Fact-checked by Grok 2 weeks ago

Tidal range

The tidal range is the vertical difference in height between the and the at a specific coastal , typically measured over a cycle. This phenomenon results from the gravitational interactions between the , , and Sun, which cause periodic rises and falls in , with the Moon's influence being dominant due to its proximity. Tidal ranges can vary significantly, from less than 1 meter in some open ocean areas to over 16 meters in extreme cases, and are classified based on patterns such as semidiurnal (two high and two low daily with roughly equal ranges), diurnal (one high and one low daily), or mixed. Tidal ranges are influenced by both astronomical and geographical factors. Astronomically, ranges increase during spring tides—when the Sun, , and align (at new or full moon)—producing greater gravitational pull, and decrease during neap tides when the Sun and are at right angles, resulting in smaller ranges. Additionally, the Moon's elliptical orbit causes higher ranges at perigee (closest approach) and lower at apogee, while Earth's orbital position relative to the Sun amplifies this during perihelion. Geographically, coastal plays a crucial role: funnel-shaped bays amplify ranges through , as seen in the between ’s and , where the world's highest recorded tidal range reaches up to 16 meters (53 feet) due to the basin's shape, depth, and a 12-hour oscillation period matching the tidal cycle. Other factors include shoreline configuration, shapes, river outflows, wind patterns, and , which can modify local ranges by several meters during storms. In contrast, the Pacific Ocean's vast size leads to generally smaller ranges compared to . The tidal range holds significant implications for coastal environments, human activities, and renewable energy. It shapes intertidal ecosystems by determining the extent of submersion and exposure, influencing biodiversity in zones like salt marshes and mudflats where species adapt to varying inundation periods. For navigation, precise knowledge of tidal ranges is essential to avoid grounding in shallow waters or to time port operations, as variations affect water depths and currents. In engineering, large ranges inform the design of harbors, bridges, and flood defenses, while in energy production, they enable tidal range technologies like barrages to harness the potential energy of water flow, with sites like the Bay of Fundy offering substantial hydroelectric potential equivalent to billions of cubic meters of water movement daily. Overall, understanding tidal ranges is vital for mitigating coastal hazards, sustainable development, and climate adaptation amid rising sea levels.

Fundamentals

Definition

The tidal range refers to the vertical difference in between consecutive high and low tides at a specific coastal . This metric captures the amplitude of the tidal oscillation over a single tidal cycle, typically spanning about 12 to 24 hours depending on the local tidal pattern. Tidal range is commonly measured in meters or feet using tide gauges, which record continuous water level variations relative to a fixed on land. In modern applications, satellite altimetry supplements these observations by providing global data on sea surface heights, from which tidal ranges can be derived through . The mean tidal range, a standardized value, is calculated as the difference between mean high water (the average of all high water heights over a 19-year ) and mean low water (the average of all low water heights over the same period). Within the broader tidal cycle, the range connects high and low water levels, forming the basis for reference datums like mean high water and mean low water, which serve as benchmarks for nautical charting and . These datums account for long-term averages to mitigate short-term variations, such as those during spring tides (larger ranges) or neap tides (smaller ranges). The concept of tidal range emerged in 19th-century through systematic observations, where researchers tabulated differences between high and low water heights to quantify behavior. This approach, pioneered in coastal monitoring efforts across and , laid the foundation for modern analysis.

