The Alaska Current is a wind-driven surface ocean current in the northeastern Pacific Ocean that branches northward from the North Pacific Current, forming the eastern limb of a counterclockwise gyre within the Gulf of Alaska.[1] This gyre circulation transports relatively warm subtropical waters toward the Alaskan coast, moderating regional temperatures and supporting productive marine ecosystems through nutrient distribution and upwelling processes. Characterized by meanders and eddies typical of an eastern boundary current, it extends offshore before splitting into the westward-flowing Alaskan Stream along the Aleutian Islands and the narrower, fresher inshore Alaska Coastal Current influenced by coastal runoff and winds.[2] The current plays a critical role in the subarctic Pacific's large-scale circulation, affecting fisheries, sea ice dynamics, and climate variability in Alaska by delivering heat and influencing seasonal ocean acidification cycles via its interaction with the broader gyre system.[3]
Formation and Driving Mechanisms
Origins in the North Pacific Gyre
The Alaska Current originates as the eastern limb of the counterclockwise North Pacific Subpolar Gyre, emerging in the Gulf of Alaska from the northward-turning branch of the North Pacific Current, which itself derives from the eastward extension of the Kuroshio Current carrying subtropical waters poleward.[4] This positioning reflects the gyre's cyclonic structure, where the Alaska Current initiates the westward flow along the northern perimeter of the Gulf, distinct from the intensified western boundary represented by the downstream Alaskan Stream.[2]Formation of this current aligns with fluid dynamic principles of large-scale oceanic circulation, wherein wind stress over the North Pacific induces Ekman transport that converges in the subpolar region, promoting upwelling and subsequent geostrophic adjustment to establish meridional and zonal flows. In the Gulf of Alaska, these processes yield a broad, diffuse current regime before boundary effects concentrate the flow. Empirical hydrographic surveys confirm the Alaska Current's role in closing the gyre's eastern segment, with baroclinic volume transport estimates relative to 1500 dbar averaging approximately 9.2 Sverdrups (10^6 m³/s), based on geostrophic calculations from density profiles.[5]Historical measurements, such as those from mid-20th-century expeditions, initially reported lower transports around 5 Sverdrups, but subsequent data incorporating full-depth referencing indicate higher values consistent with the gyre's overall Sverdrupian interior balance. This inflow sustains the gyre's recirculation without relying on direct subtropical equatorial inputs beyond the Kuroshio pathway, emphasizing the subpolar system's relative autonomy in transport partitioning.[5]
Primary Driving Forces
The Alaska Coastal Current, the primary manifestation of the Alaska Current along the Gulf of Alaska shelf, is predominantly propelled by buoyancy forces arising from substantial freshwater inputs, including river runoff and glacial meltwater, which lower surface salinity and establish a strong horizontal density gradient across the shelf.[6][7] This gradient drives a baroclinic jet through geostrophic adjustment, with surface velocities typically ranging from 50 to 100 cm/s in the core, narrowing to widths under 30 km.[8][9] Annual freshwater discharge into the Gulf exceeds 870 km³, with distributed coastal sources contributing the majority, enhancing stratification and sustaining the alongshore momentum despite the region's high precipitation and glacial contributions.[10]Wind forcing supplements buoyancy through direct alongshore stress from prevailing downwelling-favorable winds, which accelerate the current during favorable conditions and can reverse or intensify flow via Ekman dynamics, with correlations observed between wind events and velocity peaks up to 150 cm/s.[11][12] On gyre scales encompassing the Alaska Current, broader wind curl drives interior transport via Sverdrup balance, where planetary vorticity balances Ekman pumping, though coastal boundary effects dominate the nearshore jet.[13]Earth's rotation imposes the Coriolis effect, deflecting the northward-propagating flow offshore in the Northern Hemisphere, which constrains the jet's width and promotes cross-shelf density contrasts observable in buoy and drifter trajectories showing rightward deviations under geostrophic conditions.[14][6] Moored observations confirm this deflection aligns with f-plane approximations, balancing pressure gradients against Coriolis torques without invoking topographic steering as the sole constraint.[15]
