Fact-checked by Grok 2 weeks ago

Tide

A tide is the periodic rise and fall of sea levels in the 's oceans, caused primarily by the gravitational interactions between the , , and Sun, along with the planet's . These movements create alternating high and low tides, typically occurring twice daily in most coastal regions, with the exerting the strongest influence due to its proximity despite the Sun's greater mass. The resulting tidal bulges—two on the , one facing the and one on the opposite side—manifest as the oceans' response to these forces, producing that travel across the globe. The fundamental cause of tides traces back to gravitational attraction, first mathematically described by in 1687, where the 's gravity pulls the 's water toward it on the near side, creating a bulge, while on the far side the weaker gravitational pull allows to form the second bulge. The Sun contributes about half the Moon's tidal effect, leading to variations: spring tides occur during full and new moons when the Sun, Moon, and Earth align, amplifying tidal ranges by about 20% compared to neap tides; conversely, neap tides happen at quarter moons when gravitational pulls partially cancel, resulting in smaller ranges. Local geography, such as coastal shape and ocean basin depth, further modifies tidal heights and timings, with some areas experiencing extremes like the 16-meter range in the . Tidal patterns vary globally into three main types: semidiurnal tides, with two nearly equal high and low tides per day (common along the U.S. East Coast); diurnal tides, featuring one high and low tide daily (prevalent in the ); and mixed semidiurnal tides, combining unequal highs and lows (typical on the U.S. West Coast). These cycles, lasting about 12.4 hours from high to high tide due to the Moon's orbital motion, play crucial roles in marine ecosystems by facilitating nutrient mixing and larval dispersal, while supporting human activities like , , and renewable tidal energy generation. Accurate tidal predictions, monitored by networks like NOAA's, are essential for coastal safety, prevention, and environmental management.

Fundamentals

Definition and Types

Tides are the periodic rise and fall of sea levels in oceans, gulfs, bays, and estuaries, primarily caused by the gravitational interactions between , . These interactions produce alternating bulges in 's oceans, resulting in the observed vertical movements that typically occur twice daily, though patterns vary by location. Tides are classified by their frequency and pattern into three main types: semidiurnal, diurnal, and mixed. Semidiurnal tides feature two high waters and two low waters each (approximately 24 hours and 50 minutes), with the highs and lows of roughly equal height; this type dominates along the U.S. East Coast. Diurnal tides have one high water and one low water per , commonly observed in the . Mixed tides, often semidiurnal in character, exhibit two unequal high waters and two unequal low waters daily; they prevail along the U.S. West Coast and Pacific islands. The tide range refers to the vertical difference between high water and the subsequent low water. Regions are categorized by mean spring as microtidal (<2 m), mesotidal (2–4 m), or macrotidal (>4 m). Macrotidal areas, such as the where ranges exceed 10 m (up to 16 m during extreme tides), experience amplified effects due to coastal funneling. In contrast, microtidal regions like the upper Gulf Coast have ranges around 0.5 m. Tidal datums serve as reference elevations for measuring water levels relative to the tide. Mean sea level (MSL) is the of hourly heights over a 19-year Tidal Datum Epoch. Mean higher high water (MHHW) is the average of the higher high water heights over the same epoch, used for delineating coastal boundaries and flood risks.

Tidal Cycles and Patterns

Tidal cycles are primarily driven by the relative to the , resulting in a of approximately 24 hours and 50 minutes, which is the time it takes for the to return to the same position in the sky. This extended compared to the day causes successive high tides to occur roughly 50 minutes later each day, shifting the timing of tidal peaks and troughs progressively throughout the month. In most coastal regions, this manifests as semidiurnal tides, featuring two high tides and two low tides per , though the exact pattern can vary by location. Spring tides occur when the Sun, , and are aligned in —during new and full moons—causing their gravitational pulls to reinforce each other and produce the highest tidal ranges of the cycle. Conversely, neap tides take place when the Sun and are at right angles to each other in —during the first and third quarter moons—resulting in partially opposing gravitational effects that lead to the lowest tidal ranges. These alignments alternate predictably, with spring tides exhibiting ranges up to twice those of neap tides in many areas, such as along the U.S. East Coast where differences can exceed 2 meters. The interplay of these alignments creates a fortnightly cycle, spanning about 14.8 days from spring to neap tide and back, as the Moon completes half its orbit around relative to . Over the full of approximately 29.5 days, tidal ranges thus vary systematically, with two spring-neap sequences per month, allowing predictable forecasting for and coastal activities. For instance, in the , , the fortnightly modulation amplifies extreme ranges up to 16 meters during springs, with neap tides featuring smaller ranges. Local tidal patterns are further shaped by coastal geography, such as the configuration of shorelines and bays, which can amplify or dampen these cycles through and funneling effects. In enclosed basins like estuaries, these features may enhance diurnal components or alter timing, leading to mixed tidal regimes distinct from the global semidiurnal norm.

Causes and Mechanisms

Gravitational and Centrifugal Forces

The tides on Earth are primarily driven by the interplay of gravitational forces from the Moon and centrifugal effects arising from the Earth-Moon orbital motion. The Moon's gravitational pull is not uniform across the Earth's surface due to the inverse-square law of gravity; it is strongest on the side of Earth facing the Moon and weakest on the opposite side. This differential gravitational acceleration, known as the tidal force or gravitational gradient, causes the ocean water to be pulled more strongly toward the Moon on the near side, creating a tidal bulge aligned with the Moon. On the far side, the weaker pull relative to the Earth's center results in a second bulge, where water is effectively left behind as the planet is accelerated toward the Moon. The centrifugal force emerges from the rotation of the Earth-Moon system around their common center of mass, or barycenter, which lies approximately 1,068 miles beneath Earth's surface. This force acts outward uniformly across Earth, directed away from the barycenter, and contributes to the far-side bulge by counteracting the Moon's gravity less effectively at greater distances. Together, these forces produce two tidal bulges per lunar orbit: one on the sublunar point due predominantly to the enhanced gravitational attraction and one on the antipodal point influenced by the centrifugal effect and reduced gravity. The net tide-generating force is the vector sum of the gravitational and centrifugal components, with the horizontal tractive component drawing water toward the bulges and zero at points 90 degrees from the Moon-Earth line. Earth's rotation plays a crucial role in how these bulges affect observers on the surface. As Earth spins on its once every 24 hours, any fixed point rotates beneath the stationary bulges (relative to the Moon), experiencing two high tides and two low tides per lunar day of about 24 hours and 50 minutes. This alignment ensures that the bulges appear to move across the oceans from the perspective of a rotating observer. The equilibrium tide theory provides a foundational model for understanding these forces by assuming a static, global ocean response to the combined potential. In this framework, the tidal potential V due to the Moon, after accounting for the uniform and linear terms that are balanced in the orbital frame, is given by the quadrupolar component: V \approx -\frac{G M_m r^2}{D^3} P_2(\cos \theta) where G is the gravitational constant, M_m is the Moon's mass, D is the Earth-Moon distance, r is the radial distance from Earth's center (approximately Earth's radius R at the surface), \theta is the angle from the Earth-Moon line, and P_2(\cos \theta) = \frac{3 \cos^2 \theta - 1}{2} is the second Legendre polynomial. This potential describes the deformation of the ocean surface into an ellipsoid elongated along the Moon-Earth axis, with the varying \theta-dependent term driving the differential forces. The equilibrium model idealizes the bulges' height as about 0.36 meters for the Moon's contribution alone, though real tides are amplified by dynamic effects.

Lunar and Solar Influences

The Moon exerts the dominant influence on 's tides due to its proximity, generating a approximately 2.2 times stronger than that of , despite the Sun's vastly greater mass. This force arises from the differential gravitational pull across Earth's diameter, proportional to the celestial body's mass divided by the cube of its distance to (M/r^3). The Moon's mass is about 1/27,000,000 that of (or precisely, M_m / M_s \approx 3.7 \times 10^{-8}), but its distance is roughly 390 times closer, yielding this enhanced effect. The Sun's tidal contribution is significant but secondary, producing tides with an amplitude about 46% of the lunar tide's amplitude. During alignments of the , , and Sun—known as syzygies, occurring at new and full moons—their gravitational forces reinforce each other, resulting in spring tides with greater range. Conversely, at (first and third quarter moons), the forces are nearly perpendicular, partially canceling to produce neap tides with reduced range. In the simple equilibrium model, spring tide ranges are approximately (H_L + H_S)/(H_L - H_S) times neap tide ranges, where H_L and H_S are lunar and solar amplitudes; with H_S \approx 0.46 H_L, this ratio is about 2.7, though observed ratios vary from 2.5 to 3.3 in deep oceans due to dynamic effects. The inclinations of the Moon's orbit (about 5.1° to the ) and the itself (23.4° to Earth's ) introduce effects, tilting the tidal bulges relative to the and causing latitudinal variations in tide types. The Moon's oscillates up to ±28.5° over fortnightly cycles due to its orbital nodes, while the Sun's reaches ±23.5° annually at solstices. These shifts amplify diurnal components at higher latitudes, leading to mixed semidiurnal-diurnal tides poleward of about 30° latitude, whereas equatorial regions experience predominantly semidiurnal tides when declinations are low.

