive management. Accelerometers placed along the centerline (optimally 7 units) measure accelerations, which are double-integrated to derive displacements with accuracies exceeding 98% when fused with data via filters. Tension is indirectly monitored through displacement-mooring correlations or direct sensors where feasible, feeding into deep neural networks that detect failures across 21 scenarios under varying waves. These systems link to emergency controls, such as adjustable , to restore during detected anomalies.

Materials and Construction Methods

Submerged floating tunnels (SFTs) primarily utilize high-strength concrete for the main tube structure to withstand hydrostatic pressures and provide inherent buoyancy control, often combined with steel-concrete composites for enhanced durability in marine environments. Steel, particularly high-strength grades like S460 NH, is employed for tethers and anchoring components due to its fatigue resistance and suitability for tensile loads in submerged conditions. Corrosion-resistant materials, such as carbon fiber-reinforced polymers (CFRP), are integrated into cable systems and joints for their lightweight properties, high strength-to-weight ratio, and resistance to marine corrosion, reducing long-term maintenance needs. Construction begins with prefabrication of tube segments onshore in dry docks, where or steel-concrete sandwich structures are assembled under controlled conditions to ensure watertight integrity. These segments, typically up to 150-200 meters in length depending on spacing and transport feasibility, are fitted with flexible joints using rubber gaskets or for assembly, allowing for and minor movements post-installation. Once completed, segments are floated out to the site, sealed, and prepared for submersion, minimizing on-site risks in deep water. The installation sequence prioritizes seabed preparation, where anchors—such as blocks or piled —are positioned using geotechnical surveys to ensure stable points against currents and seismic activity. segments are then ballasted with or temporary weights to achieve negative buoyancy for controlled lowering into position via winches or cranes from support vessels, followed by de-ballasting to restore and tensioning of tethers. Alignment and connections rely on remotely operated vehicles (ROVs) or divers for precise sealing and verification, ensuring structural continuity without leaks. Recent advancements include the 2025 introduction of triple-chord designs in conceptual SFT prototypes, particularly explored for fjords, which employ concrete-filled double-skin (CFDST) structures for superior load distribution and reduced material use compared to traditional single-tube configurations. These trussed systems enhance overall by distributing hydrodynamic and vehicular loads across multiple chords and web members, as demonstrated in feasibility studies for deep-water applications.

Advantages and Challenges

Key Benefits for Transportation and Environment

Submerged floating tunnels (SFTs) offer significant advantages in efficiency by enabling direct crossings over deep and wide water bodies, such as fjords exceeding 1 km in width, where traditional ferries or bridges are impractical. In Norway's E39 coastal highway project, for instance, SFTs across the would eliminate multiple ferry crossings, reducing overall travel time from over 20 hours to under 10 hours between southern and northern regions. This halving of journey duration enhances connectivity, supports through faster goods and passenger movement, and provides reliable all-weather access unaffected by surface conditions like storms or high winds. From an environmental perspective, SFTs minimize disruption compared to conventional underwater tunnels that require extensive , preserving sensitive ecosystems and reducing sediment disturbance. Positioned 20-50 meters below the surface, they impose no visual impact on scenic seascapes, maintaining aesthetic and touristic value in areas like Norway's fjords. Additionally, by replacing ferry services, SFTs can cut carbon emissions by up to 50% through the elimination of fuel-intensive vessel operations, while their submerged design allows to pass freely above and around the structure without significant . SFTs enhance and due to their flexible , which absorbs seismic forces better than rigid tunnels, making them suitable for earthquake-prone regions. Their depth placement protects against surface hazards, such as floes, ship collisions, or , as the tunnel remains below shipping lanes and wave action. Designs incorporating redundant pontoons and systems further ensure structural , with studies showing reduced lateral by up to 60% under hydrodynamic loads compared to alternative configurations. SFTs also facilitate utility integration by accommodating cables or pipelines within the tunnel structure alongside vehicular traffic, optimizing use in environments. Conceptual studies demonstrate that integrating submarine pipelines into SFTs enhances safety by containing potential leaks and maintaining through careful , reducing environmental risks associated with seabed-laid utilities. This multi-purpose capability extends the tunnel's value beyond transportation, supporting efficient delivery of resources like oil, gas, or across water barriers.

