Trends and recent shifts in the ocean hydrography of the temperate north-east Atlantic Insights from routinely repeated sections around Spanish waters.

Slides:

Advertisements

Similar presentations

1 ICES/NAFO Symposium Santander May Seasonal to interannual variability of temperature and salinity in the Nordic Seas: heat and freshwater budgets.

Advertisements

An analysis of transport and water masses in the Straits of Florida and the Bahamas Moulin Aurélie Moulin Department of Marine and Environmental Systems.

- Perspectivas actuales en el estudio de la evolución del CO2 en la superficie del océano => case studies - Perspectivas actuales en el estudio de la.

RAPID/MOCHA/WBTS THE SEASONAL CYCLE OF THE AMOC AT 26ºN Eastern Boundary Considerations Gerard McCarthy, Eleanor Frajka- Williams, Aurélie Duchez and David.

About the recent warming of intermediate waters of the Bay of Biscay Spanish Institute of Oceanography C. González-Pola, A. Lavín, R. Somavilla, C. Rodriguez.

Essentials of Oceanography

Water mass transformation in the Iceland Sea Irminger Sea, R/V Knorr, October 2008 Kjetil Våge Kent Moore Steingrímur Jónsson Héðinn Valdimarsson.

Wind-Driven Circulation in a Stratified Ocean Consider the ocean in several isopycnal layers that can be separated into two groups: Layers that outcrop.

Thermohaline circulation ●The concept of meridional overturning ●Deep water formation and property Antarctic Bottom Water North Atlantic Deep Water Antarctic.

L AST SIXTY YEARS OF MIXED LAYER DEPTH VARIABILITY IN THE SOUTHERN B AY OF B ISCAY. D EEPENING OF WINTER MLD S CONCURRENT TO GENERALIZED UPPER WATER WARMING.

TS TRENDS IN THE WESTERN MEDITERRANEAN: WATER MASS CHANGES AND VERTICAL DISPLACEMENTS (HEAVING) Patricia Zunino Rodríguez Manolo Vargas Yáñez M. Carmen.

Temperature and salinity variability of the Atlantic Water in the Eastern Eurasian Basin between 1991 and 2011 Meri Korhonen R/V Akademik Fedorov, August.

Observed variability of hydrography and transport at 53°N in the Labrador Sea Johannes Karstensen GEOMAR Helmholtz Centre for Ocean Research Kiel With.

Decadal Water Mass Variations in the Northeast Atlantic Ocean G C Johnson, J Bullister, M Baringer, C Mordy, C Sabine, J-Z Zhang, R Wanninkhof, & R Feely.

CO 2 flux in the North Pacific Alan Cohn May 10, 2006.

Ocean Stratification and Circulation Martin Visbeck DEES, Lamont-Doherty Earth Observatory

Earth Systems Science Chapter 5 OCEAN CIRCULATION I: SURFACE Winds, surface currents Flow within gyres: convergence, divergence, upwelling, downwelling,

Historical surface records (T-S-density) NE Atlantic subpolar gyre - Corridor of the northward upper layer transport to convection sites and- this Arctic,

SIO 210 Typical distributions (2 lectures) Fall 2014

Ocean Response to Global Warming William Curry Woods Hole Oceanographic Institution Wallace Stegner Center March 3, 2006.

=(S,,0); 4=(S,,4000).

Evaporative heat flux (Q e ) 51% of the heat input into the ocean is used for evaporation. Evaporation starts when the air over the ocean is unsaturated.

Spatial coherence of interannual variability in water properties on the U.S. northeast shelf David G. Mountain and Maureen H. Taylor Presented by: Yizhen.

The meridional coherence of the North Atlantic meridional overturning circulation Rory Bingham Proudman Oceanographic Laboratory Coauthors: Chris Hughes,

Video Field Trip 1. How are waves created? 2. Describe the way in which the moon influences the tides.

Investigating changes in the Atlantic Waters characteristics along the Egyptian Mediterranean Coast M. A. Said, M. A. Gerges, I. A. Maiyza, M.A. Hussien.

Temperature and Salinity Variabitlity on the Scotian Shelf and in the Gulf of Maine BRIAN PETRIE AND KENNETH DRINKWATER.

1. 2 ocean circulation thermohaline conceptual model.

Mode (Eighteen Degree) Water V.Y. Chow EPS Dec 2005.

Western boundary circulation in the tropical South Atlantic and its relation to Tropical Atlantic Variability Rebecca Hummels 1, Peter Brandt 1, Marcus.

Composition and Movement of Ocean Water. Salinity Seawater is a solution containing a variety of salts dissolved in water Expressed in grams of salt per.

Transport in the Subpolar and Subtropical North Atlantic

Surface Currents Movement of water that flow in the upper part of the ocean’s surface.

What’s the story?.