Physical Causes

The tidal range, which measures the vertical difference between high and low tides, arises primarily from the gravitational attractions exerted by on 's oceans. The Moon's gravitational pull is the dominant force due to its proximity to , despite the Sun's much greater mass; the Moon is about 390 times closer to than is, resulting in a approximately twice as strong as the Sun's, as tidal effects scale inversely with the cube of the distance between bodies. These gravitational forces create a two-bulge in Earth's oceans: one bulge forms on the side facing the due to direct gravitational attraction pulling toward it, while the second bulge appears on the opposite side because the from the Earth-Moon orbital motion exceeds the Moon's gravitational pull there, causing to lag behind. Earth's rotation beneath these relatively stationary bulges (aligned with the ) produces the observed semidiurnal tidal cycle, with locations experiencing high twice daily as they pass through each bulge. In the equilibrium tide theory, the shape of these ocean bulges is determined by the tidal potential, which describes the gravitational perturbation from the (or Sun). The basic form of this potential at a point on or near Earth's surface is given by \Phi_\text{tide} = -\frac{GM}{d} \left( \frac{r}{d} \right)^2 P_2(\cos \gamma), where G is the , M is the mass of the (or Sun), d is the distance from Earth's center to the 's (or Sun's) center, r is the distance from Earth's center to the point (approximately Earth's radius), \gamma is the angle between the position vectors to the point and the , and P_2(\cos \gamma) = \frac{1}{2} (3 \cos^2 \gamma - 1) is the second-degree Legendre polynomial capturing the quadrupolar deformation. The equilibrium ocean surface aligns with equipotential surfaces of this potential plus Earth's own gravity, yielding theoretical tide heights of about 0.5 meters for the alone. The tidal range varies due to changes in the Moon's declination (its angular position relative to Earth's equator) and orbital alignments with the Sun. During new and full moons, when the Moon and Sun are aligned with Earth, their gravitational forces constructively interfere, producing spring tides with greater ranges; conversely, at quarter moons, the forces partially cancel, resulting in neap tides with smaller ranges. Declination effects further modulate this: maximum lunar declination (up to 28.5°) tilts the bulges away from the equator, reducing ranges at low latitudes and enhancing them at higher ones, while perigee (Moon's closest approach) amplifies forces by up to 20% compared to apogee. Beyond equilibrium theory, dynamic effects in the oceans modify the tidal range through wave propagation and interactions with the seafloor. In shallow waters, where depth is much less than the tidal wavelength, friction and reduced wave speed (c = \sqrt{gh}, with h as depth) cause tidal energy to concentrate, amplifying amplitudes via shoaling—similar to how waves grow taller approaching a beach—and potentially exciting resonances in basins, leading to ranges several times the equilibrium value. These shallow-water distortions also generate higher harmonics (overtides) that further alter the tidal waveform.

Tidal Patterns and Classification

Types of Tidal Cycles

Tidal cycles refer to the periodic patterns of high and low over daily and monthly timescales, primarily driven by the gravitational forces from the and Sun acting on Earth's oceans. These cycles determine the frequency and variability of tidal ranges experienced in coastal areas. The main types are classified based on the number of tides and their relative amplitudes within a lunar day, which lasts about 24 hours and 50 minutes. Semidiurnal tides occur twice daily, featuring two high tides and two low tides of approximately equal heights each . This pattern results from the dominance of semidiurnal constituents, such as the principal lunar semidiurnal tide (M2), which aligns with the Moon's orbital period. Diurnal tides, in contrast, produce one high tide and one low tide per . They are characterized by the prevalence of diurnal components, like the principal lunar diurnal tide (O1) and the principal solar diurnal tide (), which have periods close to 24 hours. Mixed tides combine elements of both, typically manifesting as two unequal high tides and two unequal low tides per , with one high tide significantly higher than the other and one low tide notably lower. This mixed semidiurnal pattern arises when both semidiurnal and diurnal components are comparably strong, leading to irregular inequalities in tide heights. The distribution of these daily tidal cycle types is influenced by factors such as basin geometry and , with diurnal tides tending to dominate near the due to the equatorial alignment of diurnal forcing mechanisms. Over monthly cycles, tidal ranges fluctuate due to changing alignments of , , and . Spring tides happen around the times of and new moon, when and Moon's gravitational pulls reinforce each other, producing the greatest tidal range. Neap tides occur during the first and third quarter moons, when the Sun and are at right angles to each other, causing their tidal effects to partially counteract and resulting in the smallest tidal range. These monthly variations stem from the relative phases of the principal lunar semidiurnal () and principal solar semidiurnal () tidal constituents.