Path and Extent
Primary Track and Flow Direction
The Alaska Current's primary track traces a counterclockwise trajectory within the Gulf of Alaska gyre, initiating as poleward flow along the eastern continental margin before veering westward along the southern Alaskan coast toward the Aleutian Islands.[6] This path follows the continental shelf, with the current's axis generally positioned between 55°N and 60°N, extending westward over distances spanning the breadth of the Gulf.[8] Empirical tracking from satellite altimetry and ARGO float data delineates this looping pattern, revealing a transition from northeasterly to southwesterly directions near Kodiak Island at approximately 57°N, 152°W, where the flow aligns more closely with the shelf break.[16][17]Flow direction remains predominantly westward along the Alaskan shelf, driven by the gyre's dynamics, with mean velocities exceeding 20 cm/s at intermediate depths.[2] Seasonal variations enhance this track in summer, when elevated freshwater inputs from coastal runoff amplify the baroclinic pressure gradient, strengthening the along-shelf component to typical speeds of 20-50 cm/s.[6] ARGO-derived geostrophic transports confirm this intensification, linking it to peak discharge periods that reinforce the current's coherence without altering its core orientation.[16]
Branches and Interactions with Adjacent Currents
The Alaska Current bifurcates near the Alaska Peninsula, with a northern branch of the Alaska Coastal Current entering the Bering Sea primarily through Unimak Pass, a shallow conduit less than 200 meters deep that allows exchange between the North Pacific and Bering shelves.[18] Volume transport through this pass is estimated at approximately 1.9 Sverdrups (Sv), contributing to the Alaskan North Slope Current and influenced by tidal and wave mixing dynamics.[19] The dominant westward branch transitions into the Alaskan Stream, a narrow, intense western boundary current of the subarctic gyre that flows southwestward along the southern edge of the Aleutian Islands, maintaining relatively constant transport from the Gulf of Alaska head to the western Aleutians.[20][21]Interactions with the California Current occur indirectly through the cyclonic closure of the Gulf of Alaska sub-gyre, where southward recirculating flows from the Alaska Current meet northern extensions of the southward California Current, fostering shelf-break eddies that enhance lateral mixing.[22] These eddies, typically anticyclonic and confined within 200 kilometers of the shelf break, propagate southwestward and trap coastal waters, as documented in hydrographic and satellite observations.[23] Tracer studies, including tritium distributions from the 1960s onward, reveal diffusive mixing across the gyre boundaries, supporting evidence of exchange between the warmer Alaska Current waters and cooler California Current inflows.[24]Subsurface dynamics involve poleward extensions of the California Undercurrent along the continental slope, which intersect the Alaska Current to form sharp frontal zones prone to shear instabilities.[25] These instabilities, driven by vertical shears in the undercurrent (with wavelengths of 65-94 kilometers and periods of 5-10 days), generate mesoscale anticyclones and promote upwelling of nutrient-rich waters at the front.[26][27] Such features create zones of high vorticity and eddy kinetic energy, distinct from the primary surface flows.[28]
Physical Characteristics
Temperature, Salinity, and Volume Transport