Tidal Constituents and Variations

Primary Constituents

Tidal variations are modeled as the superposition of numerous sinusoidal harmonic constituents, each arising from periodic celestial motions of the , , and Sun relative to one another. These constituents represent the basic building blocks of the tide, with their amplitudes and phases determined through of observed data. In total, up to 37 primary astronomical constituents are commonly used, though a few dominate the overall signal in most locations. The principal semidiurnal constituents are M₂, the principal lunar semidiurnal tide with a period of 12.42 hours, and S₂, the principal solar semidiurnal tide with a period of 12.00 hours. M₂ originates from the direct gravitational attraction of the on 's oceans, accounting for the and the Moon's orbital motion around ; it is typically the largest constituent, often contributing more than half of the total energy in many coastal regions. S₂ stems from the Sun's direct gravitational effect, modulated by 's daily rotation, and is roughly 46% the amplitude of M₂ due to the Sun's greater distance from . The interaction between M₂ and S₂ drives the spring-neap . Diurnal constituents include K₁, the luni-solar diurnal tide with a period of 23.93 hours, and O₁, the principal lunar diurnal tide with a period of 25.82 hours. K₁ results from the combined gravitational influences of the and Sun, particularly their declinational effects as seen from . O₁ arises primarily from the Moon's , the variation in its position north or south of the . These diurnal components contribute to tidal inequalities and are prominent in regions with mixed or predominantly diurnal tides. Over longer timescales, the amplitudes of these constituents are modulated by the 18.6-year nodal cycle, caused by the of the Moon's orbital nodes relative to the plane. This cycle introduces periodic variations in the of the and Sun, affecting the tide potential; for example, M₂ amplitude varies by about ±4%, K₁ by ±11%, and O₁ by ±18%. Accurate tidal predictions thus require accounting for these nodal corrections, typically over a 19-year .

Amplitude, Phase, and Range Variations

The of the tide at any location results from the vector addition of multiple constituents, each characterized by its own and , leading to modulation through patterns. When constituent phases align, constructive amplifies the total , as seen in spring tides where the principal lunar semidiurnal constituent (M₂) and the solar semidiurnal constituent (S₂) combine in , producing higher high waters and lower low waters. In contrast, destructive occurs during neap tides when these constituents are approximately 90 degrees out of , resulting in reduced overall and more moderate tidal ranges. This vector summation is fundamental to tidal analysis, where the resultant tide height is the scalar sum of phasors in the . Phase differences among constituents and relative to astronomical forcing arise primarily from the propagation of tidal waves across ocean basins, introducing lags or leads that alter the timing of high and low waters. The phase lag δ represents the delay between the observed tidal maximum and the equilibrium position predicted from , influenced by factors such as continental barriers and frictional dissipation during . This can be expressed in the phase equation: \phi = \frac{2\pi (t - t_0)}{T} + \delta where t is the time, t_0 is a reference time (often lunar ), T is the constituent , and δ accounts for local propagation effects, typically measured in degrees or hours. For instance, the phase lag of the M₂ constituent can vary by several hours across a single ocean basin, as depicted in cotidal charts showing progressive delays from the open ocean toward coasts. Tidal ranges exhibit significant variations due to changes in the - over the lunar orbit's 27.55-day anomalistic month. At perigee, when the is closest to , the tidal-generating increases, enhancing amplitudes by up to 40% compared to apogee, where the is farthest and the diminishes accordingly; this stems from the dependence of gravitational on , with the perigee-apogee yielding a force modulation of approximately 1.4:1 for lunar tides. perturbations contribute smaller variations, with a force of about 1.11:1 between perihelion and aphelion, further modulating ranges when aligned with lunar cycles, such as during perigean spring tides that can exceed average ranges by 20-50% in susceptible locations. Local factors, including in semi-enclosed basins like bays and estuaries, can amplify or distort these variations by exciting natural oscillations that align with tidal periods, leading to enhanced ranges without altering the underlying astronomical drivers. For example, may cause surging motions that increase tidal amplitudes in specific coastal systems, though the effect diminishes with frictional losses.

Theoretical Models

Equilibrium Tide Theory

The equilibrium tide theory posits a simplified model of tidal behavior on , assuming a static that instantaneously adjusts to the gravitational potentials induced by the and Sun. This theory envisions a perfectly covered entirely by a uniform, frictionless layer of that responds without or dynamic effects to the tide-generating forces. Under these conditions, the surface deforms into a that maintains with the combined gravitational and centrifugal potentials. The tide height in this model is derived from the tidal potential, which arises primarily from the Moon's gravitational influence. The equilibrium tide height h(\theta) as a function of colatitude \theta (measured from the sub-lunar point) is given by h(\theta) = \frac{3}{2} \cdot \frac{G M R^2}{g r^3} \cdot (\cos^2 \theta - \frac{1}{3}), where G is the gravitational constant, M is the Moon's mass, R is Earth's radius, g is the acceleration due to gravity at Earth's surface, and r is the Earth-Moon distance. This expression ensures a zero global mean height and captures the latitudinal variation, with the factor (\cos^2 \theta - 1/3) corresponding to the associated Legendre function P_2(\cos \theta) normalized for the quadrupolar deformation. The derivation stems from expanding the gravitational potential in spherical harmonics and balancing it against the geopotential to find the equipotential surface that the ocean follows. A similar but smaller term applies for the Sun, scaled by its mass and greater distance. This model predicts two symmetric tidal bulges: one facing the and one on the opposite side of , resulting from the differential gravitational pull and the due to the Earth-Moon orbital motion. As Earth rotates beneath these fixed bulges with a matching the lunar orbital cycle, locations experience two high tides and two low tides per (approximately 24 hours and 50 minutes), producing a purely semidiurnal tide with highs and lows separated by about 6 hours and 12 minutes. Despite its conceptual elegance, the equilibrium tide theory has significant limitations, as it neglects the complexities of real dynamics. The predicted maximum is unrealistically small, around 0.5 meters for the lunar contribution, compared to observed ranges of 1 to 10 meters or more in many coastal areas. This discrepancy arises because the model assumes an idealized, global without continents, shallow depths, or frictional dissipation that amplify tides in reality.

Dynamic Tide Theory

The dynamic theory of tides provides a more realistic framework for understanding tidal behavior by incorporating the effects of , basin geometry, and frictional forces, which the equilibrium theory overlooks. Unlike the equilibrium model, which assumes an instantaneous global response to gravitational forces, the dynamic approach treats tides as propagating waves influenced by shallow water dynamics, where wave speed is determined by c = \sqrt{gH} with g as and H as depth. This propagation is governed by shallow water wave equations that account for variations in depth and continental boundaries, which impose reflective conditions that shape tidal patterns. Additionally, the deflects tidal crests— to the right in the and to the left in the Southern—leading to rotational wave propagation and lags relative to the direct lunar or solar forcing. A central feature of dynamic tide theory is the formation of amphidromic systems in ocean basins, where tidal crests rotate around a central node () with minimal , while cotidal lines—connecting points of simultaneous high water—radiate outward like spokes. In the , this rotation is counterclockwise around the node, driven by the Coriolis effect and coastal Kelvin that propagate with the coast on the right; the opposite occurs in the . These systems arise from the interaction of incoming with basin boundaries, resulting in co-rotating patterns that explain regional variations, such as the progression of high tide times across the North Atlantic. Basin dimensions further modify tidal amplitudes through resonance effects, where certain tidal frequencies align with natural oscillation modes, amplifying waves akin to seiches in semi-enclosed waters. For instance, the exhibits quarter-wave resonance for semi-diurnal tides, as its length approximates one-quarter of the wavelength, enhancing amplitudes in the southern bight through constructive with incoming Atlantic tides. This resonance depends on factors like width and depth, which influence wave speed and frictional damping, leading to pronounced tidal ranges in resonant areas compared to non-resonant ones. In contrast to the theory's direct response, dynamic tides operate as co-oscillating forced , where basins respond to periodic forcing from adjacent open s, delayed by time and modified by local geography. This results in tides that are not globally synchronous but vary in timing and , with differences that can span hours across continents.

Mathematical Formulations

The mathematical formulations for tidal dynamics are grounded in the linearized shallow-water equations, adapted to include the forcing potential. These equations, known as Laplace's tidal equations, describe the evolution of sea surface height and horizontal velocities in a rotating frame on a , assuming hydrostatic balance and shallow depth relative to the . The in its linearized form is \frac{\partial \eta}{\partial t} + H \nabla \cdot \mathbf{u} = 0, where \eta is the sea surface elevation anomaly, H is the mean water depth, and \mathbf{u} is the depth-integrated horizontal velocity vector. The momentum equations are \frac{\partial \mathbf{u}}{\partial t} - f \hat{k} \times \mathbf{u} + g \nabla \eta = -\nabla \Phi, with f = 2 \Omega \sin \phi as the Coriolis parameter (\Omega is Earth's angular velocity and \phi the latitude), g the gravitational acceleration, and \Phi the tidal potential arising from lunar and solar gravitational perturbations. These equations neglect nonlinear advection and bottom friction in their basic form but can be extended accordingly. Solutions to Laplace's tidal equations for global tides are obtained by into normal modes, which represent free oscillations of the under the linearized system. Assuming time-harmonic forcing e^{-i \sigma t} (where \sigma is the tidal frequency), the equations decouple into spatial eigenfunctions for elevation and velocity fields on the sphere. These modes, often expanded in , capture the resonant structure of basin-scale tides, with eigenvalues determining the equivalent depths and phase speeds for each mode. The forced response combines these modes to match observed tidal patterns, enabling representation of semidiurnal (e.g., M_2) and diurnal constituents. Tidal dissipation arises primarily from frictional processes in the equations, converting barotropic energy into internal and , with a global average rate of approximately 3.7 terawatts (TW). This energy loss is parameterized by the tidal quality factor [Q](/page/Q), defined as the ratio of the maximum energy stored in the to the energy dissipated per tidal cycle, where lower [Q](/page/Q) indicates higher efficiency. For Earth's oceanic tides, effective [Q](/page/Q) values range from about 20 to 30, reflecting the phase lag between the tidal potential and response. Bathymetry introduces spatial variations in water depth H, altering the propagation of tidal waves through changes in phase speed c = \sqrt{gH}, which decreases over shallower regions. This depth gradient causes refraction of tidal wavefronts, analogous to Snell's law, bending rays toward shallower areas and amplifying amplitudes near coasts via energy conservation. Such effects are incorporated by solving the equations over variable H, leading to focusing or shadowing in complex topographies.

