Abstract
Scleractinian cold-water corals preserve in their aragonite skeleton information on the past changes of the physico-chemical properties of the seawater in which they grew. Such information is stored as geochemical signals, such as changes in trace elements concentration (B/Ca, Li/Mg, P/Ca, Sr/Ca, Ba/Ca, U/Ca) or stable and radiogenic isotopes composition (δ11B, δ13C, δ18O, 14C, εNd), that are usually converted into environmental parameters using empirical calibration equations. The aragonite skeleton of cold-water corals is sufficiently uranium-rich to be suitable for U-series dating, providing precise and accurate ages for the last 600–700 kyrs. This opens the possibility to obtain reconstructions of key oceanographic parameters for the intermediate and deep water masses at sub-decadal scale resolution for climatically-relevant time windows in the past. However, part of the geochemical signal incorporated into the coral skeleton is modulated by the physiology of the coral, which complicates the interpretation of the geochemical proxies. This “vital effect” needs to be taken into account and corrected for to obtain reliable reconstructions of past changes in seawater temperature, pH and nutrient content. On the other hand, these biologically-induced geochemical signals can be used to investigate the processes controlling coral biomineralisation and better understand the resilience of cold-water corals to environmental and climate changes.
In the recent years, Mediterranean cold-water corals have been targeted for geochemically-oriented studies and their trace elements and isotopes composition has contributed significantly to developing and understanding new and established coral proxies. Living in an environment characterised by relatively warm seawater temperatures (13–14 °C) and high pH (8.1), the Mediterranean cold-water corals provide the end-member geochemical composition useful to derive empirical calibration equations. In particular, the analysis of several specimens of the cold-water corals species Lophelia pertusa, Madrepora oculata and Desmophyllum dianthus live-collected in the western, central and eastern Mediterranean Sea, has contributed to the development of the Li/Mg thermometer, boron isotopes pH proxy and P/Ca nutrient proxy, as well as a better understanding of the neodymium isotopic composition of cold-water corals as a water mass tracer. A multi-proxy approach has been recently applied to precisely U/Th-dated cold-water corals fragments from coral-bearing sediment cores retrieved in the western and central Mediterranean Sea, showing large changes in the dynamics of the intermediate waters during the Holocene. Further investigations of fossil cold-water corals specimens from different Mediterranean locations will open new perspectives on the reconstruction of past changes in the physico-chemical properties of sub-surface waters and their potential role in modifying the Mediterranean climate.
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References
Adkins JF, Boyle EA (1997) Changing atmospheric Δ14C and the record of deep water paleoventilation ages. Paleoceanography 12:337–344. https://doi.org/10.1029/97PA00379
Adkins JF, Cheng H, Boyle EA, et al (1998) Deep-sea coral evidence for rapid change in ventilation of the deep North Atlantic 15,400 years ago. Science 280:725–728
Adkins JF, Griffin S, Kashgarian M, et al (2002) Radiocarbon dating of deep-sea corals. Radiocarbon 44:567–580