Surface temperatures in the Alaska Current range from 2°C to 14°C over multi-year observations in the northern Gulf of Alaska, with typical values of 4–10°C reflecting advection of relatively warm North Pacific Gyre waters into sub-Arctic latitudes.[29] Salinities remain low at the surface, spanning 26–31.5 psu, primarily due to dilution from continental freshwater runoff and precipitation exceeding evaporation in the source region.[29]Conductivity-temperature-depth (CTD) profiles reveal a distinct vertical structure, characterized by a fresher, low-salinity lens in the upper layers overlying saltier, denser deep waters, which enhances stratification and influences density-driven processes.[30] This halocline typically forms between 75 and 150 m depth, with salinity increasing sharply below.[13]Volume transport estimates for the Alaska Current, derived from geostrophic calculations relative to deep reference levels such as 1500 dbar, average 9–16 Sverdrups (Sv; 1 Sv = 10⁶ m³ s⁻¹), with specific surveys reporting 9.2 Sv baroclinically and up to 12.5 Sv full-depth seaward of the continental shelf.[5][31] Transport increases westward as the current transitions into the Alaskan Stream, reaching approximately 16 Sv at 140°W based on Argo float and historical CTD data.[32] Seasonal variations are generally modest relative to interannual changes, though baroclinic components exhibit some modulation.[33]
Velocity and Depth Profile
The Alaska Current features surface velocities peaking at up to 1 m/s within intensified coastal jets along the shelf, with flows decaying rapidly offshore to less than 10 cm/s beyond the continental slope, as measured by moored acoustic Doppler current profilers (ADCPs) and high-frequency (HF) radar systems in the northern Gulf of Alaska.[6][34] These near-surface speeds reflect the current's confinement to the shelf and slope, where alongshore momentum is amplified by topographic steering and freshwater influences.[11]Vertically, the flow is shallow and surface-intensified, with significant velocities limited to the upper 200–500 m, below which shear increases and speeds diminish due to the underlying baroclinic structure and bottom friction over the sloping bathymetry.[6] ADCP profiles from deployments in the Gulf of Alaska confirm this depth restriction, distinguishing the Alaska Current from the deeper Alaskan Stream, which exhibits persistent subsurface cores extending beyond 1,000 m with velocities up to 90 cm/s at 150 m depth.[35][13]Meandering in the Alaska Current manifests as alongshore undulations with wavelengths around 100 km, observed via satellite altimetry and HF-radar mappings of sea surface height and radial velocities, and attributed to barotropic instability converting mean kinetic energy into eddy variance along the unstable shear zone.[36][37] These patterns enhance lateral mixing but remain shallower than comparable instabilities in the barotropic Alaskan Stream.[11]
Ecological and Economic Role
Nutrient Upwelling and Primary Productivity
The Alaska Current, interacting with the Gulf of Alaska shelf topography and modulated by wind stress curl, drives localized upwelling that supplies macronutrients such as nitrate and phosphate to surface waters, particularly at shelf breaks where cross-shelf exchange is enhanced.[38][39] This process counteracts the region's high-nutrient, low-chlorophyll status by vertically advecting nutrient-rich subsurface waters, with observed nitrate concentrations increasing toward the shelf break during periods of downwelling relaxation.[40]These nutrient inputs sustain primary productivity rates on the Gulf of Alaska shelf estimated at 150–300 g C m⁻² yr⁻¹, classifying the ecosystem as moderately productive and supporting phytoplankton blooms dominated by diatoms under iron co-limitation.[41] Empirical chlorophyll a data and modeled nitrate distributions reveal elevated productivity hotspots near the shelf break, where upwelling-favorable conditions intermittently elevate nutrient fluxes despite overall downwelling dominance in the eastern boundary regime.[42]Productivity exhibits pronounced spring-summer peaks, coinciding with maximum solar insolation and freshwater stratification from coastal runoff, which shoals the mixed layer and concentrates nutrients supplied via upwelling without excessive deep-water dilution. This temporal pattern correlates with observed nitrate depletion in surface waters post-bloom, as low-salinity lenses from the adjacent Alaska Coastal Current limit vertical entrainment while upwelled pulses sustain growth until iron constraints dominate.[43]The upwelling-driven blooms contribute to biogeochemical cycling through enhanced carbon export, with sinking biogenic particles from phytoplankton detritus facilitating vertical flux, as quantified by sediment trap deployments showing elevated particulate organic carbon downward transport during productive seasons.[38] This mechanism underscores the current's role in sequestering fixed carbon from the euphotic zone, with export efficiencies varying by bloom intensity and stratification strength.[39]