Historical Development

Ancient and Early Modern Observations

Ancient observations of tides date back to the Greek explorer in the 4th century BCE, who during his voyages to became the first recorded figure to link tidal movements to the phases of the , noting the regularity of high and low waters in regions like the Atlantic coasts. His accounts, preserved through later writers such as and , described extreme tidal ranges in areas such as the , where he reported rises of up to 80 cubits (about 35-40 meters), though likely exaggerated as actual maximum ranges in the region are around 15 meters, highlighting the phenomenon's variability and lunar correlation. In the 2nd century BCE, Seleucus of Seleucia proposed that tides were caused by the Moon's attraction, with tidal height varying with the Moon's distance from Earth. In the medieval period, Islamic scholars advanced empirical understanding of tidal periodicity. Abu Rayhan al-Biruni, in the , documented observations of tidal variations tied to lunar phases in his work Tahqiq ma li-l-Hind, noting how high tides corresponded to the Moon's position and attributing the to celestial influences, based on reports from coastal regions. Concurrently in Europe, the Venerable , writing in the early 8th century in De Temporum Ratione, provided one of the earliest systematic descriptions of semidiurnal tides, explaining their twice-daily cycle as synchronized with the Moon's orbit and recognizing that local phase differences caused variations across ports, such as those along the coasts. By the , practical records emerged in navigational aids, with diagrams like the late-12th-century Rota (tidal wheel) illustrating monthly tidal cycles aligned with lunar ages to assist sailors in ports facing significant ranges, including those in the and , where extreme tides necessitated careful timing for shipping. These empirical tools reflected accumulated port-specific observations, emphasizing the need for localized predictions amid the region's pronounced tidal bores and ranges exceeding 10 meters. In the 17th and 18th centuries, scientific observations gained precision through systematic surveys. Isaac Newton, in his Philosophiæ Naturalis Principia Mathematica (1687), offered the first gravitational explanation for tides, positing that the Moon and Sun's attractions deformed Earth's oceans into bulges, with interference patterns explaining semidiurnal cycles and regional variations. Building on this, Edmond Halley conducted detailed tidal surveys in the English Channel aboard the HMS Paramour in 1701, recording high-water times at multiple sites to map tidal propagation, producing the first empirical tidal chart that illustrated progressive wave delays from Land's End to the Thames, akin to early cotidal patterns. These efforts marked a shift from qualitative records to quantitative data essential for navigation in tidally complex areas like the Channel.

Evolution of Tidal Theory

The foundational explanation of tides as gravitational phenomena originated with in his 1687 work , where he described the tidal bulges on as resulting from the Moon's and Sun's gravitational pulls, incorporating a component in his equilibrium model; however, this model inaccurately assumed a static and overestimated tidal forces. In the late , advanced tidal understanding through his dynamic theory, developed between 1775 and 1778 and detailed in Mécanique Céleste (1799), which integrated hydrodynamics to account for and ocean responses, separating tides into diurnal, semidiurnal, and long-period components using a tidal potential framework. Early 19th-century refinements included Thomas Young's contributions in the 1810s, particularly his 1813 paper in Nicholson's Journal and entries in the Encyclopædia Metropolitana, which incorporated frictional effects to better explain tidal dissipation and irregularities in shallow waters. The mid-19th century saw William Thomson () introduce in 1867, building on Laplace's ideas to decompose tides into sinusoidal components for prediction, which facilitated the development of mechanical tide-predicting machines. In the 1920s, Arthur Doodson expanded this approach at the Liverpool Tidal Institute, identifying over 400 tidal constituents based on the lunar theory of E.W. Brown, enabling more precise global predictions through the Doodson-Legendre expansion. The advent of computers in the post-1960s era shifted focus to numerical models, simulating complex ocean dynamics and to refine dynamic theory beyond harmonic methods. Modern advancements have leveraged satellite altimetry, with the TOPEX/Poseidon mission launched in 1992 providing the first global tidal maps and validating models by revealing that about one-third of tidal energy dissipates in deep oceans rather than solely on continental shelves. Recent projections incorporate effects, showing that sea-level rise—observed at an average of approximately 3.7 mm/year from 1993 to 2023, with recent acceleration—will amplify tidal ranges and flooding risks in coastal regions by altering hydrodynamic interactions, with global models forecasting up to 10-20% increases in extreme sea levels by 2100 under high-emission scenarios.

Measurement and Prediction

Observational Methods

Tide gauges have long served as the primary instruments for measuring levels associated with tides. Traditional tide gauges often employed stilling wells, which are vertical pipes connected to the that dampen wave action to provide stable readings, typically measured via floats or staffs. These mechanical systems, dating back centuries, have largely been supplanted by sensors in modern setups. Contemporary tide gauges predominantly use sensors, either acoustic or hydrostatic, submerged below the surface to detect changes in corresponding to variations. The (NOAA) operates the National Water Level Observation Network (NWLON), comprising over 200 automated tide stations across the and territories, which collect continuous data using these sensors to monitor tides with high . To measure tidal currents, or tidal streams, acoustic Doppler current profilers (ADCPs) are widely utilized. These instruments emit acoustic pulses into the water column and analyze the Doppler shift in echoes reflected from particles or scatterers to determine current velocity profiles vertically and horizontally. ADCPs can be deployed in bottom-mounted, moored, or vessel-mounted configurations, enabling detailed mapping of tidal flow speeds and directions over depths ranging from shallow coastal zones to the open ocean. For instance, ship-mounted ADCPs have been employed to capture the spatial and temporal variations in tidal currents during complete tidal cycles, revealing phase differences and amplitude gradients in estuarine and shelf environments. Satellite-based observations have revolutionized global since the through radar altimetry missions in the Jason continuity series. These satellites, including Jason-1 (launched 2001), Jason-2 (2008), (2016), and Sentinel-6 (launched 2020), measure sea surface height (SSH) by calculating the two-way travel time of radar pulses reflected from the ocean surface, providing along-track with centimeter-level accuracy. The series has mapped signals across 95% of the ice-free ocean every 10 days, enabling the derivation of global constituents and mean variations influenced by tides. Complementing these, the Surface Water and Ocean Topography (SWOT) mission, launched in 2022, uses wide-swath interferometric altimetry to provide higher-resolution SSH measurements, enhancing mapping in coastal and riverine areas. Complementing altimetry, GNSS-equipped buoys offer real-time, localized SSH measurements by tracking the vertical position of the buoy's antenna using global navigation systems, achieving millimeter precision in dynamic coastal settings. These buoys are particularly valuable for validating and short-term fluctuations in areas inaccessible to fixed gauges. Tidal reference levels, or datums, are established to standardize measurements relative to fixed benchmarks. The Lowest Astronomical Tide (LAT) represents the lowest level of the predicted astronomical tide expected under average meteorological conditions over a 19-year (NTDE). These datums are computed through of long-term records, typically spanning at least 19 years to capture the full of lunar phases, ensuring statistical reliability in separating astronomical tides from other influences. NOAA's methodology involves averaging high and low waters after filtering non-tidal components, providing a consistent vertical for charting, , and scientific applications.

Analytical and Numerical Prediction

is a fundamental method for tide prediction, involving the decomposition of observed water level time series into sinusoidal components known as tidal constituents. These constituents correspond to specific astronomical frequencies arising from the gravitational interactions of the , , and Sun, as well as nonlinear effects in shallow waters. The process employs least-squares fitting to determine the amplitudes and lags (epochs) of these constituents from historical data, minimizing the squared residuals between observed and modeled values. This simultaneous fitting of multiple constituents accounts for overlapping frequencies through nodal corrections and related adjustments, enabling the generation of harmonic constants essential for forecasting. The technique, refined by organizations like NOAA's Center for Operational Oceanographic Products and Services (CO-OPS), typically analyzes data over periods ranging from 29 days to 19 years to resolve up to 149 constituents, depending on data length and location-specific dynamics. A historical variant, the Admiralty method, developed for practical tidal forecasting, uses precomputed harmonic constants from short observation series (15–29 days) to predict hourly heights at ports worldwide. Detailed in the Admiralty Manual of Tides, this approach fits basis functions to data via least-squares principles, incorporating satellite-derived adjustments for modern applications, and remains influential for its efficiency in operational settings like . Numerical modeling complements by solving the governing equations of tidal motion on spatial grids, particularly for regions where local and coastline geometry introduce complexities beyond simple sinusoidal sums. These models solve the shallow-water equations—linearized forms of the Navier-Stokes equations for barotropic flow—using finite-difference schemes to simulate propagation, friction, and dissipation across global or regional domains. The TPXO series, for instance, represents a widely used global model that assimilates satellite altimetry data (e.g., from TOPEX/Poseidon) into a finite-difference barotropic , yielding high-resolution elevations and currents with errors below 3 cm in open oceans. Such models provide boundary conditions for regional simulations and improve predictions in data-sparse areas by incorporating physics-based dynamics. Short-term tide predictions, typically spanning days to months, rely on precomputed harmonic constants to generate tide tables, which list predicted high and low water times and heights at specific stations. NOAA produces these tables for over 3,000 U.S. locations by summing the contributions of 37 primary constituents, updated annually to reflect minor observational refinements. Real-time adjustments for meteorological influences, such as storm surges or wind-driven setup, are applied operationally through systems like the Physical Oceanographic Real-Time System (PORTS), which overlay harmonic predictions with nowcasts from coupled hydrodynamic models to account for non-tidal residuals. For long-term predictions extending years or decades, harmonic methods incorporate secular variations, notably the 18.6-year lunar , which modulates tidal amplitudes and phases through factors f and u in the prediction formula. This , arising from the precession of the Moon's orbital , causes gradual changes in diurnal inequality and range, requiring updates to constants every 19 years to align with the National Tidal Datum Epoch used by NOAA. Almanacs, such as the U.S. published by the U.S. Naval Observatory, integrate these adjustments into extended forecasts, ensuring consistency with astronomical ephemerides for applications like coastal planning.