Range-Based Classification

The range-based of tidal regimes, primarily focused on the of the mean spring tidal range, provides a framework for understanding coastal dynamics and morphology. Introduced by J.L. in 1964, this system categorizes shorelines into three principal classes: microtidal (less than 2 meters), mesotidal (2 to 4 meters), and macrotidal (greater than 4 meters). These thresholds reflect the dominant role of energy in shaping coastal features, with lower ranges indicating limited tidal influence on movement and higher ranges promoting extensive intertidal zones and stronger currents. Microtidal conditions, with ranges below 2 meters, are characteristic of open ocean coastlines and enclosed seas, where frictional dissipation reduces , leading to -dominated morphologies. Mesotidal ranges of 2 to 4 meters occur along moderate coastlines, balancing and wave processes to form mixed sedimentary environments. Macrotidal regimes, exceeding 4 meters, are prevalent in funnel-shaped estuaries, where basin geometry amplifies tides, resulting in tide-dominated landscapes with pronounced ebb and flood channels. Subsequent refinements by Miles O. Hayes in 1979 incorporated wave-tide interactions, expanding ' model into a hydrodynamic classification that considers both mean spring tidal range and annual to delineate tide-dominated, wave-dominated, and mixed-energy coasts. This approach highlights how relative energy partitioning affects formation and inlet stability, with implications for patterns and distribution. For extreme cases, hypertidal regimes with ranges over 6 meters—often amplified to exceed 9 meters in resonant bays—represent specialized subsets of macrotidal systems, fostering unique ecological and geomorphic features due to intense tidal currents. This amplitude-focused classification applies across tidal cycle types, such as semidiurnal patterns, where the range defines the vertical excursion between successive high and low waters.

Geographical Distribution

Global Variations

Tidal ranges exhibit significant latitudinal variations, with generally smaller amplitudes near the and larger ones at higher , primarily due to the interplay of the and continental basin geometries that channel tidal energy more effectively poleward. The Coriolis parameter, which increases with , deflects tidal waves, causing them to rotate around amphidromic points and concentrate energy in mid- to high- coastal regions where landmasses like and form resonant pathways. This latitudinal gradient arises because equatorial regions experience minimal deflection, leading to more uniform dissipation of tidal energy across vast open oceans, whereas higher benefit from constructive interference in semi-enclosed basins. Amphidromic systems further contribute to global variations by creating nodes of zero tidal at central points within , from which tidal ranges radiate outward in concentric patterns. These systems form due to the , with co-tidal lines emanating from the and co-range lines forming irregular circles where increases with distance from the , often reaching maxima at basin edges. In the , rotation occurs counterclockwise around these points, enhancing range gradients in regions like the North Atlantic, while systems rotate clockwise, influencing Pacific and Indian margins differently. Continental shelves and coastal amplify tidal ranges through shallow-water effects and geometric funneling, particularly for semi-diurnal . As tidal waves propagate onto shelves, decreasing water depth slows the wave speed, causing crests to bunch up and increase , with amplification factors up to 60% from shelf break to coast in some systems. in narrowing coastal geometries further enhances this, as tidal energy is conserved while the wavefront narrows, leading to heightened ranges in shelf seas compared to adjacent deep oceans. Ocean basin plays a key role in spatial variations, where tidal periods align with natural oscillation modes of the basin, amplifying ranges in responsive geometries. For instance, the acts as a quarter-wave for the semi-diurnal M2 , with its length approximating one-quarter of the , resulting in pronounced amplification toward the southern and eastern coasts. Global tide models such as TPXO illustrate these patterns, revealing average ranges of 1-2 m across much of the , contrasted with higher values often exceeding 2 m in the and its approaches, reflecting basin-scale differences in and shelf interactions.

Notable Examples

The in exhibits one of the world's largest tidal ranges, reaching up to 16 meters at its head, primarily due to resonant amplification within its funnel-shaped basin that concentrates incoming tidal waves. These extreme tides have been documented in historical records dating back to early European explorations in the 17th century, with systematic measurements confirming the range's consistency over time. In the , the experiences a maximum tidal range of approximately 15 meters during spring tides, driven by the narrowing channel that funnels Atlantic waters and generates a prominent —a that propagates upstream. This site represents a classic macrotidal environment, second only to certain North American bays in global scale. The features predominantly diurnal cycles, with ranges up to 10-12 meters in its northern reaches during spring , influenced by the region's mixed regime and coastal topography that enhances local variations. Conversely, the exemplifies minimal ranges, typically less than 1 meter and averaging around 0.4 meters, owing to its semi-enclosed nature and limited open- fetch that dampens incoming energy. Ungava Bay, , is a contender for having one of the world's highest tidal ranges, with historical records from indicating up to 16.6 meters at Leaf Basin and recent analyses (post-2020) suggesting around 16.3 meters, due to resonant effects in . As of 2025, this places it in dispute with the for the global record, with ongoing efforts to verify and recognize the measurements.