Support for Fisheries and Marine Biodiversity
The Alaska Current plays a critical role in sustaining commercially important fisheries along Alaska's southern coast, particularly for Pacific salmon (Oncorhynchus spp.), walleye pollock (Gadus chalcogrammus), and crab species such as king crab (Paralithodes camtschaticus) and snow crab (Chionoecetes opilio), by influencing larval dispersal, juvenile retention, and adult migration patterns in coastal habitats.[44] These fisheries benefit from the current's advection of early life stages, which aligns with observed hotspots for recruitment in the Gulf of Alaska.[45]Annual commercial catches supported by these dynamics exceed 1 million metric tons, with walleye pollock harvests reaching 1.43 million metric tons in 2023 across Alaska stocks, including those in the Gulf of Alaska where current flows predominate.[46]Salmon fisheries, targeting species like pink, chum, and sockeye that utilize coastal currents for ocean entry and growth, averaged 172 million fish harvested annually from 1990 onward, contributing substantial biomass alongside crab landings that fluctuate but historically add tens of thousands of tons.[47][48]Areas influenced by the Alaska Current host elevated marine biodiversity, with hotspots for large migratory predators including humpback whales (Megaptera novaeangliae), whose feeding aggregations correlate with prey patches in current-driven productive zones off southeast and southcentral Alaska.[49] Species distribution models indicate higher diversity indices in these coastal bands compared to offshore regions, supporting populations of forage fish and invertebrates that underpin broader food webs.[44]These fisheries generate an economic value of approximately $6 billion annually for Alaska through ex-vessel revenues, processing, and support industries, representing over half of U.S. wild seafood production.[50] However, Alaska Department of Fish and Game stock assessments highlight risks from current flow variability, which can disrupt migration routes and larval transport, leading to recruitment shortfalls observed in periodic fishery declines.[48][51]
Atmospheric and Climatic Interactions
Heat and Momentum Exchange with Atmosphere
The Alaska Current, as a warm western boundary current in the Gulf of Alaska, drives substantial air-sea heat fluxes through its advection of relatively warm subsurface waters toward colder atmospheric conditions, particularly in winter. Annual mean sensible and latent heat fluxes over the northern Gulf of Alaska shelf, where the current dominates, range from 50 to 100 W/m² in magnitude, representing net oceanic heat loss that moderates coastal air temperatures by releasing stored thermal energy.[52] These fluxes exhibit strong seasonal variability, with winter values for latent heat averaging approximately -68 W/m² and sensible heat -59 W/m² (negative denoting ocean-to-atmosphere direction), derived from mooring observations within the current's path.[6] The overall annual air-sea heat flux deficit averages about 60 W/m² on the inner shelf, partially offset by cross-shelf oceanic convergence but underscoring the current's role in sustaining regional heat budgets.[52]Momentum exchange between the Alaska Current and the atmosphere occurs primarily through wind stress acting on the ocean surface, with the current's flow influencing relative wind speeds and thus the effective transfer. ERA5 reanalysis data quantify typical wind stresses over the Gulf of Alaska as 0.05-0.1 Pa on average, rising to 0.1-0.2 Pa during winter storms, generating curls that contribute to the cyclonic forcing of the current.[53][54] These stresses exhibit onshore gradients, enhanced near the coast due to topographic effects like barrier jets, which amplify momentum input into the current's boundary layer.[52]Moored buoy observations in the Alaska Coastal Current reveal elevated latent heat fluxes—and thus evaporation rates—in zones of low surface salinity (<32 psu), where freshwater runoff stratifies the upper layer but warmer advected waters sustain higher vapor pressure deficits relative to overlying air.[6][52] This enhancement, linked to the current's low-salinity core, contrasts with offshore areas, highlighting spatially variable air-sea interaction tied to the current's hydrological properties.[52]