Practical Examples and Calculations

One practical example of tidal prediction involves calculating the approximate time of high tide at a specific location using the dominant semidiurnal constituents (principal lunar) and (principal solar), which together account for much of the tidal variation in many coastal areas. For , on September 1, 1991, the M2 constituent has an amplitude of 3.185 feet and a phase of -127.24 degrees relative to a reference time of midnight, while the S2 has an amplitude of 0.538 feet and a phase of -343.66 degrees. The height contribution from each is given by h_{M2} = A_{M2} \cos(\omega_{M2} t + \phi_{M2}) and h_{S2} = A_{S2} \cos(\omega_{S2} t + \phi_{S2}), where \omega_{M2} = 28.984^\circ/hour (period T_{M2} = 12.42 hours) and \omega_{S2} = 30^\circ/hour (period T_{S2} = 12 hours). To find the time of high tide dominated by M2, solve \omega_{M2} t + \phi_{M2} = 0^\circ (mod $360^\circ), yielding t = -\phi_{M2} / \omega_{M2} \approx 127.24 / 28.984 \approx 4.39 hours after midnight, or roughly 4:23 AM; the S2 contribution shifts this slightly depending on alignment, but for spring tides when phases align, the total height peaks near this time. A notable case study is the in , where the reaches up to 16 meters due to in the Gulf of Maine-Fundy basin, which amplifies the incoming tidal wave near the natural period of the system (approximately 13.3 hours for semidiurnal tides). This resonance boosts the amplitudes of constituents like M2 and S2; for instance, at the head of the bay in , the M2 amplitude can exceed 7 meters, compared to less than 1 meter in the open Atlantic. The total water level is approximated as h(t) = A_{M2} \cos(\omega_{M2} t + \phi_{M2}) + A_{S2} \cos(\omega_{S2} t + \phi_{S2}), where during spring tides, constructive interference yields heights up to 8 meters above mean , resulting in the observed 16-meter range from low to high tide. Tidal predictions can deviate from astronomical models due to non-astronomical factors, such as storm surges driven by and , which can alter water levels by tens of centimeters through tide-surge interactions and superelevation. These meteorological effects introduce errors that oscillate over time, particularly during high-wind events, and are not captured in pure harmonic predictions. For everyday use, modern tools like the free XTide software enable users to generate accurate tidal predictions by applying to global datasets, producing graphs, tables, and calendars for any location without manual computation. XTide relies on established constituent data from sources like NOAA and supports predictions far into the future or past.

Practical Applications

Navigation and

Tidal currents, driven by the rise and fall of tides, present significant navigational challenges for maritime vessels, particularly in regions with strong tidal streams such as the , where speeds can reach up to 5 knots (approximately 2.6 m/s) during peak flows. These currents can alter a vessel's course, reduce effective speed over ground, and complicate maneuvering, especially in narrow channels or during docking, necessitating precise planning to avoid grounding or collision. Mariners rely on tide tables, which provide predicted times and heights of high and low tides as well as current directions and speeds, to determine safe passage windows and adjust routes accordingly. For instance, crossings in the often require vessels to time departures with favorable tidal streams to maintain efficiency and safety, using tools like numerical models for real-time adjustments. In harbor design, tidal ranges dictate the need for to maintain navigable depths during , creating "tidal windows" for larger ships to enter or exit without risking stranding. Ports in tidal estuaries, such as those on the River Thames, incorporate locks and barriers to manage fluctuating water levels and facilitate safe transit. The , for example, features ten navigable spans and associated locks that allow vessels to pass during operational closures, ensuring continuous access while protecting against high tides. These structures are engineered to accommodate typical tidal ranges of 6-7 meters in the , with operations routinely maintaining channel depths to support commercial traffic. Safety concerns in tidal waters include hazards like tidal bores—sudden upstream surges of water that can capsize small craft—and rip currents enhanced by outgoing tides, which pull swimmers and lightweight vessels seaward at speeds exceeding 2 meters per second. Notable examples include the in the UK, where bore heights up to 2 meters create turbulent conditions hazardous for navigation outside designated times. International standards from the (IHO) mandate the inclusion of tidal predictions on nautical charts, specifying cotidal lines and current data to inform mariners of these risks and promote safer passage. Compliance with IHO S-44 survey standards ensures that charted tidal information meets accuracy requirements for safe navigation in varying coastal environments. Coastal engineering addresses tidal influences through structures like breakwaters and seawalls, designed to mitigate by accounting for ranges and associated wave action. Detached breakwaters, for instance, are positioned to interrupt longshore and reduce wave energy on beaches, with effectiveness varying by regime—suitable for shingle beaches across all ranges but limited on in macro- areas exceeding 4 meters. Seawalls, often constructed with curved or stepped faces, incorporate toe protection such as or gabions to prevent scour from currents and breaking , with crest elevations set above high water plus to withstand overtopping. In the U.S., the U.S. Army Corps of Engineers guidelines emphasize filters and aprons in seawall designs to handle fluctuations, as seen in projects like the , where structures rise 17 feet above the base to counter surges and in an area with minimal ranges of about 0.5 meters. These measures stabilize shorelines by dissipating wave forces and limiting sediment loss during ebb and flood cycles.

Tidal Energy Generation

Tidal energy generation harnesses the predictable movements of ocean tides to produce renewable electricity, primarily through the capture of potential and kinetic energy. Potential energy arises from the vertical rise and fall of sea levels during high and low tides, which can exceed 12 meters in some locations, and is typically converted using structures like barrages or lagoons that impound water and release it through turbines to drive generators. Kinetic energy, on the other hand, is derived from the horizontal flow of tidal currents during flood and ebb phases, extracted via submerged turbines that rotate under the force of moving water. These principles enable continuous power output aligned with tidal cycles, distinguishing tidal energy from intermittent sources like solar or wind. Key technologies include horizontal-axis tidal stream turbines, which resemble underwater wind turbines and operate efficiently in currents exceeding 2 meters per second, achieving power conversion efficiencies of approximately 20-40% depending on design and site conditions. A notable example is the turbine, a 1.2 MW horizontal-axis system with twin 16-meter rotors deployed in , , in 2008 and operated until 2016, which demonstrated reliable grid-connected operation and served as a for commercial-scale stream energy extraction. Tidal lagoons represent an alternative for potential energy capture, consisting of offshore enclosures with turbines embedded in their walls; unlike shore-connected barrages, lagoons can be positioned flexibly in coastal waters to minimize land-based disruption while generating power bidirectionally during tidal filling and emptying. Prominent projects illustrate the scalability of these technologies. The in , operational since 2011, is the world's largest installation at 254 MW capacity, utilizing a barrage across an artificial lake to generate for over 500,000 households through ten 25.4 MW turbines. In , the MeyGen project in the reached 6 MW in its Phase 1 demonstration array by 2018, comprising four 1.5 MW horizontal-axis turbines on gravity foundations, with Phase 1A operational since 2018 and expansions planned but delayed as of 2025, aiming toward 398 MW total. Globally, the technically harvestable tidal resource is estimated at around 1 TW near coastal areas, sufficient to meet a significant portion of worldwide if fully developed. Despite these advancements, tidal energy faces substantial challenges, including high capital costs—such as over USD 3,000/kW for large barrages—and environmental effects like altered that can impact coastal ecosystems and navigation. Recent studies as of 2025 indicate that while wakes may influence local hydrodynamics, widespread ecological disruption fears are often overstated, though site-specific monitoring remains essential. Emerging floating tidal systems address deployment hurdles in deeper waters; for instance, Orbital Marine Power's platform, a 2 MW floating horizontal-axis deployed in since 2021, has advanced commercialization, with ongoing efforts including potential U.S. sites as of 2025.

Ecological and Biological Impacts

Intertidal Ecosystems

The intertidal zone, shaped by the rhythmic submersion and exposure due to tides, is divided into distinct vertical zones based on the duration and frequency of tidal inundation. The supralittoral or splash zone lies above the highest high tide mark, experiencing only spray from waves, where desiccation-resistant species like lichens and certain algae predominate, with barnacles such as Balanus glandula exhibiting adaptations like tight shell closure to minimize water loss during prolonged air exposure. The midlittoral or intertidal zone is alternately submerged and exposed by average tides, supporting a diverse array of organisms including mussels (Mytilus californianus), sea stars (Pisaster ochraceus), and macroalgae like Fucus species, which have evolved tolerances to fluctuating salinity and temperature. Below this, the sublittoral or lower intertidal fringe remains submerged most of the time except during extreme low tides, hosting kelp beds and mobile invertebrates like crabs and anemones that are adapted to near-constant immersion but occasional aerial exposure. These zonation patterns are primarily determined by tidal range and exposure gradients, creating sharp boundaries in species distribution that reflect selective pressures from tidal cycles. Intertidal ecosystems harbor exceptional , with complex food webs anchored by primary producers such as , seaweeds, and epiphytic that form the base for herbivores like snails and limpets. , including , worms, and bivalves, serve as intermediaries, preyed upon by carnivores such as predatory whelks and shore , while birds like and plovers on exposed mudflats and rocky shores, linking intertidal to terrestrial and trophic levels. These interactions foster , as seen in rocky shores where mussel beds provide for over 100 associated , enhancing overall community stability. flushing plays a critical role in cycling, importing dissolved and from adjacent coastal waters during high tide and exporting waste, which sustains high productivity rates in productive systems like salt marshes. This dynamic exchange prevents limitation, supporting detrital pathways where decomposed fuel microbial communities and subsurface food chains. Human activities exacerbate tidal stresses in intertidal habitats, with pollution from introducing contaminants like and plastics that bioaccumulate in filter-feeding , disrupting dynamics and reducing in affected areas. Habitat loss from coastal development, such as shoreline armoring and , fragments zonation patterns and amplifies during tidal cycles, leading to the decline of foundational species like oysters in estuarine intertidal zones. efforts, including the establishment of protected areas (MPAs), mitigate these impacts by restricting and restoring natural tidal flows; for instance, MPAs along California's have increased invertebrate densities through reduced trampling and harvesting. Climate change, particularly accelerating sea-level rise, is reshaping intertidal zonation by compressing habitable space and shifting distributions upward, with low-lying zones like mudflats potentially losing 10-20% of area per decade in vulnerable regions. In mangrove-dominated intertidal systems, rising waters have driven seaward migration at rates of 18 m/year in some Southeast Asian sites, offsetting inland habitat loss but exposing new areas to salinity stress and . A 2022 study in documented mangrove expansion into former salt marsh zones at 9.41 mm/year sea-level rise rates, altering by favoring salt-tolerant while threatening freshwater-dependent communities. Similarly, 2025 analyses of ecosystems revealed mixed responses, with mangrove shifts reducing in some wetlands by altering tidal inundation patterns. These changes highlight the need for to preserve intertidal resilience amid ongoing tidal alterations.