Influences and Applications

Environmental and Coastal Impacts

The extent of the , which spans the area between high and marks, is directly proportional to the tidal range, creating broader habitats in areas with larger ranges that support diverse assemblages of flora and fauna. In mesotidal regions (tidal ranges of 2–4 m), such as parts of the U.S. East Coast, extensive salt marshes develop within these zones, where vegetation like Spartina alterniflora stabilizes sediments and fosters high through stratified plant communities adapted to varying inundation levels. Greater tidal ranges enhance marsh stability by expanding the elevational window for vegetation growth, allowing for richer microbial, invertebrate, and bird populations that thrive in the dynamic wetting-drying cycles. This zonation promotes , with lower intertidal areas hosting and mobile crustaceans, while upper zones support desiccation-tolerant species like and periwinkles. In macrotidal environments (tidal ranges exceeding 4 m), such as those along the coasts of and , intense and deposition processes dominate, resulting in highly dynamic shorelines and expansive s that reshape rapidly over cycles. During flood in extremely shallow waters (depths <0.2 m), elevated bed —up to twice that of deeper stages—drives significant , mobilizing fine sediments and preventing permanent stabilization. Conversely, ebb favor net accretion as reduced shear allows suspended particles to settle, forming thick layers that serve as grounds for shorebirds and support microbial mats essential for nutrient cycling. These alternating forces contribute to migratory shorelines, where s can advance or retreat by meters per , influencing long-term coastal morphology without human intervention. Tidal range-induced salinity fluctuations profoundly shape ecosystems in mangroves and estuaries, creating sharp gradients that dictate zonation and . In estuarine mangroves, such as those in the , larger tidal ranges amplify incursions of saline seawater into freshwater-dominated areas, causing daily salinity swings of 10–30 ppt that favor salt-tolerant species like Rhizophora mangle in seaward zones and less tolerant Avicennia germinans inland. These variations promote vertical , with propagules sorting by density in response to salinity density gradients, leading to distinct bands of that enhance overall diversity for nurseries and epibenthic . In broader estuarine settings, such zonation supports food webs by providing refugia during low-salinity floods and saline stress periods. Climate change exacerbates these impacts through sea-level rise, which can modify tidal ranges by altering coastal and increasing inundation frequencies in intertidal habitats. According to IPCC AR6 assessments, global mean sea-level rise is projected to reach 0.28–0.55 m by 2100 under low-emission scenarios (SSP1-1.9) and 0.63–1.01 m under high-emission scenarios (SSP5-8.5), relative to 1995–2014 levels, potentially compressing intertidal zones and shifting regimes in marshes and mangroves. This rise could amplify in macrotidal areas and submerge low-elevation marshes, reducing their extent by 20–50% in vulnerable regions without compensatory supply. High tidal ranges also create biodiversity hotspots by concentrating nutrients and prey through intense mixing, as exemplified in the , where ranges up to 16 m sustain over 2,000 species including the endemic mud piddock clam (Barnea truncata) and critical habitats for endangered North Atlantic right whales. The fundy's tidal fronts aggregate , supporting unique benthic communities like horse mussel reefs and sponge fields, which harbor species such as the giant Melananchora elliptica sponge, underscoring the role of extreme ranges in fostering exceptional ecological productivity.