Engineering and Safety Challenges

Submerged floating tunnels (SFTs) face significant engineering challenges from due to environmental forces such as currents, surface , and tsunamis, which can induce coupled motions including , heave, and roll. These forces lead to transient s and high tensions, with shorter-duration solitary waves causing up to 2.5 times greater lateral displacements compared to longer combined waves, exacerbating structural . Recent 2025 studies have analyzed these vulnerabilities using three-dimensional coupled models, emphasizing the role of flexible end supports in mitigating motion amplitudes under loads like ship collisions; for instance, end below a critical threshold (approximately 10^8 N/m) can amplify displacements and torsion post-adjustment. Optimizing parameters such as cross-sectional , buoyancy-weight , and cable angle can reduce maximum motion amplitudes by 4.2%–53.8% and forces by 6.9%–46.8%, but tsunamis remain understudied relative to ordinary , posing unresolved risks in prone regions. Maintenance of SFTs presents unique hurdles due to their submerged depth, typically 20–50 meters, necessitating specialized remotely operated vehicles (ROVs) or submersibles for inspections of the structure and anchoring systems. These underwater operations are complicated by poor visibility, high pressures, and , requiring advanced sensors for non-destructive testing. A primary concern is in tethers and mooring cables from cyclic loading by waves and currents, which can lead to micro-cracks and potential leaks if not monitored; long-term integrity relies on drawing from immersed and offshore oil platform practices, including periodic tether tension adjustments. Safety protocols for SFTs must address emergencies like or structural failures in confined, pressurized environments, incorporating automated detection systems and longitudinal limited to 8–10 m/s to control without compromising . Evacuation strategies emphasize cross passages spaced at 50–200 meters, enabling access to escape bays or vertical shafts for surface egress, with simulations showing safe tenable exposure durations based on heat release rates from 5–100 MW. suppression challenges include high hindering traditional systems, relying instead on or mechanisms integrated into the tunnel lining, though diffusion can outpace evacuation in scenarios without intermediate shelters. principles aid overall resilience by maintaining neutral equilibrium, but do not eliminate the need for robust protocols. Seismic and extreme event design for SFTs requires accommodating accelerations up to 0.5g, particularly in regions with non-uniform ground motions, using flexible-support boundaries to simulate joint and reduce peak responses. dissipation occurs through spring-like elements at pipe segment joints and buckling-restrained braces, which provide and limit differential displacements during earthquakes. Models incorporating multipoint and anchor cable demonstrate that increasing joint flexibility lowers tube accelerations but heightens tether demands, with ongoing challenges in validating these under full-scale extreme events like tsunamis combined with seismic activity.

Economic and Regulatory Considerations

The of submerged floating tunnels (SFTs) involves significant upfront capital investment, with cost estimates typically ranging from $20 million to $50 million per kilometer, depending on site-specific factors such as water depth, seismic activity, and material choices. This initial expenditure is generally higher than that for conventional bridges or bored tunnels due to the novel requirements, but long-term costs are projected to be lower owing to reduced exposure to surface and . For instance, Norway's E39 coastal highway project, which incorporates proposed SFT elements across multiple crossings totaling over 1,100 kilometers, is estimated at approximately $40 billion overall, highlighting the scale of investment needed for such innovative infrastructure. Funding for SFT projects often relies on public-private partnerships (PPPs), where governments collaborate with private entities to share risks and resources, supplemented by grants targeted at sustainable or initiatives. is anticipated through mechanisms such as revenues and savings from eliminating operations, which currently impose substantial subsidies on public budgets in fjord-heavy regions like . Regulatory challenges for SFTs stem primarily from international maritime laws, particularly the United Nations Convention on the Law of the Sea (UNCLOS), which governs submersion depths to ensure and prevent interference with maritime traffic. Projects must undergo rigorous environmental impact assessments compliant with UNCLOS provisions on coastal state jurisdiction and marine resource protection, often requiring coordination across multiple national authorities for cross-border or deep-water installations. Insurance and liability frameworks for SFTs remain underdeveloped due to their unprecedented risks, such as hydrodynamic forces and collision vulnerabilities, necessitating the evolution of new engineering standards. Discussions in by the Association (HKA) highlighted the "identity crisis" of SFTs in existing codes, advocating for tailored guidelines to address liability allocation among designers, constructors, and operators.