Circatidal Rhythms in Organisms

Circatidal rhythms are endogenous biological clocks in marine organisms that approximate the 12.4-hour cycle, enabling of and even in constant conditions. These rhythms are entrained by environmental zeitgebers such as hydrostatic changes, fluctuations, and water flow, allowing intertidal to synchronize behaviors like feeding, , and burrowing with phases. In fiddler crabs (Uca spp.), circatidal rhythms drive swarming and foraging activity, with peaks during low tide exposure when crabs emerge from burrows to feed, persisting as free-running cycles of approximately 12.4 hours in laboratory conditions without tidal cues. Similarly, in reef-building corals (Acropora spp.), these rhythms entrain spawning events, where gamete release is timed to coincide with outgoing tides shortly after sunset, ensuring larval dispersal; the semidiurnal tidal immersion cycle acts as a key entrainer alongside diurnal light cues. Mechanisms underlying involve sensory detection of signals, including mechanoreceptors that respond to water and variations, which reset the internal clock to maintain with local tides. Lunar cues, particularly intensity and timing, further synchronize these rhythms by modulating circalunidian (24.8-hour) cycles that interact with the circatidal clock, enhancing precision across lunar phases. Representative examples illustrate behavioral adaptations tied to these rhythms. fish (Leuresthes tenuis) undertake spawning runs on sandy beaches during the highest spring tides, three to four nights after full or new moons, when females deposit eggs in damp sand wetted by receding waves, with males fertilizing them in a brief, synchronized event. In oysters ( spp.), valve opening and filter-feeding peak during immersion at high tide, governed by circatidal components in their genes that can oscillate at tidal frequencies under . Evolutionarily, circatidal rhythms confer survival advantages by optimizing during nutrient-rich low tides while minimizing exposure to predators during high tides, and facilitating when larvae face reduced predation risk in dispersing currents. These adaptations likely arose in intertidal ancestors to exploit predictable tidal predictability, enhancing in dynamic coastal environments. However, anthropogenic disruptions such as artificial light at night (ALAN) can desynchronize these rhythms; for instance, in corals, ALAN shifts spawning one to three days closer to the , potentially reducing fertilization success by misaligning with optimal flows. In fiddler crabs and oysters, ALAN alters activity peaks and valve behaviors, impairing energy acquisition and increasing vulnerability to predators.

Related Phenomena

Earth and Solid Tides

Solid Earth tides refer to the elastic deformations of the planet's crust induced by the differential gravitational attractions of the and Sun, resulting in periodic vertical and horizontal displacements of the surface. These tides cause the to bulge and recede twice daily, with maximum vertical displacements reaching up to 40 cm, primarily at equatorial latitudes. Such deformations are measured using highly sensitive instruments, including superconducting gravimeters, which detect associated gravity variations with amplitudes of several hundred microgals, and GPS receivers for direct displacement observations. The elastic response of the Earth to tidal forcing is quantified by the Love and Shida numbers, which describe the ratios of induced displacements and potential perturbations to the applied tidal potential. For the dominant degree-2 tidal harmonics, the vertical Love number h_2 is approximately 0.60, indicating that the actual vertical displacement is about 60% of the equilibrium tide height, while the horizontal Shida number l_2 is around 0.08, reflecting smaller lateral shifts. These values, derived from models like the (PREM), account for the Earth's layered structure and are essential for interpreting observational data. Globally, tides exhibit semidiurnal dominance, with the principal lunar constituent M_2 (period of approximately 12.42 hours) accounting for the largest amplitudes, up to about 30 cm vertically near the . This pattern arises from the of the tidal bulge with the Moon's and varies latitudinally as \sin^2 \theta, where \theta is the . In applications, solid Earth tide models are critical for correcting geodetic measurements, such as those from GPS and very long baseline interferometry, where uncorrected tidal displacements can introduce errors exceeding 30 cm in vertical positions. They also inform earthquake monitoring by revealing how tidal stresses modulate fault slip, with studies linking semidiurnal peaks to increased seismicity rates. Additionally, these tides interact with ocean loading effects, where redistributed ocean water masses amplify crustal deformations by up to 10-20% in coastal regions, necessitating combined models for precise geophysical analysis.

Atmospheric and Oceanic Tides

Atmospheric tides manifest as global-scale oscillations in , temperature, and winds, primarily exhibiting diurnal (24-hour) and semidiurnal (12-hour) periodicities. These tides are driven predominantly by the differential heating of the Earth's atmosphere, which causes and contraction, rather than gravitational forces from the or Sun. The semidiurnal component, often the most prominent at , produces variations with amplitudes typically around 0.5 millibars (), detectable worldwide but strongest in tropical regions due to insolation. This forcing excites waves that propagate vertically and horizontally, influencing the middle and upper atmosphere up to altitudes of about 100 km, where absorption further amplifies the semidiurnal tide around 50 km. In contrast to oceanic tides, which are mainly gravitational, atmospheric tides are thermal in origin, with the migrating diurnal tide (denoted as S1) arising from longitudinal variations in solar heating due to land-sea thermal contrasts and topography. The S1 tide propagates westward with the Sun's apparent motion (zonal wavenumber s = -1), achieving pressure amplitudes of approximately 0.5–0.7 mb over continental areas, where sensible heat fluxes from sun-warmed land enhance the response, compared to weaker oceanic signatures. Gravitational lunar influences contribute only marginally to these tides, typically less than 10% of the solar thermal forcing, making atmospheric tides distinct from the lunisolar-driven oceanic cycles. The coupling between atmospheric and oceanic tides occurs through wind-driven setup and pressure loading, where variations and surface winds alter sea surface heights, often amplifying or modifying oceanic responses. Low-pressure systems reduce overlying air weight, causing inverse effects that raise sea levels by about 1 cm per mb drop, while winds pile water against coastlines, contributing to setups of several meters during storms. The Sea, Lake, and Overland Surges from Hurricanes (SLOSH) model, developed by the (NOAA), numerically simulates these interactions by solving shallow-water equations with parametric wind and pressure fields to forecast storm surges, aiding coastal flood predictions with resolutions down to 200 meters. Observations of atmospheric tides rely on ground-based barometers, which have recorded semidiurnal pressure oscillations since the , revealing global patterns tied to heating and confirming amplitudes of 0.3–0.7 mb in the . altimetry and gravimetry missions, such as and Jason series, provide complementary global views by measuring sea surface height perturbations from atmospheric loading and internal tide responses, highlighting influences on large-scale circulation like the . These datasets demonstrate how atmospheric tides modulate tropospheric winds and contribute to interannual variability in global circulation patterns.

Inland and Lake Tides

Inland tides manifest in enclosed water bodies such as large lakes and rivers, where gravitational forces from the and Sun induce subtle water level fluctuations independent of oceanic influences. These effects arise primarily from direct tidal potential—the gravitational gradient across the water body—combined with barometric changes that alter water density and level via the inverted . In lakes, these mechanisms produce seiche-like oscillations, where the water surface responds resonantly to periodic loading, though amplitudes remain minimal due to the basins' limited size and frictional damping. Lake tides are characteristically small, often on the centimeter scale, as the enclosed nature of these basins prevents amplification from coastal resonance seen in . For instance, in , the principal lunar semidiurnal M2 tidal constituent exhibits an amplitude of about 5 cm, driven solely by astronomical forcing without any oceanic propagation. Similarly, other show tidal responses under 5 cm, frequently overshadowed by larger meteorological variations like wind setup or seiches. These tides follow semidiurnal and diurnal cycles but contribute only marginally to overall water level dynamics in such systems. In river systems, particularly estuaries, tidal effects propagate upstream from the , creating progressive that can form pronounced bores in funnel-shaped channels with strong tidal ranges. The exemplifies this, where the incoming tide generates a bore known as the , reaching heights exceeding 4 m and traveling hundreds of kilometers inland before damping due to channel friction and bed roughness. This upstream propagation diminishes with distance, as energy dissipates through and width variations, limiting significant tidal influence to the lower reaches. Studies of Great Lakes tides reveal long-term modulations, including the 18.6-year lunar nodal cycle, which tilts the Moon's and varies tidal forcing amplitudes by up to 20% over this period. Observations from lake-level gauges confirm these nodal variations in the small tidal signals, influencing mean water levels on decadal scales alongside climatic factors. Such cycles have practical implications for water management, as they affect long-term forecasting for , coastal , and ecosystem in the , where precise level predictions mitigate risks to shipping and water diversion.