Human Uses and Engineering

Tidal ranges have been exploited for power generation through barrages that impound water during high tides and release it through turbines to produce , particularly in sites with mean spring ranges exceeding 5 meters. The La Rance Tidal Power Station in , , operational since November 1966 and managed by (EDF), represents the pioneering example of this technology, featuring 24 reversible bulb turbines with a total installed capacity of 240 MW. This facility has demonstrated long-term reliability, generating approximately 500 GWh annually by harnessing a tidal range of approximately 8 meters. In macrotidal environments, where ranges surpass 4 meters, and face significant challenges from fluctuating water depths and , often requiring regular to maintain safe channels. For example, in the with its extreme 12-15 meter spring tides, ports such as undergo frequent to combat siltation from tidal currents, ensuring accessibility for large vessels despite the natural scouring that keeps the main channel deep. Lock systems further mitigate these issues by isolating vessels from rapid changes, enabling controlled transit between tidal estuaries and inland waterways, as seen in various ports adapting to high-range conditions. Large tidal ranges exacerbate flood risks during storm surges, prompting engineered defenses to protect coastal populations and . The Thames in , completed in 1982, serves as a critical example, closing to block tidal surges amplified by the estuary's 7-meter-plus spring tidal range, having prevented over 200 flooding events to date. Such structures use hydraulic gates to hold back water levels up to 10.2 meters above mean , combining predictive modeling with mechanical reliability to safeguard urban areas. Tidal flats in mesotidal zones, characterized by ranges of 2-4 meters, offer productive habitats for and , particularly shellfish cultivation that benefits from periodic exposure and submersion. These intertidal areas facilitate and farming by providing nutrient-rich sediments and natural filtration, as exemplified in where shellfish operations on mudflats and eelgrass beds yield significant commercial harvests. Traditional also thrives here, with low tides exposing flats for hand-gathering or raking of bivalves, supporting local economies in regions like the U.S. . Contemporary engineering advancements leverage tidal ranges through stream generators that capture from currents without full barrages, enabling deployment in moderate-to-high range sites. Devices like Orbital Marine Power's turbine, a 2 MW floating system installed at Scotland's MeyGen array since 2021, operate in areas with strong tidal currents associated with tidal ranges of several meters to produce reliable baseload power with minimal environmental footprint. As of November 2025, Orbital Marine Power is expanding to sites like Nova Scotia's with O2-X turbines. Accurate tidal predictions, essential for these and other applications, employ models that resolve observed water levels into constituent sinusoids for forecasting, as standardized by NOAA protocols using least-squares fitting of up to 37 components.