Influence on Regional Weather Patterns
The Alaska Current contributes to the persistence of low-pressure systems over the Gulf of Alaska by supplying heat and moisture that support atmospheric cyclogenesis and vorticity dynamics within these features. Observational analyses of atmospheric circulation patterns indicate that enhanced oceanic heat transport during periods of stronger current flow correlates with deepened Aleutian Low intensities, directing more frequent southeastward-moving storms toward coastal Alaska and increasing winter precipitation in the region.[55][56]This oceanic influence manifests in reduced variability of winter precipitation along Alaska's southern coast, where the current's poleward heat advection stabilizes near-surface atmospheric conditions and dampens extreme storm track deviations, as evidenced by correlations in National Centers for Environmental Prediction (NCEP) reanalysis datasets spanning multiple decades. Such effects stem from the current's role in elevating sea surface temperatures, which modulate baroclinic instability and limit the propagation of highly variable mid-latitude cyclones inland.[57]Historical warm anomalies in the Alaska Current, such as those observed during the 1988–1989 El Niño event, have coincided with milder winter air temperatures in southern and coastal Alaska, despite heightened storm activity linked to intensified Aleutian Low troughing. In that period, elevated Gulf of Alaska sea surface temperatures—driven by enhanced gyre circulation—correlated with above-average coastal warmth and moderated cold outbreaks, illustrating the current's downstream meteorological feedback on seasonal weather regimes.[58][59]
Variability and Long-Term Dynamics
Seasonal and Interannual Fluctuations
The Alaska Coastal Current, a key component of the broader Alaska Current system, displays pronounced seasonal variations in volume transport, with mean winter transports at Gore Point reaching 1.4 × 10⁶ m³ s⁻¹ compared to 0.6 × 10⁶ m³ s⁻¹ in summer, driven primarily by enhanced winter wind forcing that overcomes freshwater stratification from seasonal river runoff peaking in late spring and summer.[60] Shorter-term fluctuations, observed via moorings deployed in the 1980s through 2010s across sites like Shelikof Strait and Gore Point, reveal subtidal variability with amplitudes up to 3.0 × 10⁶ m³ s⁻¹ over days, often exhibiting geostrophic balance (correlation coefficient r = 0.79), while winter storms contribute to increased flow speeds of 50–100 cm s⁻¹ along-shelf, contrasting with weaker summer velocities around 10–20 cm s⁻¹.[61][6][62]Interannual fluctuations in the Alaska Current and associated Alaskan Stream, derived from mooring arrays and hydrographic sections spanning the 1990s to 2010s, show volume transports averaging 27.5 × 10⁶ m³ s⁻¹ with a standard deviation of 6.5 × 10⁶ m³ s⁻¹ over 1989–1996, equating to roughly 20–25% variability year-to-year, with peaks such as 41.0 × 10⁶ m³ s⁻¹ in 1997.[63][64] ENSO teleconnections induce flow anomalies of 10–20%, as evidenced by weakened circulation during the 1997–98 El Niño, which propagated atmospheric signals to the Gulf of Alaska by mid-1997, elevating sea surface temperatures and altering coastal hydrography consistent with reduced gyre intensity.[65]Pacific Decadal Oscillation (PDO) modulations further drive interannual to multiyear variability, with positive PDO phases correlating to southward shifts in the Alaska Gyre's bifurcation and enhanced offshore deflection, influencing current strength through altered wind patterns and sea level anomalies observed in time-series data.[16][66] Spectral characteristics from these records highlight dominant periodicities of 1–5 years in transport anomalies, linked to PDO's intrinsic variability superimposed on ENSO forcing.[66]
Observed Trends and Natural Oscillations