References

  1. [1]
    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.
  2. [2]
    What Causes Tides? | NESDIS - NOAA
    The Short Answer. High and low tides are caused by the moon. The moon's gravitational pull generates something called the tidal force. The tidal force causes ...
  3. [3]
    Tides - NASA Science
    The Moon's gravitational pull plays a huge role in the formation of tides. Tides are a cycle of small changes in the distribution of Earth's oceans.
  4. [4]
    What are spring and neap tides? - NOAA's National Ocean Service
    Jun 16, 2024 · Tides are long-period waves that roll around the planet as the ocean is "pulled" back and forth by the gravitational pull of the moon and the ...
  5. [5]
    The Influence of Position and Distance - Tides and water levels
    The moon is a major influence on the Earth's tides, but the sun also generates considerable tidal forces. Solar tides are about half as large as lunar tides.Missing: importance | Show results with:importance
  6. [6]
    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.
  7. [7]
    Tides | National Oceanic and Atmospheric Administration
    Sep 17, 2025 · When we observe the tides what we are actually seeing is the result of the earth rotating under this bulge. Flooding in Norfolk, Virginia, on ...
  8. [8]
    Tides and Currents - NOAA's National Ocean Service
    We need accurate tide and current data to aid in navigation, but these measurements also play an important role in keeping people and the environment safe.Missing: types | Show results with:types
  9. [9]
    What are tides? - NOAA's National Ocean Service
    Jun 16, 2024 · Tides are caused by gravitational pull of the moon and the sun. The rise and fall of the tides play an important role in the natural world and ...
  10. [10]
    [PDF] Tidal datums and their applications - NOAA Tides and Currents
    Jun 23, 2000 · There are three basic types of tides: semidiurnal (semi-daily), mixed, and diurnal (daily). The first type, semidiurnal (Figure 1, top), has two ...
  11. [11]
    [PDF] Mesoscale Modeling of Sedlrnent Transport and lNorphologlc ...
    by tide range using the terms micro, meso, and macro to distinguish tide ranges of 0 2 rn, 2 4 m, and > 4 m, respectively. Hayes 979! used this breakdown ...
  12. [12]
    JetStream Max: Bay of Fundy: The Highest Tides in the World - NOAA
    Apr 14, 2023 · Along the Atlantic side of Nova Scotia, outside of the Bay of Fundy, the tidal range is from four to eight feet (1½-2½meters) and without much ...
  13. [13]
    [PDF] Salinity characteristics of Gulf of Mexico estuaries
    mean tidal range along the upper Gulf coast is on the order of 0.5 m, about three-quarters of which is diurnal. Diurnal tides vary substantially with the moon's.
  14. [14]
    [PDF] Computational Techniques for Tidal Datums Handbook
    There are three basic types of tides: semidiurnal (twice-daily), mixed (also twice-daily), and diurnal (daily) (Figure 1). The first type, semidiurnal, has two ...
  15. [15]
    Frequency of Tides - The Lunar Day - Tides and water levels
    Coastal areas experience two high and two low tides every 24 hours and 50 minutes. High tides occur 12 hours and 25 minutes apart.
  16. [16]
    Detailed Explanation of the Differential Tide Producing Forces
    The tide-raising forces at the earth's surface thus result from a combination of basic forces: (1) the force of gravitation exerted by the moon (and sun) upon ...Missing: definition | Show results with:definition<|separator|>
  17. [17]
    OC2910 - Tides: Basic Concepts and Terminology
    When the sun and moon are at right angles to each other (in quadrature), you have neap tides, which have relatively small tidal ranges. When the sun and moon ...
  18. [18]
    [PDF] CHAPTER 8 COASTS
    Tides with the greater tidal ranges are called spring tides (no relation to the spring season of the year!), and tides with the smaller tidal ranges are called ...
  19. [19]
    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.
  20. [20]
    Gravity, Inertia, and the Two Bulges - Tides and water levels
    The moon's gravity pulls water towards it, creating a bulge on the near side. On the far side, inertia causes a bulge as water tries to move away.
  21. [21]
    [PDF] Equilibrium Tides
    This centrifugal force is balanced by the moon's gravitational attraction. But the moon's gravity is not the same everywhere on the earth. For one thing, it is.
  22. [22]
    Tidal Elongation - Richard Fitzpatrick
    Thus, the tidal elongation due to the Sun is about half that due to the Moon. It follows that the tides are particularly high when the Sun, the Earth, and the ...
  23. [23]
    [PDF] 6.8. 201 d) From part c) Flunar tidal = GMMoonm 2R d3
    Hence the magnitude of the lunar tidal force on m is about 2.2 times larger than the solar tidal force on m. In fact, the Earth is the only planet in the solar ...
  24. [24]
    Chapter 3 Earth Tides and Tidal Deformations - ScienceDirect.com
    The ratio of lunar to solar tidal attractions can be determined from ... lunar attraction is therefore about 2.2 times greater than the solar attraction.
  25. [25]
    [PDF] chapter 2 - the tide-raising forces
    GS/(r-e)², at A' it is GS/(r+e)², and at B and B' it is. GS/(r² + e²), where e is the earth's radius. All the attractions are directed from the point toward ...
  26. [26]
    [PDF] PASI Tide Lecture
    Jan 13, 2013 · A lunar day is therefore 24 hours 50 minutes long. Because Earth must turn an additional 50 minutes for the same tidal alignment, lunar tides.
  27. [27]
    Reflections over Neap to Spring Tide Ratios and ... - AMS Journals
    In the deep ocean the neap to spring ratio varies generally between 0.3 and 0.4, but tends to become larger in shelf seas. Extreme values approaching 0.8 or ...
  28. [28]
    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.
  29. [29]
    Chapter 4 - Variations in the Ranges of the Tides: Tidal Inequalities
    Chapter 5 - Factors Influencing the Local Heights and Times of Arrival of the Tides ... The range of the tides at any location is subject to many variable factors ...Missing: geography | Show results with:geography
  30. [30]
    [PDF] Tidal Analysis and Predictions - NOAA Tides and Currents
    ... Types of Graphs. 229. 7.2 Spatial Variation in Tidal and Tidal Current ... examples of such problems are very briefly mentioned below (they are explained.
  31. [31]
    About Harmonic Constituents - NOAA Tides & Currents
    ... 50 minutes to “catch up” to the Moon. This results in a tidal signal (M2) which has 2 peaks every 24-hours and 50 minutes. S2 – The largest solar ...
  32. [32]
    [PDF] CHAPTER I: TIDAL FORCES
    of the tide producing forces between apogee and perigee. The ratio of the tidal forces at apogee and perigee is 1.4:1 for the moon and 1.11:1 for the sun.
  33. [33]
    Factors Influencing the Local Heights and Times of Arrival of the Tides
    Topography on the ocean floor can also provide a restraint to the forward movement of tidal waters - or create sources of local-basin response to the tides.
  34. [34]
    Formulation of a new explicit tidal scheme in revised LICOM2.0 - GMD
    Jun 1, 2022 · Ftide,m≈32MmE(aD ... With the global total tidal height at zero, cos2Θ=1/3 . Therefore, the instantaneous tidal height is. ηtide,m=Mm ...<|separator|>
  35. [35]
    [PDF] Tides - UHSLC
    Tidal waves rotate around amphidromic points, where tidal range is minimum and increases radially outward. • Co-range lines link areas with the same tidal.
  36. [36]
    11.1 Tidal Forces – Introduction to Oceanography
    This represents Newton's Equilibrium Theory of Tides, where there are two high tides and two low tides per day, of similar heights, each six hours apart. But as ...Missing: assumptions derivation<|control11|><|separator|>
  37. [37]
    [PDF] Tide Dynamics
    Dynamic Theory of Tides.​​ Laplace first rearranged the rotating shallow water equations into the system that underlies the tides, now known as the Laplace tidal ...
  38. [38]
    11.2 Dynamic Theory of Tides – Introduction to Oceanography
    The moon oscillates between 28.5o north and 28.5o south of the equator every two weeks, leading to uneven tidal heights each day at a particular latitude (PW).Missing: lunar | Show results with:lunar
  39. [39]
    An idealized model of tidal dynamics in the North Sea
    Jul 19, 2011 · As can be seen from the co- tidal chart in Fig. 5a, the first peak is associated with a quarter wavelength resonance of the Kelvin mode in the ...
  40. [40]
    The Vector Harmonic Analysis of Laplace's Tidal Equations - SIAM.org
    A modal analysis is presented of the linearized shallow-water equations on the sphere called Laplace's tidal equations, using the spherical vector harmonics.
  41. [41]
    Shallow-water wave theory - Coastal Wiki
    May 12, 2025 · This article explains some theories of periodic progressive waves and their interaction with shorelines and coastal structures.Missing: linearized | Show results with:linearized
  42. [42]
    Pytheas | Macedonia, Massalia & Voyages - Britannica
    Oct 13, 2025 · He also observed that the polestar is not at the true pole and that the Moon affects tides. ... The 4th century · To the King's Peace (386 bce).
  43. [43]
    On the Ocean: The Famous Voyage of Pytheas
    Jul 14, 2017 · It is a firsthand account of Pytheas's voyage and contains a multitude of astronomical, geographic, biological, oceanographic, and ethnological ...Missing: 4th | Show results with:4th
  44. [44]
    [PDF] Abu Rayhan al-Biruni - Target Exploration
    He noted that Hindus relate tides to phases of the moon, although the cause was unknown. •. Gems -- The work was written late in Biruni's life, during ...
  45. [45]
    [PDF] A concise history of the theories of tides, precession-nutation and ...
    In the beginning of the 8th century Bede discovered the phase lag of the ocean tides, realizing that each port had its own tidal phase.
  46. [46]
    Tidal Diagram (Rota), late 12th century. Acquired by Henry Walters ...
    This wheel-shaped diagram illustrates the monthly movement of the tides, and shows the correspondences between the tides and the age of the Moon.
  47. [47]
    Halley's Tidal Chart - jstor
    how the observations were taken. The observations on which the chart was based were carried out in 1701 between June and October on the Admiralty "pink" ...
  48. [48]
    Dictionary of National Biography, 1885-1900/Young, Thomas (1773 ...
    Dec 28, 2020 · Young's 'Theory of the Tides,' given first in his 'Lectures' (p. 576), then in 'Nicholson's Journal' (1813), and more completely in the ' ...Missing: friction | Show results with:friction
  49. [49]
    25 years of global sea level data, and counting