References

  1. [1]
    Tides and Water Levels - NOAA's National Ocean Service
    The difference in height between the high tide and the low tide is called the tidal range. A horizontal movement of water often accompanies the rising and ...
  2. [2]
    Types and Causes of Tidal Cycles - Tides and Water Levels
    Three basic tidal patterns occur along the Earth's major shorelines. In general, most areas have two high tides and two low tides each day.
  3. [3]
    The Influence of Position and Distance - Tides and water levels
    Once a month, when the moon is closest to the Earth (at perigee), tide-generating forces are higher than usual, producing above-average ranges in the tides.
  4. [4]
    JetStream Max: Bay of Fundy: The Highest Tides in the World - NOAA
    Apr 14, 2023 · The Bay of Fundy has the world's largest tidal variations, up to 53 feet, due to its funnel shape, depth, and a 12-hour oscillation period.
  5. [5]
    What Affects Tides in Addition to the Sun and Moon?
    Shoreline shape, bay/estuary shape, river flows, wind, and weather patterns, including high/low pressure systems, affect tides.
  6. [6]
    FAQs - NOAA Tides & Currents
    Another factor affecting the tidal range is the size of the ocean basin in which the tides are located. The Pacific Ocean is, by far, the largest of the world's ...<|control11|><|separator|>
  7. [7]
    Tide Formation—Tide Height - University of Hawaii at Manoa
    Tidal Geographic Factors. Factors that influence tidal range occur not only on a solar system scale, but also on local scales. Tidal ranges vary considerably ...
  8. [8]
    Tides | National Oceanic and Atmospheric Administration
    Sep 17, 2025 · Knowledge of the times, heights, and the flow of tides is of importance in a wide range of situations such as navigation through coastal ...
  9. [9]
    Tidal Energy | PNNL
    Tidal energy is a form of power produced by the natural rise and fall of tides caused by the gravitational interaction between Earth, the sun, and the moon.
  10. [10]
    What are tides? - NOAA's National Ocean Service
    Jun 16, 2024 · The difference in height between the high tide and the low tide is called the tidal range. Search Our Facts. Get Social ...
  11. [11]
    [PDF] Understanding Tides
    For example, the tidal datum of mean lower low water is defined as the average of the lower low water heights (or only low water height) of each tidal day ...
  12. [12]
    Monitoring Sea Level in the Coastal Zone with Satellite Altimetry and ...
    We examine the issue of sustained measurements of sea level in the coastal zone, first by summarizing the long-term observations from tide gauges.
  13. [13]
    Tidal Datums - NOAA Tides & Currents
    A tidal datum is a standard elevation defined by a certain phase of the tide. Tidal datums are used as references to measure local water levels.
  14. [14]
    The Tides They Are A‐Changin': A Comprehensive Review of Past ...
    Dec 13, 2019 · Most tide gauge data from the nineteenth century comprise tabulations of heights and times of high and low waters, with the difference between ...
  15. [15]
    [PDF] Nineteenth Century North American and Pacific Tidal Data
    This article describes historical tide measurements in the Pacific. Ocean and North America, their current status, and ongoing efforts to recover the data.
  16. [16]
    What Causes Tides - Tides and Water Levels
    In 1687, Sir Isaac Newton explained that ocean tides result from the gravitational attraction of the sun and moon on the oceans of the earth.
  17. [17]
    Gravity, Inertia, and the Two Bulges - Tides and water levels
    On the “near” side of the Earth (the side facing the moon), the gravitational force of the moon pulls the ocean's waters toward it, creating one bulge.
  18. [18]
    Tide Generating Potential - Richard Fitzpatrick
    The gravitational force per unit mass exerted by the moon on one of the planet's constituent points, located at position vector $ {\bf r}$ , is written
  19. [19]
    Changing Angles and Changing Tides - Tides and Water levels
    This is known as its declination. The two tidal bulges track the changes in lunar declination, also increasing or decreasing their angles to the equator.Missing: range | Show results with:range
  20. [20]
    https://www.vims.edu/research/units/labgroups/tc_tutorial/tide_analysis.php
  21. [21]
    Tide Analysis | Virginia Institute of Marine Science
    We get spring tides when M2 and S2 are in phase so that both waves peak at the same time causing tides of greater range. Neap tides occur when M2 and S2 are out ...
  22. [22]
    11.3 Tide Classification – Introduction to Oceanography
    A semidiurnal tide exhibits two high and two low tides each day, with both highs and both lows of toughly equal height (Figure 11.3.2). “Semidiurnal” means “ ...<|control11|><|separator|>
  23. [23]
    ARE TIDES CONTROLLED BY LATITUDE? | GeoScienceWorld Books
    Jan 1, 2019 · A common belief about tidal sedimentation is that tides are always larger near the equator and negligible at high latitudes.
  24. [24]
    (PDF) The origin of neap-spring tidal cycles - ResearchGate