Historical and Current Developments

Early Concepts and Theoretical Foundations

The concept of the submerged floating tunnel (SFT) emerged in the late as an innovative alternative to traditional bridge and tunnel constructions for waterway crossings. However, the concept was first proposed in 1860 by S. Préault for a crossing of the Bosphorus Strait. In 1886, British naval architect Sir Edward James Reed patented the first design for an SFT in the , envisioning a buoyant tubular structure that could be submerged and anchored below the water surface to facilitate safe passage over deep or wide bodies of water without interfering with surface navigation. This early proposal laid the groundwork for utilizing of to support the tunnel's weight, distinguishing it from bottom-supported immersed tunnels. Early 20th-century developments further advanced theoretical foundations, particularly in . In 1923, engineer Trygve Olsen secured the first for a "submerged ," proposing a floating tube anchored by cables to span fjords, addressing the challenges of Norway's deep, narrow waterways where conventional bridges were impractical. These ideas transitioned from speculative sketches to more formalized engineering concepts in the post-World War II era, as offshore oil exploration and progress highlighted the feasibility of buoyant structures in deep waters. Theoretical milestones in the mid-20th century included initial investigations into and for deep-water applications during the and , culminating in small-scale model tests at the Marine Laboratory in in the late for a proposed 3.5 km SFT across the Bjørnafjord. These experiments focused on hydrodynamic responses and systems, validating the concept's potential against waves and currents. In the 1970s, Italian engineers conducted pioneering research on what they termed " bridges," with detailed feasibility studies for an SFT across the , emphasizing structural integrity and equilibrium in seismically active regions. Key publications from this period, such as early analyses in international proceedings, shifted SFTs from to credible solutions, with reports on model testing and preliminary designs appearing in forums like the Strait Crossings symposia starting in the . Small-scale testing expanded in the , including hydrodynamic experiments in controlled basins to assess dynamic loads, paving the way for site-specific applications in regions like .

Major Proposals in Europe

leads European proposals for submerged floating tunnels (SFTs) as part of its ambitious E39 coastal initiative, aimed at creating a ferry-free route along the western coast from to . Key components include the proposed 3.6-km Sulafjord crossing and the crossing, envisioned as a 3,700-meter SFT spanning the fjord's narrowest point between Lavik and Oppedal, positioned about 20 meters below the sea surface to minimize interference with surface navigation while avoiding extreme pressures at greater depths. The design incorporates a curved twin-tube structure for two-way traffic, with managed through approximately 15 floating pontoons and anchoring tethers to the for stability against currents and waves. As of early 2025, planning for the SFT advances within the broader E39 framework, with conceptual evaluations emphasizing truss-like horizontal elements or increased tube dimensions to enhance lateral stiffness in the fjord's challenging conditions. The overall E39 project carries an estimated cost of approximately €45 billion (as of 2025), though specific allocations for the Sognefjord segment remain under review amid ongoing feasibility assessments. Complementing these efforts, the project—a 26.7-kilometer subsea tunnel beneath the Boknafjord—serves as a hybrid immersed element in the E39 corridor, with construction progressing since 2020 and targeted completion in 2033 at a revised budget of NOK 24.8 billion (approximately $2.3 billion). Beyond , Denmark's Fehmarnbelt fixed link, an 18-kilometer immersed tunnel connecting Lolland to Germany's island, has prompted discussions of potential SFT extensions for deeper crossings, though these remain exploratory within ongoing infrastructure planning. In the , feasibility studies for an crossing between and have evaluated SFT configurations since 2021, deeming them technically viable despite significant engineering hurdles like seabed geology and high costs exceeding £200 billion. These concepts gained renewed attention at a September 2025 event, where experts discussed SFT applications for deep-water links, including potential adaptations. Progress across these proposals includes 2024 testing of SFT designs to assess and 2025 on seismic , with regulatory approvals pending evaluation of environmental and compliance under national guidelines. Economic funding draws from Norway's National Plan, supporting phased development amid debates on cost-benefit ratios.