    Aug 11, 2017 · Topex-Poseidon made the first global maps of tides, which changed scientists' understanding of how tides dissipate. The data show that a third ...
  50. [50]
    Climate-change–driven accelerated sea-level rise detected ... - PNAS
    Feb 12, 2018 · Satellite altimetry has shown that global mean sea level has been rising at a rate of ∼3 ± 0.4 mm/y since 1993. Using the altimeter record ...Missing: 1992 | Show results with:1992
  51. [51]
    The impact of future sea-level rise on the global tides - ScienceDirect
    Jun 15, 2017 · Sea-level rise (SLR) has been observed from tide gauges over the 20th century at an average rate of 1.7 mm/yr (Church and White, 2011) and by ...
  52. [52]
    [PDF] Manual on sea level measurement and interpretation, v. V
    This volume reviewed float and pressure tide gauges once again, but also introduced the new method of measuring sea level by means of reflection of an acoustic ...
  53. [53]
    What is a tide gauge? - NOAA's National Ocean Service
    Jun 16, 2024 · The older stilling well has been replaced with an acoustic sounding tube and the tidal staff with a pressure sensor.
  54. [54]
    Full article: NOAA's national water level observation network (NWLON)
    Nov 5, 2018 · NWLON is the foundation of a comprehensive system for observing, communicating, and assessing the impact of changing water levels nationwide.
  55. [55]
    Acoustic Doppler Current Profiler - NOAA Ocean Exploration
    Jun 22, 2020 · An acoustic Doppler current profiler, or ADCP, is a device that uses sound waves to measure the speed and direction of currents throughout ...
  56. [56]
    Understanding ADCPs: a guide to measuring currents, waves &…
    ADCPs are instruments that measure water velocity by using underwater acoustic technology. In a similar way to sonars, ADCPs transmit acoustic signals.Different Doppler processing... · ADCP frequency and profiling... · ADCP range cells
  57. [57]
    Acoustic Doppler Current Profiler measurements of tidal phase and ...
    Measurements from a ship mounted Acoustic Doppler Current Profiler (ADCP) over a single tidal cycle are used to determine the horizontal and vertical variation ...
  58. [58]
    Get Data - Ocean Surface Topography from Space - NASA
    This dataset contains along track Sea Surface Height Anomalies (SSHA) for individual 10-day cycles from the TOPEX/Poseidon, Jason-1, OSTM/Jason-2, and Jason-3 ...
  59. [59]
    JASON-3 | NESDIS | National Environmental Satellite, Data ... - NOAA
    Jason-3 will make highly detailed measurements of sea surface height, which is a measure used to study sea level rise—a critical factor in understanding Earth's ...
  60. [60]
    Development of GNSS Buoy for Sea Surface Elevation Observation ...
    Nov 11, 2023 · This study presents the development and testing of a global navigation satellite system (GNSS) buoy designed for measuring the sea surface elevation and tide ...
  61. [61]
    Development of a GNSS Buoy for Monitoring Water Surface ...
    Jan 18, 2017 · The field tests demonstrate that the developed GNSS buoy can be used to obtain accurate real-time tide and wave data in estuaries and coastal ...
  62. [62]
    [PDF] CHAPTER 5 WATER LEVELS AND FLOW - IHO
    British Charts now use a Chart Datum of Lowest Astronomical Tide (LAT) based on the lowest predicted tide expected to occur in a 19 year period.
  63. [63]
    [PDF] National Tidal Datum Epoch - NOAA Tides and Currents
    The NTDE is a 19-year time period used by NOAA to collect water level observations and calculate tidal datums. ... However, long-term sea level trends have shown ...Missing: records | Show results with:records
  64. [64]
    The Admiralty Manual of Tides - Internet Archive
    Dec 31, 2019 · The Admiralty Manual of Tides. by: Doodson, A.T. (Arthur Thomas), 1890-1968; Warburg, H.D. (Harold Dreyer), 1878-1947. Publication date: 1941.
  65. [65]
    Harmonic Analysis and Prediction of Tides
    The plot of M2 + S2 shows the combined tidal effect of this ideal sun and the ideal moon of the previous graph. M2+S2 for Bridgeport CT, September 1-28, 1991.
  66. [66]
    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.
  67. [67]
    Tidal Energy Estimates in the Bay of Fundy - Stanford
    Dec 17, 2022 · ... tidal system that is being forced near resonance to give extremely large tidal ranges. [3,4] Southern Nova Scotia is located on the bay of ...
  68. [68]
    [PDF] Lecture 4: Resonance and Solutions to the LTE - WHOI GFD
    The response of the Bay of Fundy and the Gulf of Maine implies a resonant period of about 13.3 hours and a Q, for M2, of about 5. On the west coast, the tidal ...
  69. [69]
    The Tides They Are A‐Changin': A Comprehensive Review of Past ...
    Dec 13, 2019 · Tidal properties have changed, and continue to evolve, due to nonastronomical factors Attributing causation remains challenging Regionally ...
  70. [70]
    XTide: Harmonic tide clock and tide predictor - FlaterCo
    Free tide software for Unix/X11 with ports to other platforms. Tide graphs, tide clocks, plain old text listings and more. Works great under Linux.
  71. [71]
    The UK's 11 fiercest tide races - Yachting Monthly
    Dec 18, 2020 · Breaking waves and lurking rocks have earned some British tide races a fearsome reputation. Dag Pike explains how to navigate them.The Uk's 11 Fiercest Tide... · 1. Portland Bill · 9. Pentland Firth<|separator|>
  72. [72]
    NOAA Tide Tables
    Access Them Anytime. Supporting safe navigation and coastal recreation for more than 150 years.
  73. [73]
    The Changing Tides in the English Channel
    Mar 4, 2021 · The modern way to navigate the English Channel's complexities is to use a tidal model to forecast the currents' speed and direction. Tap to ...
  74. [74]
    Navigating the Thames Barrier | Port of London Authority
    Here's what you need to know for your next passage on the eastern tidal Thames. The Thames Barrier has ten spans lettered A to K from south to north.
  75. [75]
    Managing future flood risk and Thames Barrier: Thames Estuary 2100
    Apr 19, 2023 · The barrier gates would be closed to keep out many high tides as well as storm tides. A second set of gates would provide greater reliability.How the estuary's flood... · Options for adapting to sea... · Choosing an option
  76. [76]
    Tidal Bores of England, Scotland and Wales - Meteowriter
    Tips on finding out tide times, safety and how the tides affect tidal bores. Insights into how historic river engineering works for shipping have affected ...
  77. [77]
    [PDF] iho standards for hydrographic surveys
    The tidal stream and current at each position should be measured at depths sufficient to meet the requirements of normal surface navigation in the survey area.
  78. [78]
    Hard coastal protection structures - Coastal Wiki
    May 23, 2024 · This article provides an introduction to hard coastal protection structures. An overview is given of structures that are often used in practice.
  79. [79]
    [PDF] Design of Coastal Revetments, Seawalls & Bulkheads
    Jun 30, 1995 · seawalls, and bulkheads are commonly employed either to combat erosion or to maintain development at an advanced position from the natural ...
  80. [80]
    [PDF] Tidal Energy Technology Brief - IRENA
    The rise and fall of the tides – in some cases more than 12 m – creates potential energy. The flows due to flood and ebb currents creates kinetic energy. Both ...
  81. [81]
    Tidal power - U.S. Energy Information Administration (EIA)
    May 24, 2024 · Tidal energy systems generate electricity. Producing tidal energy economically requires a tidal range of at least 10 feet.
  82. [82]
    Development and testing of Marine Current Turbine's SeaGen 1.2 ...
    Oct 8, 2013 · This paper gives the background to the development of the 1.2MW SeaGen tidal turbine commercial demonstrator, and describes the installation and subsequent ...
  83. [83]
    Tidal Lagoons: Another Technique for Capturing Marine Renewable ...
    Jul 6, 2016 · Tidal lagoons are circular enclosures where water flows through turbines during high and low tides, generating electricity. They are built ...
  84. [84]
    Sihwa Lake Tidal Power Plant - Water Services | K-water
    Location : Sihwa embankment, Ansan City, Gyeonggi-do, Korea · Power Capacity : 254MW(25.4MW×10 turbines) · Energy Productivity : supply for 500,000 population ...
  85. [85]
    MeyGen Tidal Energy Project - Tethys
    Jan 27, 2025 · Phase 1 is an operational 6MW demonstration array, which comprises four 1.5MW turbines installed as part of MeyGen's “deploy and monitor ...
  86. [86]
    New study challenges ecological fears around tidal power
    Oct 15, 2025 · The researchers found that while tidal barrages and tidal flow turbines do alter local hydrodynamics and sediment movement, the widespread fears ...
  87. [87]
    The potential of tidal energy | IEC e-tech
    May 27, 2025 · Orbital Marine Power is a Scottish renewable energy company focused on the development and global deployment of its floating tidal stream ...
  88. [88]
    Rocky shore habitat - Coastal Wiki
    Dec 25, 2024 · The intertidal zone or littoral zone is the shoreward fringe of the seabed between the highest and lowest limit of the tides. The upper limit is ...
  89. [89]
    [PDF] Life in the Rocky Intertidal Zone - National Park Service
    (Littoral Zone)​​ The middle zone is covered by the highest tides and exposed by the lowest tides. The animals here have to be able to live both in and out of ...
  90. [90]
    Intertidal Zone - an overview | ScienceDirect Topics
    Intertidal zones are defined as areas along the shoreline that are exposed to air during low tide and submerged during high tide, characterized by dynamic and ...
  91. [91]
    Fact Sheet: Intertidal rocky shores - Marine Waters
    Feb 6, 2020 · This is the highest zone on the shore of true marine life. Organisms surviving in this environment include barnacles, limpets and periwinkles.
  92. [92]
    [PDF] Climate Change and Oregon's Intertidal Habitats - ODFW
    Phytoplankton and algae form the base of intertidal marine food webs and produce the food and energy required to sustain life in nearshore waters15.
  93. [93]
    Structure and functioning of intertidal food webs along an avian ...
    Jun 27, 2015 · We investigate the structure and functioning of food webs in four tidal ecosystems of international importance for migratory shorebirds along ...Missing: flushing | Show results with:flushing
  94. [94]
    On the Edge: The Curious Lives of Intertidal Organisms and How We ...
    Nov 28, 2022 · The rocky intertidal zone is a strange and magical place, home to an incredible diversity of invertebrate organisms adapted to life on the edge.Missing: cycling flushing
  95. [95]