Adkins JF, Boyle EA, Curry WB, et al (2003) Stable isotopes in deep-sea corals and a new mechanism for “vital effects”. Geochim Cosmochim Acta 67:1129–1143
Adkins JF, Henderson GM, Wang S-L, et al (2004) Growth rates of the deep-sea scleractinia Desmophyllum cristagalli and Enallopsammia rostrata. Earth Planet Sci Lett 227:481–490
Aggarwal SK, You C-F (2016) A review on the determination of isotope ratios of boron with mass spectrometry. Mass Spectrom Rev 9999:1–21
Allemand D, Ferrier-Pagès C, Furla P, et al (2004) Biomineralisation in reef-building corals: from molecular mechanisms to environmental control. Comptes Rendus Palevol 3:453–467
Anagnostou E, Sherrell RM, Gagnon A, et al (2011) Seawater nutrient and carbonate ion concentrations recorded as P/Ca, Ba/Ca, and U/Ca in the deep-sea coral Desmophyllum dianthus. Geochim Cosmochim Acta 75:2529–2543. https://doi.org/10.1016/j.gca.2011.02.019
Anagnostou E, Huang K-F, You C-F, et al (2012) Evaluation of boron isotope ratio as a pH proxy in the deep sea coral Desmophyllum dianthus: evidence of physiological pH adjustment. Earth Planet Sci Lett 349:251–260
Angeletti L, Canese S, Franchi F, et al (2015) The “chimney forest” of the deep Montenegrin margin, south-eastern Adriatic Sea. Mar Pet Geol 66:542–554. https://doi.org/10.1016/j.marpetgeo.2015.04.001
Antonioli F, Auriemma R, Anzidei M, et al (2014) Sergio Silenzi (1969–2012). Quat Int 332:1
Beck JW, Edwards RL, Ito E, et al (1992) Sea-surface temperature from coral skeletal strontium/calcium ratios. Science 257:644–648
Bethoux JP, Gentili B (1996) The Mediterranean Sea, coastal and deep-sea signatures of climatic and environmental changes. J Mar Syst 7:383–394
Blamart D, Rollion-Bard C, Meibom A, et al (2007) Correlation of boron isotopic composition with ultrastructure in the deep-sea coral Lophelia pertusa : implications for biomineralization and paleo-pH. Geochem Geophys Geosyst https://doi.org/10.1029/2007GC001686
Boyle E (1998) Oceanography: pumping iron makes thinner diatoms. Nature 393:733–734. https://doi.org/10.1038/31585
Case DH, Robinson LF, Auro ME, et al (2010) Environmental and biological controls on Mg and Li in deep-sea scleractinian corals. Earth Planet Sci Lett 300:215–225
Cheng H, Adkins J, Edwards RL, et al (2000) U-Th dating of deep-sea corals. Geochim Cosmochim Acta 64:2401–2416
Cohen AL, Gaetani GA, Lundälv T, et al (2006) Compositional variability in a cold-water scleractinian, Lophelia pertusa: New insights into “vital effects”. Geochem Geophys Geosyst https://doi.org/10.1029/2006GC001354
Copard K, Colin C, Douville E, et al (2010) Nd isotopes in deep-sea corals in the North-Eastern Atlantic. Quat Sci Rev 29:2499–2508. https://doi.org/10.1016/j.quascirev.2010.05.025
Corrège T (2006) Sea surface temperature and salinity reconstruction from coral geochemical tracers. Palaeogeogr Palaeoclimatol Palaeoecol 232:408–428. https://doi.org/10.1016/j.palaeo.2005.10.014
Cuif J-P, Dauphin Y (2005) The two-step mode of growth in the scleractinian coral skeletons from the micrometre to the overall scale. J Struct Biol 150:319–331
De La Rocha CL (2003) Silicon isotope fractionation by marine sponges and the reconstruction of the silicon isotope composition of ancient deep water. Geology 31:423–426
De Lange GJ, Thomson J, Reitz A, et al (2008) Synchronous basin-wide formation and redox-controlled preservation of a Mediterranean sapropel. Nat Geosci 1:606–610