Instrumental observations in the northern Gulf of Alaska reveal multidecadal shifts in sea surface temperatures (SST) strongly modulated by the Pacific Decadal Oscillation (PDO), with a pronounced warming phase during the positive PDO regime from roughly 1977 to the late 1990s. This period coincided with enhanced Alaska Current transport and SST increases of approximately 0.22 ± 0.10 °C per decade, contrasting with a slower long-term trend of 0.10 ± 0.03 °C per decade from 1900 onward, underscoring the dominance of oscillatory modes over linear progression.[67] Proxy records, including sedimentary indicators from the region, corroborate these shifts, showing PDO-linked temperature anomalies of up to +0.5 °C in comparable historical warm phases driven by atmospheric-oceanic teleconnections rather than monotonic forcing.[68]Salinity profiles along the Alaska Coastal Current exhibit slight freshening trends, on the order of reduced surface salinity tied to episodic increases in glacial meltwater discharge, as recorded in coralline algal archives spanning recent decades. These changes align with natural variability in regional glacial mass balance and runoff cycles, with freshwater fluxes fluctuating in response to decadal-scale climate modes rather than isolated radiative effects.[69] Accompanying observations of vertical stratification alterations further reflect this dynamic interplay between current strength and buoyancy inputs from coastal glaciers.[70]Paleoclimate reconstructions from varved sediments in southwest Alaska demonstrate pre-industrial hydroclimate variability, including multidecadal cycles in discharge and sediment flux that mirror PDO influences and often exceed the amplitude of 20th-21st century fluctuations. These records, spanning over 280 years from AD 1718 to 2006, highlight recurrent strengthening and weakening of current-related processes, with natural forcings such as atmospheric pressure anomalies driving sedimentological proxies of flow intensity beyond recent instrumental ranges.[71] Subarctic proxy syntheses further confirm ~20-90-year oscillations in the region, embedding modern trends within a continuum of PDO-like variability over millennia.[72]
Attribution of Changes: Natural vs. Anthropogenic Factors
Regression analyses of sea surface temperature (SST) and circulation patterns in the Gulf of Alaska attribute the majority of decadal-scale variability in the Alaska Current to the Pacific Decadal Oscillation (PDO), a natural mode of North Pacific climate variability characterized by alternating warm and cool phases lasting 20–30 years. During positive PDO phases, enhanced Aleutian Low pressure anomalies strengthen westerly winds, intensifying the Alaska Gyre and thereby accelerating the Alaska Current's alongshore flow and offshore transport. This mechanism explains up to interdecadal variance in regional SST and gyre strength, with positive phases correlating to observed strengthening of the current since the mid-2010s, consistent with the PDO's shift toward positive values around 2014.[16][73][67]The Atlantic Multidecadal Oscillation (AMO), while primarily influencing Atlantic circulation, exerts secondary teleconnections to the North Pacific via atmospheric bridges, modulating PDO-like patterns and contributing to multidecadal SST shifts in the Gulf of Alaska; however, its role remains subordinate to PDO forcing in regression models of local current dynamics. Empirical reconstructions and Bayesian regression frameworks confirm that these natural oscillations account for 50–70% of explained variance in Gulf of Alaska thermal and velocity anomalies over the instrumental record, far exceeding the detectable imprint of anthropogenic greenhouse gas forcing in hindcast simulations.[74][75]General circulation models (GCMs) struggle to reproduce observed North Pacific decadal variability, often underestimating PDO-driven current fluctuations while projecting amplified responses to CO2 increases that mismatch ARGO float and mooring data; for instance, GCM ensembles show poor hindcast skill for SST and circulation trends, with internal variability dominating over radiative forcing signals. Claims of anthropogenic dominance in media reports frequently overlook controls for solar irradiance cycles and PDO/AMO phasing, as evidenced by 2020s warming anomalies aligning closely with the positive PDO regime rather than isolated CO2 trends.[76][77]Projections of reduced coastal upwelling and primary productivity under anthropogenic warming—stemming from increased stratification—have not materialized in Gulf of Alaska observations, where ARGO-derived nitrate fluxes and satellite chlorophyll estimates indicate stable or episodic enhancements tied to PDO-modulated wind events, contradicting model-expected declines. Ecosystem status assessments corroborate this, linking productivity oscillations to natural wind-current coupling rather than unidirectional anthropogenic suppression, underscoring the primacy of internal ocean-atmosphere dynamics in causal attribution.[44][78]