    [PDF] Material for Estuaries
    Tides are necessary for healthy estuaries as they flush the systems and provide nutrients to keep the food webs functional. However, tides create constantly ...<|control11|><|separator|>
  96. [96]
    Shorebirds Affect Ecosystem Functioning on an Intertidal Mudflat
    Aug 24, 2020 · Intertidal mudflat ecosystem functions include nutrient cycling, erosion protection and carbon sequestration, which mediate associated services ...<|control11|><|separator|>
  97. [97]
    Intertidal zone ecosystems: what are they and why are they under ...
    Jan 2, 2022 · 1. Habitat Destruction and Pollution Human impact on intertidal zones can manifest in the form of habitat destruction and pollution.
  98. [98]
    Existing evidence on the impact of changes in marine ecosystem ...
    Jul 20, 2023 · Marine ecosystems endure numerous direct drivers of change, mainly habitat loss and degradation, overexploitation, pollution, climate change ...
  99. [99]
    MPA Literature Summaries - California Department of Fish and Wildlife
    Marine protected areas are increasingly being used to protect biologically rich habitats, resolve user conflicts, and help restore overexploited stocks and ...
  100. [100]
    Climate Change, Human Impacts, and Coastal Ecosystems in the ...
    Oct 7, 2019 · Managing local human impacts through local conservation actions (e.g., marine protected areas, mitigation of terrestrial stressor input, and ...
  101. [101]
    Full article: Understanding the consequences of sea level rise
    Here we summarise the ecological consequences of a reduction in intertidal area from increasing SLR, and the implications for people, management and planning.Missing: 2020s | Show results with:2020s
  102. [102]
    Overestimation of Mangroves Deterioration From Sea Level Rise in ...
    Oct 3, 2024 · We find that mangroves are migrating seaward at a rate of 18% ± 12% m/yr, which can offset landward mangroves loss, 67% of which caused by land use conversion.Missing: 2020s | Show results with:2020s
  103. [103]
    Accelerating sea-level rise and the fate of mangrove plant ...
    Sep 1, 2022 · Average rate of sea-level rise in South Florida has accelerated from 3.9 mm yr -1 (1900-2021) to 9.41 mm yr -1 (2010-2021).Missing: intertidal 2020s
  104. [104]
    Everglades Ecosystems Show Mixed Reactions to Rising Sea Levels
    Jun 30, 2025 · Scientists have discovered that changes in climate and water levels are reducing the ability of some ecosystems in the Everglades to sequester carbon.Missing: intertidal 2020s<|control11|><|separator|>
  105. [105]
    Climate Change Connections: Florida (The Everglades) | US EPA
    Aug 11, 2025 · Rising sea levels, mangrove migration, and wetland shifts can have unpredictable cascading impacts for Florida's vulnerable ecosystems that lie ...Missing: intertidal 2020s studies
  106. [106]
    Towards an Understanding of Circatidal Clocks - PMC - NIH
    Feb 25, 2022 · This mini-review will focus on circatidal clocks most studied in intertidal animals, their origins, their zeitgebers, diversity, and future research directions.
  107. [107]
    [PDF] Untitled
    Fiddler crabs have clear, endogenous, circatidal rhythms that free-rum (the rhythms persist in constant conditions with periods close to 12.4 h) in constant ...
  108. [108]
    Modeling activity rhythms in fiddler crabs - PubMed
    Fiddler crabs feed during low tide and burrow at high tide. Their activity rhythms are internal, and may be regulated by two circalunidian clocks or a  ...
  109. [109]
    Experimental analysis of the diurnal and tidal spawning rhythm in ...
    The timing mechanism of synchronous spawning is entrained by a diurnal light-dark cycle and a semidiurnal tidal immersion cycle, sensed at both the beginning ...
  110. [110]
    Time me by the moon: The evolution and function of lunar ... - NIH
    Jul 16, 2024 · Again, as in animals, synchronizing to lunar cycles involves internal biological clocks entrained by environmental cues. Despite the limited ...
  111. [111]
    California Grunion Facts and Expected Runs
    For four consecutive nights, beginning on the nights of the full and new moons, spawning occurs after high tides and continues for several hours. As waves break ...
  112. [112]
    Bivalve mollusc circadian clock genes can run at tidal frequency - PMC
    Jan 8, 2020 · To control the ability of these circadian clock genes to run on a daily rhythm, we placed the oysters in LD entrainment conditions, which ...
  113. [113]
    Biological Clocks: Riding the Tides - ScienceDirect.com
    Oct 21, 2013 · A deeper understanding of circatidal and circalunar timepieces will be critical to assess how intertidal organisms and their uniquely diverse ...
  114. [114]
    Global disruption of coral broadcast spawning associated ... - Nature
    May 15, 2023 · Corals exposed to light pollution are spawning between one and three days closer to the full moon compared to those on unlit reefs.
  115. [115]
    Artificial light at night at environmental intensities disrupts daily ...
    Concerning their daily rhythm, oysters have a plastic endogenous circadian rhythm generated by a molecular clock (Mat et al., 2012; Mat et al., 2014; Payton ...Missing: circatidal | Show results with:circatidal
  116. [116]
    Impact of solid Earth tide models on GPS coordinate and ...
    Apr 22, 2006 · The resultant response is called the solid Earth tide (also termed the Earth body tide), and can account for displacements up to ∼0.4 m at ...
  117. [117]
    [PDF] 3.06 Earth Tides - Elsevier
    The uppermost frame shows gravity and vertical displacement (with scales for each) which have the same latitude dependence; the next horizontal displacement and ...
  118. [118]
    Earth tides and ocean tidal loading - SpringerLink
    The tidal deformation of the solid earth is superimposed by the loading effect caused by the ocean tides.
  119. [119]
    Atmospheric Tidal Variations within the ERICA Drifting-Buoy Data
    Subtracting a 12-h moving average from the trace reveals a semidiurnal oscillation with an amplitude of 0.5 mb (see Fig. 5). To get a better indication of ...
  120. [120]
    Atmospheric Semidiurnal Solar Tide Response to Sudden ...
    Mar 1, 2025 · The semidiurnal solar tide is a global-scale atmospheric wave, which is generated by solar heating in the Earth's atmosphere. It can propagate ...
  121. [121]
    [PDF] The Surface-Pressure Signature of Atmospheric Tides in Modern ...
    Sep 14, 2010 · Thus the semidiurnal tide is primarily excited in a broad range of altitudes around 50 km by ozone heating and effectively propagates to the ...
  122. [122]
    Diurnal and Semidiurnal Tides in Global Surface Pressure Fields in
    Over land areas, the absorbed solar radiation at the ground creates large sensible heating of the surface air and generates large diurnal ranges of surface air ...
  123. [123]
    Diurnal and semidiurnal tides in global surface pressure fields
    and longitudinal variations in water vapor and ozone. Model simulations suggest that the upward sensible heat flux from the ground due to solar heating ...
  124. [124]
    [PDF] Chapter 9 Atmospheric tides
    The peculiar feature of these atmospheric surface pressure tides is that they are primarily solar semidiurnal. Laplace, already aware of this fact, concluded ...
  125. [125]
    SLOSH - MDL - Virtual Lab - NOAA VLab
    A numerical model that computes storm surge using a set of finite-difference equations to solve the Navier-Stokes equations of motion.
  126. [126]
    [PDF] THE ROLE OF THE SLOSH MODEL IN NATIONAL WEATHER ...
    The SLOSH model has proven to be a dependable and valuable tool for forecasters and emergency management officials in predicting storm surge in real-time and ...
  127. [127]
    [PDF] Barometric tides from ECMWF operational analyses
    Comparisons of global barometric tides derived from the available gridded analyses with the meteoro- logical station data provide a useful test of the analyzed ...
  128. [128]
    Atmospheric Contributions to Global Ocean Tides for Satellite ...
    Oct 17, 2022 · Accurate models of global atmospheric tides and their oceanic response are in particular important for the processing of satellite gravimetry ...
  129. [129]
    As Regular as Clockwork: Alexander von Humboldt, Robert ... - MDPI
    Indeed, the tides are very prominent features of the global scale circulation of the atmosphere above the stratosphere. The atmospheric tides are generated by ...
  130. [130]
    [PDF] Astronomical Tide and Storm Surge Signals Observed in an Isolated ...
    Apr 30, 2021 · The main result of our study has therefore excluded the local tidal-generating force, wind-driven seiche, and barometric effect, as possible ...
  131. [131]
    [PDF] TIDAL FREQUENCY ESTIMATION for CLOSED BASINS
    Feb 15, 1978 · The models of closed tidal basins, numerically studied in this investigation, were three in number - the test basin, Lake Erie and Lake Superior ...
  132. [132]
    [PDF] Guidance for Flood Risk Analysis and Mapping - FEMA
    The Canadian Hydrologic/Hydrographic Service reports a tidal response of less than 2 inches in the Great Lakes, the strongest being on Lakes Superior and Erie.<|separator|>
  133. [133]
    Do the Great Lakes have tides? - NOAA's National Ocean Service
    Jun 16, 2024 · The Great Lakes are considered to be non-tidal. Water levels in the Great Lakes have long-term, annual, and short-term variations.Missing: amplitude M2
  134. [134]
    They Come in Waves: Seiches and a Type of Tsunami Affect the ...
    Oct 23, 2014 · Tides of less than 2 inches (5 cm) occur twice daily on the Great Lakes, but water levels are primarily influenced by meteorological effects.Missing: implications | Show results with:implications
  135. [135]
    [PDF] Catalog of Worldwide Tidal Bore Occurrences and Characteristics
    Bores whose amplitudes are reputed to exceed 6 m have been reported from the Amazon and Qiangtang Rivers. (Branner, 1884; Moore, 1888, 1893). Although these are.<|separator|>
  136. [136]
    Analysis of the water level dynamics simulated by a global river ...
    Sep 7, 2012 · Because of the very flat terrain of the Amazon basin, the area affected by the ocean tide can be as far as 1000 km inland of the coast. The ...
  137. [137]
    [PDF] Great Lakes Basin Framework Study APPENDIX 11 LEVELS AND ...
    This appendix describes the factors which affect Great Lakes water levels and outflows. It discusses the physiography, hydraulics, and hydrology of the Great ...
  138. [138]
    Water Levels: NOAA Great Lakes Environmental Research Laboratory
    Dec 14, 2023 · Great Lakes water levels are continuously monitored by US and Canadian federal agencies in the region through a binational partnership.