    Aug 6, 2025 · When the M 2 and S 2 tidal components are in phase it yields spring tide, while neap tide occurs when they are out of phase (Kvale, 2006; Penna ...
  25. [25]
    [PDF] 1 Morphological Classification of Shorelines based on Hydrographic ...
    Davies (1964) first classified shorelines by tidal range (Table 1A). The focus on tides was considered justified because tidal range controls the length of ...
  26. [26]
    Coastal Effects of Tides - Institute for Water Resources
    Davies (1964) applied an energy-based classification to coastal morphology by subdividing the world's shores according to tide range. Hayes (1979) expanded ...
  27. [27]
    [PDF] Tide
    Davies (1964): classification based on spring tidal ranges. Microtidal: less than 2m. Mesotidal: 2-4 m. Macrotidal: greater than 4 m. Tidal Asymmetry: shallow ...
  28. [28]
    Classification of Tidal Beaches on the basis of Tidal Range (TR ...
    Classification of Tidal Beaches on the basis of Tidal Range (TR) (After Davies, 1964).
  29. [29]
    [PDF] Tidal Inlet Morphology Classification and Empirical Determination of ...
    A figure of tidal ranges along the United States is presented in. Davies (1964). Following concepts and methods in Hayes (1979), the inlets were separated into ...
  30. [30]
    World's highest tides: Hypertidal coastal systems in North America ...
    His system defined microtidal as having a tidal range of 0 to 2 m, mesotidal as having a tidal range of 2 to 4 m, and macrotidal as having a tidal ranges ...
  31. [31]
    None
    Nothing is retrieved...<|control11|><|separator|>
  32. [32]
    Coriolis and tidal motion in shelf seas - Coastal Wiki
    Oct 14, 2024 · Tidal waves in wide basins are strongly influenced by earth's rotation (Coriolis acceleration). Tidal waves turn around so-called amphidromic ...Missing: global | Show results with:global
  33. [33]
    The Ups and Downs of Tides - Eos.org
    Aug 13, 2020 · This is why the tide is much bigger in the Atlantic than in the Pacific: the Atlantic is better shaped to host a large tide. On regional scales ...
  34. [34]
    Amphidromic Systems - University of Alaska Fairbanks
    Dec 7, 2003 · Tidal range increases with distance from the central point. The tide progresses around the amphidromic node once during each tidal period.
  35. [35]
    [PDF] 2.3 the dynamic theory of tides
    The tidal range is zero at each amphidromic point, and increases outwards away from it. In each amphidromic system, co-tidal lines can be defined, which link ...<|separator|>
  36. [36]
    [PDF] The effect of continental shelves on tides - University of Washington
    Mar 21, 1980 · At v = vc,it the coastal tide is infinite, i.e., continental shelf tidal resonance occurs. For realistic values of al/a 2 and H(L)/H(a), Fig ...
  37. [37]
    Tidal and subtidal flow patterns on a tropical continental shelf semi ...
    Sep 29, 2010 · The amplification from the shelf break to the coast is 60% for the K1 tide, which is slightly smaller than the amplification of the M2 tide. The ...
  38. [38]
    Ocean and shelf tides - Coastal Wiki
    Jul 28, 2024 · In the 19th century, the idea was put forward that the main region of origin of tides would be the belt of water around Antarctica, which is ...
  39. [39]
    [PDF] Nonlinear tidal resonance - webspace.science.uu.nl
    ... North Sea as a quarter- wavelength resonator as well. The solid and dashed lines drawn in figure 1.6(d) denote the approximate positions of the crests and ...<|control11|><|separator|>
  40. [40]
    TPXO Global Tidal Solutions - OSU TPXO Tide Models
    TPXO is a series of fully-global models of ocean barotropic tides, which best-fits, in a least-squares sense, the Laplace Tidal Equations and assimilated data.TPXO products and registration · TPXO10 · TPXO10-atlasMissing: average ranges Pacific Atlantic
  41. [41]
    Weird Science: Extreme Tidal Ranges - University of Hawaii at Manoa
    The Bay of Fundy, located in Canada between the eastern Maritime Provinces of Nova Scotia and New Brunswick, has one of the world's largest tidal ranges.
  42. [42]
    Bay of Fundy tides - ResearchGate
    Aug 10, 2025 · The Bay of Fundy is famous for having the highest tides in the world -amplified from a mean tidal range of 5 m at the bay mouth to over 12 m at ...Missing: 1610s | Show results with:1610s
  43. [43]
    Turning the tide Severn Estuary - WSP
    At 14.86 meters between its lowest and highest astronomical tides, the Estuary ... Severn Estuary's capacity to support tidal energy. Connor May Senior Marine ...
  44. [44]
    Oceanography - Severn Estuary Partnership
    Tides within the Severn Estuary are amplified as they move inland with a tidal range exceeding 12m at Avonmouth during spring tides. Tidal currents in the ...
  45. [45]
    The Severn Estuary and Bristol Channel: A 25 year critical review
    The Severn Estuary is classed hyper-tidal because it has the second highest tides in the world, with mean tidal ranges of 6.5 m at neaps and 12.3 m on springs.
  46. [46]
    Evaluation of Tidal Asymmetry and Its Effect on Tidal Energy ... - MDPI
    Oct 2, 2024 · It is worth noting that the tidal range maximum is around 7.4 m at the mouth of the Colorado River Delta, on the western side of the head of the ...