Del Bianco F, Gasperini L, Angeletti L, et al (2015) Stratigraphic architecture of the Montenegro/N. Albania Continental Margin (Adriatic Sea—Central Mediterranean). Mar Geol 359:61–74
Dickson AG (1990) Thermodynamics of the dissociation of boric acid in synthetic seawater from 273.15 to 318.15 K. Deep-Sea Res Part 1 Oceanogr Res Pap 37:755–766
Dissard D, Douville E, Reynaud S, et al (2012) Light and temperature effect on δ11B and B/Ca ratios of the zooxanthellate coral Acropora sp.: results from culturing experiments. Biogeosci Discuss 9:5969–6014
Douville E, Sallé E, Frank N, et al (2010a) Rapid and accurate U-Th dating of ancient carbonates using inductively coupled plasma-quadrupole mass spectrometry. Chem Geol 272:1–11
Douville E, Paterne M, Cabioch G, et al (2010b) Abrupt sea surface pH change at the end of the Younger Dryas in the central sub-equatorial Pacific inferred from boron isotope abundance in corals (Porites). Biogeosciences 7:2445–2459
Dubois-Dauphin Q, Bonneau L, Colin C, et al (2016) South Atlantic intermediate water advances into the North-East Atlantic with reduced Atlantic meridional overturning circulation during the last glacial period. Geochem Geophys Geosyst https://doi.org/10.1002/2016GC006281
Dubois-Dauphin Q, Montagna P, Siani G, et al (2017) Hydrological variations of the intermediate water masses of the Western Mediterranean Sea during the past 20 ka inferred from neodymium isotopic composition in foraminifera and cold-water corals. Clim Past 13:17–37
Eltgroth SF, Adkins JF, Robinson LF, et al (2006) A deep-sea coral record of North Atlantic radiocarbon through the Younger Dryas: evidence for intermediate water/deepwater reorganization. Paleoceanography. https://doi.org/10.1029/2005PA001192
Emiliani C, Hudson JH, Shinn E, et al (1978) Oxygen and carbon isotopic growth record in a reef coral from the Florida keys and a deep-sea coral from Blake Plateau. Science 202:627–629
Fallon SJ, McCulloch MT, van Woesik R, et al (1999) Corals at their latitudinal limits: laser ablation trace element systematics in Porites from Shirigai Bay, Japan. Earth Planet Sci Lett 172:221–238. https://doi.org/10.1016/S0012-821X(99)00200-9
Fink HG, Wienberg C, Hebbeln D, et al (2012) Oxygen control on Holocene cold-water coral development in the Eastern Mediterranean Sea. Deep-Sea Res Part 1 Oceanogr Res Pap 62:89–96
Fink HG, Wienberg C, De Pol-Holz R, et al (2013) Cold-water coral growth in the Alboran Sea related to high productivity during the Late Pleistocene and Holocene. Mar Geol 339:71–82
Fink HG, Wienberg C, De Pol-Holz R, et al (2015) Spatio-temporal distribution patterns of Mediterranean cold-water corals (Lophelia pertusa and Madrepora oculata) during the past 14,000 years. Deep-Sea Res Part 1 Oceanogr Res Pap 103:37–48
Flecha S, Pérez FF, García-Lafuente J, et al (2015) Trends of pH decrease in the Mediterranean Sea through high frequency observational data: indication of ocean acidification in the basin. Sci Rep 5:16770
Foster GL (2008) Seawater pH, pCO2 and [CO3 2−] variations in the Caribbean Sea over the last 130 kyr: a boron isotope and B/Ca study of planktic foraminifera. Earth Planet Sci Lett 271:254–266
Foster GL, Pogge von Strandmann PAE, Rae JWB (2010) Boron and magnesium isotopic composition of seawater. Geochem Geophys Geosyst. https://doi.org/10.1029/2010GC003201