History of Research
Early Observations and Discovery
The Alaska Current was first incidentally observed by 18th-century European explorers navigating the North Pacific approaches to Alaska. Vitus Bering, during his 1741 Great Northern Expedition, encountered prevailing westerly currents while sailing from Kamchatka toward the American mainland, which aligned with the broader West Wind Drift feeding into the Alaska Current system, though systematic current measurements were not conducted. Similarly, James Cook's 1778 voyage along the Alaskan coast documented consistent easterly winds and inferred coastal flows consistent with the counterclockwise gyre in the Gulf of Alaska, based on ship drift and navigational logs.[79]Systematic charting of currents in Alaskan waters began in the late 19th century following the U.S. purchase of Alaska in 1867, with the U.S. Coast and Geodetic Survey (USC&GS) initiating hydrographic surveys to map tides, currents, and coastal features. By the early 1900s, USC&GS expeditions using vessels like the Albatross confirmed the westward-flowing branch along the southern Alaskan coast, integrating shipboard observations of drift and temperature with triangulation for accurate positioning.[80] These efforts, detailed in reports such as the 1927 study on tides and currents in southeast Alaska, established the current's role as a gyre extension rather than isolated coastal eddies.[81]In the 1930s, international oceanographic interest grew, with German researcher Gerhard Schott describing the feature as Alaska Strom (Alaska Current) in his 1935 geographic analysis, attributing it as a distinct branch of the North Pacific circulation based on aggregated drift data and wind patterns.[13] Subsequent 1940s-1950s U.S. and Canadian expeditions, including fisheries-related cruises, further delineated its offshore extent versus nearshore flows. By the 1960s, scientific literature increasingly distinguished the buoyant, fresher nearshore component as the "Alaskan Coastal Current," reflecting refined observations from repeated transects.[13]
Key Modern Studies and Monitoring Efforts
Satellite altimetry missions, starting with TOPEX/Poseidon in 1992, have mapped sea surface height anomalies in the Gulf of Alaska, revealing mesoscale meanders and eddies in the Alaska Current with wavelengths of 100-200 km and amplitudes up to 20 km since the mid-1990s.[82] These observations, complemented by Argo float profiles deployed globally from 2000 onward, have quantified subsurface structures and transport variability in the Alaska Current's westward extension as the Alaskan Stream, showing zonal evolution with velocities decreasing from 50 cm/s near 140°W to under 30 cm/s by 175°W based on floats sampling depths to 2000 m.[83]Long-term mooring arrays, initiated in the early 2000s, extend from Seward, Alaska, to Samalga Pass, measuring currents and freshwater-influenced transports in the Alaska Coastal Current—a buoyant, shelf-confined branch of the Alaska Current—over spans of 1700 km, with mean baroclinic transports of 0.5-1.0 Sv correlated to alongshore winds at lags of 1-3 days.[60] Deployments near Samalga Pass in 2001-2002 and 2003-2004 recorded peak velocities exceeding 100 cm/s in the core, linking shelf flows to exchanges with the Alaskan Stream and Bering Sea.[84]High-frequency radar expansions in the 2020s, integrated into the Alaska Ocean Observing System, deliver near-real-time surface velocities across Gulf of Alaska coastal zones up to 100 km offshore, with resolutions of 1-5 km capturing event-scale variations in the Alaska Current's nearshore dynamics.[85]Regional Ocean Modeling System (ROMS) simulations at 1-3 km resolution have validated these in situ and remote observations by reproducing observed transports and eddy kinetic energy in the Alaska Current, yet reveal persistent uncertainties in deep isopycnal coupling below 1000 m due to sparse subsurface data constraining vertical shear.[86][87]