Proposals in Asia and Other Regions

In Asia, several proposals for submerged floating tunnels (SFTs) have emerged, primarily driven by the need to cross deep straits and waterways in regions with challenging topography and high traffic demands. has been at the forefront, with feasibility studies and prototypes advancing the concept for practical implementation. One prominent proposal targets the Qiongzhou Strait, separating Hainan Island from the in the , where the average strait width is about 29.5 km and maximum water depth reaches 88 m. The design features a tube with a circular cross-section (14 m external , 12 m internal), supported by inclined strand cables and rigid inter-module joints, positioned at a submersion depth to minimize environmental and navigational impacts. Numerical simulations using /Fluent software have demonstrated the structure's safety under extreme conditions, including wave heights up to 8.6 m and current velocities of 4.0 m/s, confirming its . This project remains in the phase, highlighting SFTs as a cost-effective alternative to longer bridge or immersed tunnel options due to the strait’s relatively shallow depths and seismic considerations. Complementing these efforts, planned a SFT in () in Province around 2010 to test structural integrity and dynamic responses under controlled conditions. The incorporates a buoyant anchored by tension piles, with geotechnical investigations ensuring foundation stability in the lake's variable soils. Structural analyses, including finite element modeling, have verified the design's ability to withstand wave loads, vortex-induced vibrations, and accidental collisions, with safety factors exceeding requirements for displacement and strength. This 100 m-long test structure utilizes a hybrid steel-concrete configuration to evaluate mooring systems and material performance, providing critical data for scaling up to full-scale crossings. The project has informed subsequent research on SFT hydroelastic responses, emphasizing its role in validating theoretical models against real-world aquatic forces. More recent plans include a 1.8-km tether-supported SFT for Kanas Lake, expected to be built over two years with semi-floating assembly and gravity anchors, and feasibility studies for a 3.3-km SFT in the Jintang Strait. In , feasibility studies have explored SFT applications for coastal and bay crossings, leveraging the country's expertise in seismic-resistant infrastructure. A notable proposal envisions an 11 km-long floating across , submerged slightly below mid-depth in waters up to 40 m deep and supported by tethers to the seabed. This design aims to connect urban centers while accommodating the bay's strong currents and risks, with preliminary evaluations focusing on vortex-induced vibrations and mooring efficiency. Broader research in has assessed SFT viability for sites like Funka Bay in , incorporating polygonal cross-sections (e.g., hexagonal) to optimize hydrodynamic performance and reduce wave loads compared to circular tubes. These studies, conducted since the 1990s, prioritize technological readiness, including advanced anchoring systems, but no projects have advanced beyond conceptual and experimental phases due to economic and regulatory hurdles. Indonesia has considered SFTs as part of inter-island connectivity initiatives, particularly for the between and , a 25 km-wide passage with depths up to 200 m and high seismic activity. A European-led proposed a buoyant tube anchored 20-30 m below the surface via cables, integrated into the to link with . The concept emphasized to counter water pressure, aiming for completion by 2018, but the project shifted to a conventional bridge design amid funding delays and environmental concerns. Although not pursued further, this proposal underscored SFT potential for archipelagic nations facing logistical challenges in strait navigation. Beyond Asia, proposals in other regions remain exploratory. In New Zealand, an SFT across —separating the North and South Islands over 26 km with depths up to 280 m—has been discussed to replace services vulnerable to weather disruptions. The design would feature a tethered tube resilient to earthquakes, with estimated costs of NZ$20-30 billion, but it stays at the conceptual level pending detailed feasibility studies on and economics. Overall, these global initiatives highlight SFTs' adaptability to diverse marine environments, though realization depends on overcoming anchoring and cost barriers through ongoing .

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