Frank N, Paterne M, Ayliffe L, et al (2004) Eastern North Atlantic deep-sea corals: tracing upper intermediate water D14C during the Holocene. Earth Planet Sci Lett 219:297–309
Fruchter N, Eisenhauer A, Dietzel M, et al (2016) 88Sr/86Sr fractionation in inorganic aragonite and in corals. Geochim Cosmochim Acta 178:268–280. https://doi.org/10.1016/j.gca.2016.01.039
Godinot C, Ferrier-Pages C, Montagna P, et al (2011) Tissue and skeletal changes in the scleractinian coral Stylophora pistillata Esper 1797 under phosphate enrichment. J Exp Mar Biol Ecol 409:200–207
Gonzalez C, Douville E, Hall-Spencer J, et al (2012) High acidification rate of Norwegian Sea revealed by boron isotopes in the deep-sea coral Madrepora oculata. AGU fall meeting abstract 1:1994
Grossman EL, Ku T-L (1986) Oxygen and carbon isotope fractionation in biogenic aragonite: temperature effects. Chem Geol Isot Geosci Sect 59:59–74
Hassoun A, Gemayel E, Krasakopoulou E, et al (2015) Acidification of the Mediterranean Sea from anthropogenic carbon penetration. Deep-Sea Res Part 1 Oceanogr Res Pap 102:1–15
Hathorne EC, Felis T, Suzuki A, et al (2013) Lithium in the aragonite skeletons of massive Porites corals: a new tool to reconstruct tropical sea surface temperatures. Paleoceanography 28:143–152
Hemming NG, Hanson GN (1992) Boron isotopic composition and concentration in modern marine carbonates. Geochim Cosmochim Acta 56:537–543
Hines SKV, Southon JR, Adkins JF (2015) A high-resolution record of Southern Ocean intermediate water radiocarbon over the past 30,000 years. Earth Planet Sci Lett 432:46–58
Holcomb M, Venn AA, Tambutté E, et al (2014) Coral calcifying fluid pH dictates response to ocean acidification. Sci Rep 4:5207. https://doi.org/10.1038/srep05207
Holcomb M, DeCarlo TM, Gaetani GA, et al (2016) Factors affecting B/Ca ratios in synthetic aragonite. Chem Geol 437:67–76
Hönisch B, Hemming NG, Grottoli AG, et al (2004) Assessing scleractinian corals as recorders for paleo-pH: empirical calibration and vital effects. Geochim Cosmochim Acta 68:3675–3685
Hughen KA, Baillie MGL, Bard E, et al (2004) Marine04 marine radiocarbon age calibration, 0-26 cal kyr BP. Radiocarbon 46:1059–1086
Kakihana H, Kotaka M, Satoh S, et al (1977) Fundamental studies on the ion-exchange separation of boron isotopes. Bull Chem Soc Jpn 50:158–163
Klochko K, Kaufman AJ, Yao W, et al (2006) Experimental measurement of boron isotope fractionation in seawater. Earth Planet Sci Lett 248:276–285
Krief S, Hendy EJ, Fine M, et al (2010) Physiological and isotopic responses of scleractinian corals to ocean acidification. Geochim Cosmochim Acta 74:4988–5001
LaVigne M, Matthews KA, Grottoli AG, et al (2010) Coral skeleton P/Ca proxy for seawater phosphate: multi-colony calibration with a contemporaneous seawater phosphate record. Geochim Cosmochim Acta 74:1282–1293. https://doi.org/10.1016/j.gca.2009.11.002
Lazareth C, Soares-Pereira C, Douville E, et al (2016) Intra-skeletal calcite in a live-collected Porites sp.: impact on environmental proxies and potential formation process. Geochim Cosmochim Acta 176:279–294
Lécuyer C (2016) Seawater residence times of some elements of geochemical interest and the salinity of the oceans. Bull Soc Géol Fr 187:245–260
López Correa M, Montagna P, Vendrell-Simón B, et al (2010) Stable isotopes (δ18O and δ13C), trace and minor element compositions of Recent scleractinians and Last Glacial bivalves at the Santa Maria di Leuca deep-water coral province, Ionian Sea. Deep-Sea Res Part 2 Top Stud Oceanogr 57:471–486