Part II: Where are we going? Like an ocean... The waves crash down... Introducing OCEAN ATMOSPHERE INTERACTION.

Latitude structure of the circulation Figure 2.12 Neelin, Climate Change and Climate Modeling, Cambridge UP.

DFO Northwest Atlantic Ocean Monitoring & Mooring Programs OSNAP Planning Meeting April 2011 BIO.

WOCE hydrographic Atlas, 1 As a result of the World Ocean Circulation Experiment (WOCE), a hydrographic survey of the world oceans occurred from

Current Weather Introduction to Air-Sea interactions Ekman Transport Sub-tropical and sub-polar gyres Upwelling and downwelling Return Exam I For Next.

Seasonal evolution of the surface mixed layer Meri Korhonen.

Typical Distributions of Water Characteristics in the Oceans.

Regional Oceanography I

Thermohaline Circulation Lecture Outline 1)What is thermohaline circulation 2)History of understanding 3)Key water masses 4)Formation of deep water 5)Theory.

Global Ocean Circulation (2) 1.Wind-driven gyre-scale circulation of the surface ocean and upper thermocline 2.Global heat and freshwater water transport,

Water Mass Distribution OEAS 604 Lecture Outline 1)Thermohaline Circulation 2)Spreading pathways in ocean basins 3)T-S diagrams 4)Mixing on T-S diagrams.

Cross-Gyre Thermohaline Transport in the Tropical Atlantic: The role of NBC Rings Bill Johns Zulema Garraffo Division of Meteorology and Physical Oceanography.

The Conveyer Belt EEn  Ocean circulation travels from the Atlantic Ocean through the Indian & Pacific oceans & back again  Warm water in upper.

Labrador Sea Export -- the DWBC at 53°N as a Fingerprint of the AMOC? J. Fischer, J. Karstensen, M. Visbeck, R. Zantopp, R. Kopte Annual Conference, Berlin.

Ocean Response to Global Warming/Global Change William Curry Woods Hole Oceanographic Institution Environmental Defense May 12, 2005 Possible changes in.

Salinity and Density Differences VERTICAL STRUCTURE, THERMOHALINE CIRCULATION & WATER MASSES.

Ocean Currents.

IPCC AR4 Chapter 5 Oxygen decline at base of pycnocline throughout subpolar and subtropical N. Pacific: reduced ventilation Deutsch et al. (2005) IPCC.

Recent Variability in Ocean Climate in the Scotia-Maine and Adjacent Regions Brian Petrie, Roger Pettipas, Charles Hannah Bedford Institute of Oceanography.

Art or Science?. Explain the thermal transfers of energy within oceans and the importance of oceanic conveyor belts.

10/24/03search_osm_10_032 Abrupt Change in Deep Water Formation in the Greenland Sea: Results from Hydrographic and Tracer Time Series SEARCH Open Science.

Sea surface temperatures Sea water T varies with position in oceans Amount of insolation absorbed depends upon angle of incidence –With normal incidence,

Thermocline & Pycnocline

Spatial Modes of Salinity and Temperature Comparison with PDO index

Ocean Currents.

Density-Driven Downwelling and Thermohaline Circulation

Scientific progress and new insights from current observations

The ability for the ocean to absorb and store energy from the sun is due to… The transparency of the water that allows the sun’s ray to penetrate deep.

Chapter 16.1 Ocean Circulation.

Ocean-Air Interaction

On the nature of winter cooling and the recent temperature shift on the northern Gulf of Alaska shelf Thomas Weingartner1, Markus Janout1, Seth Danielson1.

with contributions from Jan Aure, Roald Sætre and Didrik Danielssen

Relationship Between NO3 and Salinity:

Unit 1 Structure and Motion Part 2

Presentation transcript:

Trends and recent shifts in the ocean hydrography of the temperate north-east Atlantic Insights from routinely repeated sections around Spanish waters. Spanish Institute of Oceanography GAIC September, Galway, Ireland Gonzalez-Pola, C., Velez-Belchi, P. Sanchez-Leal, R.F., Somavilla, R., Lavin, A. and Hernandez-Guerra, A. Las Palmas University

NE Atlantic. Intergyre and EBC. Iberian Peninsula and Canaries are located in the Eastern Boundary System of the North Atlantic. (Broad weak currents, upwelling and slope flows). West Iberia and BoB at the “intergyre region” (shadow area). Tomczak and Godfrey, Reid, 1994 Pollard et. al., 1996 Pingree, Main outcome of this talk. A large shift in the hydrography of this region occurred about 10 years ago, likely having an impact on a broader scale. Below, spreading of the Mediterranean Water from the Gulf of Cadiz. And below, a mixture of intermediate and deep water masses of polar origin.