  47. [47]
    Tides around the world - AVISO.altimetry.fr
    Indeed, they generate a mean variation of about 40 centimeters, but atmospheric conditions often hide the rise and fall in sea level. Headwinds or, more often, ...
  48. [48]
    On the resonance and influence of the tides in Ungava Bay and ...
    Sep 8, 2007 · [2] The tidal range in Leaf Basin, Ungava Bay, in northern Quebec (Figure 1) can reach 16.8 ± 0.2 m (from O'Reilly et al. [2005] based on ...Missing: meters credible source
  49. [49]
    Whose tide is highest? Canadian towns battle it out over Guinness ...
    Sep 22, 2025 · Tides are a quirk of geography and the swell of those waters, which rush in through the broader Leaf Basin of Ungava Bay, once reached 16.6 ...Missing: source | Show results with:source
  50. [50]
    Influence of tidal range on the stability of coastal marshland
    Apr 21, 2010 · We find that the stability of both the channel network and vegetated platform increases with increasing tidal range.Missing: biodiversity | Show results with:biodiversity
  51. [51]
    Hydrodynamics, erosion and accretion of intertidal mudflats in ...
    Our study shows that ESWS have a key influence on intertidal flat hydrodynamics and sediment dynamics. Thus our results are the basis for an improved ...Missing: shorelines | Show results with:shorelines
  52. [52]
    Erosion and Accretion on a Mudflat: The Importance of Very Shallow ...
    Sep 14, 2017 · In this study, we examine the contribution of very shallow-water effects to erosion and accretion of the entire tidal cycle, based on measured and modeled time ...3 Materials And Methods · 4.5 Erosional (e) And... · 5 Discussion
  53. [53]
    Adaptations to Life in the Estuary - NOAA's National Ocean Service
    Aug 12, 2024 · Where a species of mangrove tree exists depends on its tolerance for tidal flooding, soil salinity, and the availability of nutrients. Three ...
  54. [54]
    A re-evaluation of the tidal sorting hypothesis of mangrove zonation
    May 16, 2024 · Water with greater salinity is denser therefore, for mangrove propagules whose densities are close to the sea water, small changes in salinity ...
  55. [55]
    Chapter 9: Ocean, Cryosphere and Sea Level Change
    This chapter assesses past and projected changes in the ocean, cryosphere and sea level using paleoreconstructions, instrumental observations and model ...
  56. [56]
    [PDF] Identification and Review of Ecologically and Biologically Significant ...
    Tidal mixing fronts, such as those in the. Bay of Fundy, provide unique habitat for predators and prey within the ocean (e.g. fishes and whales), as well as for ...
  57. [57]
    La Rance Tidal Barrage | Tethys
    Aug 27, 2019 · Opened on the 26th November 1966, it is currently operated by EDF ... With a peak rating of 240 MW, generated by its 24 turbines, it ...Mre Project Site · Details · Project Progress
  58. [58]
    [PDF] La Rance Tidal Power Plant 40 year operation feedback - Tethys
    Studied between 1943 and 1961, built between 1961 and 1966. • Equipped with 24 bulb-units rated 10MW. • Total installed capacity: 240 MW.
  59. [59]
    [PDF] Severn Tidal Power Feasibility Study Assessment of the Regional ...
    port activities from a range of different tidal power options ... Aggregate extraction by means of dredging within the Severn Estuary is covered by license.
  60. [60]
    [PDF] Hydraulic Design of Deep-Draft Navigation Projects
    May 31, 2006 · This manual provides design guidance for improving deep-draft navigation projects. The design goal applicable to project development is to ...
  61. [61]
    Other sources of flooding - Greater London Authority
    Upstream of the Thames Barrier, river walls are still necessary to prevent the normal range of high tides from flooding parts of inner and central London.<|separator|>
  62. [62]
    The Thames Barrier - GOV.UK
    The barrier will close just after low tide, or about 4 hours before the peak of the incoming tide surge reaches the barrier. Information comes from a range of ...Forecasting closures · How the Thames Barrier works · Thames Barrier closures
  63. [63]
    Shellfish aquaculture farms as foraging habitat for nearshore fishes ...
    Farming occurs on tide flats, which, depending on the location, are naturally composed of a combination of eelgrass meadows, mudflats, and naturally recruiting ...Missing: mesotidal zones
  64. [64]
    Tidal Flats - Ocean Central
    Tidal flats support important fishing and aquaculture industries, serving as nursery grounds for commercially valuable fish and shellfish species. Coastal ...Missing: mesotidal zones
  65. [65]
    Orbital Marine Power | Leaders in tidal energy technology
    Orbital Marine Power is an innovative Scottish engineering company focused on the development of a low-cost, predictable, scalable floating tidal ...Missing: modern | Show results with:modern
  66. [66]
    [PDF] Tidal Analysis and Predictions - NOAA Tides and Currents
    This document covers tidal analysis and prediction, including the theory, methods, and harmonic analysis of water level data.