Lutringer A, Blamart D, Frank N, et al (2005) Paleotemperatures from deep-sea corals: scale effects. In: Freiwald A, Roberts JM (eds) Cold-water corals and ecosystems. Springer, Berlin, Heidelberg, pp 1081–1096
Malinverno E, Taviani M, Rosso A, et al (2010) Stratigraphic framework of the Apulian deep-water coral province, Ionian Sea. Deep-Sea Res Part 2 Top Stud Oceanogr 57:345–359
Mangini A, Lomitschka M, Eichstädter R, et al (1998) Coral provides way to age deep water. Nature 392:347–348
Marcellin Yao K, Marcou O, Goyet C, et al (2016) Time variability of the North-Western Mediterranean Sea pH over 1995–2011. Mar Environ Res 116:51–60
Margreth S, Gennari G, Rüggeberg A, et al (2011) Growth and demise of cold-water coral ecosystems on mud volcanoes in the West Alboran Sea: the messages from the planktonic and benthic foraminifera. Mar Geol 282:26–39
Martin P, Goodkin NF, Stewart JA, et al (2016) Deep-sea coral δ13C: a tool to reconstruct the difference between seawater pH and d11B-derived calcifying fluid pH. Geophys Res Lett 43:299–308. https://doi.org/10.1002/2015GL066494
Mason HE, Montagna P, Kubista L, et al (2011) Phosphate defects and apatite inclusions in coral skeletal aragonite revealed by solid-state NMR spectroscopy. Geochim Cosmochim Acta 75:7446–7457. https://doi.org/10.1016/j.gca.2011.10.002
McCulloch M, Taviani M, Montagna P, et al (2010) Proliferation and demise of deep-sea corals in the Mediterranean during the Younger Dryas. Earth Planet Sci Lett 298:143–152
McCulloch M, Falter J, Trotter J, et al (2012a) Coral resilience to ocean acidification and global warming through pH up-regulation. Nat Clim Change 2:623–627
McCulloch M, Trotter J, Montagna P, et al (2012b) Resilience of cold-water scleractinian corals to ocean acidification: boron isotopic systematics of pH and saturation state up-regulation. Geochim Cosmochim Acta 87:21–34
Mitsuguchi T, Matsumoto E, Abe O, et al (1996) Mg/Ca thermometry in coral skeletons. Science 274:961–963
Montagna P, McCulloch M, Taviani M, et al (2005) High-resolution trace and minor element compositions in deep-water scleractinian corals (Desmophyllum dianthus) from the Mediterranean Sea and the Great Australian Bight. In: Freiwald A, Roberts JM (eds) Cold-water corals and ecosystems. Springer, Berlin, Heidelberg, pp 1109–1126
Montagna P, McCulloch M, Taviani M, et al (2006) Phosphorus in cold-water corals as a proxy for seawater nutrient chemistry. Science 312:1788–1791
Montagna P, McCulloch M, Mazzoli C, et al (2007) The non-tropical coral Cladocora caespitosa as the new climate archive for the Mediterranean: high-resolution (∼ weekly) trace element systematics. Quat Sci Rev 26:441–462
Montagna P, McCulloch M, Mazzoli C, et al (2008a) High-resolution geochemical records from cold-water corals: proxies for paleoclimate and paleoenvironmental reconstructions and the role of coral physiology. CIESM Workshop Monogr 36:55–60
Montagna P, Silenzi S, Devoti S, et al (2008b) Climate reconstructions and monitoring in the Mediterranean Sea: a review on some recently discovered high-resolution marine archives. Rend Lincei 19:121–140
Montagna P, Lopez Correa M, Ruggeberg A, et al (2009a) Li/Mg ratios in shallow-and deep-sea coral exoskeletons as a new temperature proxy. In: AGU fall meeting abstracts, p 1286