NE Atlantic. Intergyre. Bay of Biscay, Western Iberian Margin and Canary Basin, all exceeding 5000 m. Routinely sampling at: Bay of Biscay West Galicia (Finisterre) Gulf of Cadiz. Canary Basin. Starting in mid 90’s or early 00`s. Monthly programs focused on the shelf, yearly full-depth sampling, multidisciplinary programs. ENACW MW LSW ENADW LDW

Subsurface hydrography. Recent times. (I) Biscay Radiales Project: Monthly sampling (hydrographical and biological in standard sections around Spanish waters). Santander Section. 7 stations, 1 in the shelf break, two over the deep ocean (2400 and 2800) Small ship, sampling limited to 1000m depth (1500 from 2006; full water column coverage from 2013 with a new vessel). High frequency timeseries of central water properties since early 90`s. 6 7 S.Seb.

Subsurface hydrography. Recent times. (I) Biscay Winter Coldest in SW Europe (and NorthEast Temperate Atlantic) in many years NCEP/NCAR Reanalysis Sea Level Pressure (mb) anomaly. Dec04-March05. Anomalous atmospheric pattern. Mixed layer depth reached ~350 dbar in 2005 (maximum previous record since early 90`s ~240 dbar) Accumulated light modal water mixed with deeper water to create a denser variety. Depth of Isopycnal Temp at Isopycnals Modal waters become denser while warmer+ saltier (more difficult to get eroded by yearly winter mixing). Overall view, most heat accumulating at mid-depths

Subsurface hydrography. Recent times. (II) Western Iberia The Deep Sections program is running since 2003, providing full-depth (>5500 m ) hydrography and biogeochemistry at Western Iberia semiannually, then annual. Finisterre section. ~400 km. 20 Occupations so far. Salinity. Summer 2014

Subsurface hydrography. Recent times. (II) Western Iberia Large seasonality revealed, maximum at the MW levels. (Needed of seasonality removal when looking at interannual variability). 0.3ºC colder 0.5ºC warmer Variability for : Same pattern as in Biscay for central waters ~+0.14ºC dec -1 Drop in the MW to LSW levels (overall negative trend). Negligible changes below 2000 m. Overall Temp trend ~ ºC dec-1 Strong response to large-scale conditions (NAO)

Subsurface hydrography. Recent times. (III) Gulf of Cadiz Area of intense mixing between overflow waters from the Mediterranean (MOW) and Central waters from the Atlantic (ENACW) to form what is known as Mediterranean Waters (MW). Mooring line right at the passage since 2004 revealed seasonality due to the annual deep water formation cycle (warmer outflow in winter, Lafuente et.al. 2007). Several multidisciplinary cruises since mid 90`s. Warmer outflow in recent times (~0.3ºC respect to the 80`s) + warmer ENACW (presently stalled). Very noisy signal within the last 20 years. (e.g.trend at 400 m 0.5±0.3 ºC dec -1 though)

Subsurface hydrography. Recent times. (IV) Canaries Canary current system well embedded in the return path of the subptropical gyre. Deep sections have been run since late 90`s, with some interruptions. Trends of ~0.20 ºC dec -1 again at the upper thermocline waters ( m). No trends in the intermediate levels. Weak cooling at deep levels ~ ±0.01 ºC dec -1 Salinity trends: density compensating (heave). Large swings at intermediate levels

Summary of the observational record Sea Surface temperatures have raised notably during the last 40 years (+~0.6 ºC). Almost stalled within the last 10 years. Most detailed track of upper permanent thermocline since early 90`s (monthly). Warming at all levels peaking at m, (up to 0.5ºC in 20 years). Shift in water mass properties after 2005, central waters of much warmer/saltier type. Annual track of full-depth since Central Waters ( ) behaving as in Biscay. Lower thermocline waters (MW and LSW) subjected to strong variability (linked to large-scale atmospheric patterns). Passage of a cold+fresh anomaly in late 00`s No relevant changes in deep waters ( m). Relatively well covered since late 90`s. Large warming of formed MW (>0.5ºC in 15 years). Warmer ENACW that mix to form MW (not surfacemost Atlantic Waters that enter the Western Mediterranean). Annual track of full-depth since late 90`s (with some gaps). Notable warming of upper permanent thermocline (near 0.4ºC in 20 yr), by heave. No changes below 600 m, even slight cooling at deep levels.

Shift in ENACW props Shift in circulation??? Central waters at Biscay and West Iberia shifted in 2005 to a much warmer/saltier (denser) type. Such shift should have altered the zonal dynamic height. Zonal dynamic height in three sections across the intergyre from WODB2001 (grey) and ARGO after 2005 (blue)

Shift in ENACW props. Shift in circulation??? Flow reversal hypothesis imply: Warmer/saltier ENACW type not incorporating to the subtropical gyre (anomaly never reached the Canaries) ENACW contributing to the North Atlantic current, favoring an enhancement of saltier waters export to the subpolar gyre and Nordic Seas (further consequence: saltier surface waters in deep convection regions enables heat transfer towards the deep). North Atlantic Current carrying WNACW into the Nordic Seas must rearrange. ?