Montagna P, McCulloch M, Taviani M, et al (2009b) An improved sampling method for coral P/Ca as a nutrient proxy. Geochim Cosmochim Acta 25:1888–1947
Montagna P, Taviani M, Silenzi S, et al (2010) Marine climate archives and geochemical proxies: a review and future investigations on the Mediterranean Sea. Mar Res CNR:809–822, ISSN: 2239-5172
Montagna P, McCulloch M, Douville E, et al (2014) Li/Mg systematics in scleractinian corals: calibration of the thermometer. Geochim Cosmochim Acta 132:288–310
Noireaux J, Mavromatis V, Gaillardet J, et al (2015) Crystallographic control on the boron isotope paleo-pH proxy. Earth Planet Sci Lett 430:398–407
Nothdurft L, Webb G (2007) Microstructure of common reef-building coral genera Acropora, Pocillopora, Goniastrea and Porites: constraints on spatial resolution in geochemical sampling. Facies 53:1–26
Pagani M, Lemarchand D, Spivack A, et al (2005) A critical evaluation of the boron isotope-pH proxy: the accuracy of ancient ocean pH estimates. Geochim Cosmochim Acta 69:953–961
Painter SC, Tsimplis MN (2003) Temperature and salinity trends in the upper waters of the Mediterranean Sea as determined from the MEDATLAS dataset. Cont Shelf Res 23:1507–1522
Palmiéri J, Orr JC, Dutay JC, et al (2015) Simulated anthropogenic CO2 storage and acidification of the Mediterranean Sea. Biogeosciences 12:781–802
Pelejero C, Calvo E, McCulloch MT, et al (2005) Preindustrial to modern interdecadal variability in coral reef pH. Science 309:2204–2207
Raddatz J, Liebetrau V, Rüggeberg A, et al (2013) Stable Sr-isotope, Sr/Ca, Mg/Ca, Li/Ca and Mg/Li ratios in the scleractinian cold-water coral Lophelia pertusa. Chem Geol 352:143–152
Reimer PJ, Bard E, Bayliss A, et al (2013) IntCal13 and Marine13 radiocarbon age calibration curves 0–50,000 years cal BP. Radiocarbon 55:1869–1887
Reynaud S, Hemming NG, Juillet-Leclerc A, et al (2004) Effect of pCO2 and temperature on the boron isotopic composition of the zooxanthellate coral Acropora sp. Coral Reefs 23:539–546
Rixen M, Beckers J-M, Levitus S, et al (2005) The Western Mediterranean deep water: a proxy for climate change. Geophys Res Lett L12608: 1–4. https://doi.org/10.1029/2005GL022702
Roberts JM, Wheeler AJ, Freiwald A (2006) Reefs of the deep: the biology and geology of cold-water coral ecosystems. Science 312:543–547
Robinson LF, Adkins JF, Frank N, et al (2014) The geochemistry of deep-sea coral skeletons: a review of vital effects and applications for palaeoceanography. Deep-Sea Res Part 2 Top Stud Oceanogr 99:184–198
Rohling EJ, Marino G, Grant KM (2015) Mediterranean climate and oceanography, and the periodic development of anoxic events (sapropels). Earth-Sci Rev 143:62–97
Rollion-Bard C, Blamart D (2014) SIMS method and examples of applications in coral biomineralization. In: Gower LB (ed) Biomineralization sourcebook, characterization of biominerals and biomimetic materials. CRC Press, Boca Raton, pp 249–261
Rollion-Bard C, Blamart D, Cuif J-P, et al (2003) Microanalysis of C and O isotopes of azooxanthellate and zooxanthellate corals by ion microprobe. Coral Reefs 22:405–415. https://doi.org/10.1007/s00338-003-0347-9
Romanek CS, Grossman EL, Morse JW (1992) Carbon isotopic fractionation in synthetic aragonite and calcite: effects of temperature and precipitation rate. Geochim Cosmochim Acta 56:419–430
Rüggeberg A, Fietzke J, Liebetrau V, et al (2008) Stable strontium isotopes (δ88/86Sr) in cold-water corals — a new proxy for reconstruction of intermediate ocean water temperatures. Earth Planet Sci Lett 269:570–575