Thank s! IEO Ocean Hydrography Monitoring Programs Galicia-Biscay RADIALES: L. Valdés, A. Bode. Galicia-Biscay Deep Sects. A. Lavín, C. González- Pola Cadiz: Ricardo F. Sánchez. Canaries: Pedro Vélez, Alonso Hernández-Guerra

Extra

The Marine Strategy Framework Directive (UE directive) has arranged 5 marine regions (3 in the Atlantic). Monitoring programs, including oceanic hydrography, have been run since 90`s or 00`s by the IEO at the three regions. Other research projects and monitoring efforts available (CSIC, Universities, Puertos del Estado, Azti, SOCIB, PLOCAN etc) Observed Changes. Subsurface hydrography. Recent times

Subsurface hydrography. Recent times. (I) Biscay Radiales Project: Monthly sampling (hydrographical and biological in standard sections around Spanish waters). Santander Section. 7 stations, 1 in the shelf break, two over the deep ocean (2400 and 2800) Small ship, sampling limited to 1000m depth (1500 from 2006; full water column coverage from 2013 with a new vessel). High frequency timeseries of central water properties since early 90`s. 6 7 S.Seb.

It is possible to split changes at a fixed depth approximately in two main components (Levitus 1989, Bindoff & McDougall 1994, Arbic & Owens, 2001) : 1.Thermohaline properties variation at fixed isopycnal levels. Pure Warming//Freshening. [air-sea fluxes variability] 2.Variations due to vertical displacement of isopycnal levels. Pure Heave. [renewal rates, circulation changes] Approximate expression: Heating at isobaric levels “isobaric change” Heating at isopycnal levels “isopycnal change”. Modification of the thermohaline structure of the water masses Heating due to isopycnal level displacement “heave”. ‘Same water types’ but different proportions. Quantifying water masses changes

Intermediate Levels. Changes at isopycnals and isobars. St7. MW Sal Min ENACW ➯ Significant and progressive sinking until Then 27.1 outcropped surface 27.3 weak sinking 27.1//27.2 Thicker mode. 27.2// 27.3 ➯ Stable since // 27.3 ➯ 2005 shift triggered a 2-yr isopycnal warming that remains. Subsurface hydrography. Recent times. (I) Biscay

Intermediate Levels. Changes at isopycnals and isobars. St7. MW Sal Min ENACW Warming rates at all levels ºC/yr. (~0.015ºC/yr on average. 0.32ºC in 21 years). Salinity increase ~0.05 in 21 years. Subsurface hydrography. Recent times. (I) Biscay

Overall View, S temporal evolution Quick shift (isopycnal) Subsurface hydrography. Recent times. (I) Biscay

Winter Coldest in SW Europe (and NorthEast Temperate Atlantic) in many years NCEP/NCAR Reanalysis Sea Level Pressure (mb) anomaly. Dec04-March05. Anomalous atmospheric pattern. Mixed layer depth reached ~350 dbar in 2005 (maximum previous record since early 90`s ~240 dbar) Accumulated light modal water mixed with deeper water to create a denser variety.

Subsurface hydrography. (II) Western Iberia The Deep Sections program is running since 2003, providing full-depth (>5500 m ) hydrography and biogeochemistry at Western Iberia and Biscay semi-annually, then annual. Biscay series discontinued in Finisterre section. ~400 km. 20 Occupations so far. Salinity. Summer 2014

Subsurface hydrography. (II) Western Iberia Large seasonality revealed, maximum at the MW levels. (Needed of seasonality removal when looking at interannual variability). 0.3ºC colder 0.5ºC warmer Variability for : Same pattern as in Biscay for central waters ~+0.14ºC dec -1 Drop in the MW to LSW levels (overall negative trend). Negligible changes below 2000 m. Overall Temp trend ~ ºC dec-1 Strong response to large-scale conditions (NAO)

Area of intense mixing between overflow waters from the Mediterranean (MOW) and Central waters from the Atlantic (ENACW) to form what is known as Mediterranean Waters (MW). Subsurface hydrography. (III) Gulf of Cadiz Several multidisciplinary cruises since mid 90`s. Warmer outflow in recent times (~0.3ºC respect to the 80`s) + warmer ENACW (presently stalled).

Subsurface hydrography. (IV) Canaries Canary current system well embedded in the return path of the subptropical gyre. Deep sections have been run since late 90`s, with some interruptions. Trends of ~0.20 ºC dec -1 again at the upper thermocline waters ( m). No trends in the intermediate levels. Weak cooling at deep levels ~- 0.01±0.01 ºC dec -1 Salinity trends: density compensating (heave). Large swings at intermediate levels