Sabatier P, Reyss J-L, Hall-Spencer JM, et al (2012) 210Pb-226Ra chronology reveals rapid growth rate of Madrepora oculata and Lophelia pertusa on world’s largest cold-water coral reef. Biogeosciences 9:1253–1265. https://doi.org/10.5194/bg-9-1253-2012
Sarnthein M, Winn K, Duplessy J-C, et al (1988) Global variations of surface ocean productivity in low and mid latitudes: influence on CO2 reservoirs of the deep ocean and atmosphere during the last 21,000 years. Paleoceanography 3:361–399. https://doi.org/10.1029/PA003i003p00361
Schneider A, Wallace DWR, Körtzinger A (2007) Alkalinity of the Mediterranean Sea. Geophys Res Lett 34:L15608:1–5. https://doi.org/10.1029/2006GL028842
Schröder-Ritzrau A, Freiwald A, Mangini A (2005) U/Th-dating of deep-water corals from the Eastern North Atlantic and the Western Mediterranean Sea. In: Freiwald A, Roberts JM (eds). Cold-water corals and ecosystems. Springer, Berlin, Heidelberg, pp 157–172
Schroeder K, Millot C, Bengara L, et al (2013) Long-term monitoring programme of the hydrological variability in the Mediterranean Sea: a first overview of the HYDROCHANGES network. Ocean Sci 9:301–324
Shen GT, Boyle EA, Lea DW (1987) Cadmium in corals as a tracer of historical upwelling and industrial fallout. Nature 328:794–796. https://doi.org/10.1038/328794a0
Sherwood OA, Lehmann MF, Schubert CJ, et al (2011) Nutrient regime shift in the Western North Atlantic indicated by compound-specific δ15N of deep-sea gorgonian corals. Proc Natl Acad Sci U S A 108:1011–1015. https://doi.org/10.1073/pnas.1004904108
Shirai K, Kusakabe M, Nakai S, et al (2005) Deep-sea coral geochemistry: implication for the vital effect. Chem Geol 224:212–222
Silenzi S, Bard E, Montagna P, et al (2005) Isotopic and elemental records in a non-tropical coral (Cladocora caespitosa): discovery of a new high-resolution climate archive for the Mediterranean Sea. Glob Planet Change 49:94–120. https://doi.org/10.1016/j.gloplacha.2005.05.005
Sinclair DJ, Kinsley LPJ, McCulloch MT (1998) High resolution analysis of trace elements in corals by laser ablation ICP-MS. Geochim Cosmochim Acta 62:1889–1901
Smith JE, Schwarcz HP, Risk MJ, et al (2000) Paleotemperatures from deep-sea corals: overcoming “vital effects”. PALAIOS 15:25–32. https://doi.org/10.2307/3515589
Spooner PT, Guo W, Robinson LF, et al (2016) Clumped isotope composition of cold-water corals: a role for vital effects? Geochim Cosmochim Acta 179:123–141
Stewart JA, Anagnostou E, Foster GL (2016) An improved boron isotope pH proxy calibration for the deep-sea coral Desmophyllum dianthus through sub-sampling of fibrous aragonite. Chem Geol 447:148–160
Stolarski J (2003) Three-dimensional micro- and nanostructural characteristics of the scleractinian coral skeleton: a biocalcification proxy - Acta Palaeontologica Polonica. Acta Palaeontol Pol 48:497–530
Stuiver M, Polach H (1977) Discussion reporting of 14C data. Radiocarbon 19:355–363
Taviani M, Vertino A, Correa ML, et al (2011) Pleistocene to recent scleractinian deep-water corals and coral facies in the Eastern Mediterranean. Facies 57:579–603
Taviani M, Angeletti L, Beuck L, et al (2016) Reprint of “On and off the beaten track: Megafaunal sessile life and Adriatic cascading processes”. Mar Geol 375:146–160. https://doi.org/10.1016/j.margeo.2015.10.003
Taviani M, Angeletti L, Canese S, et al (2017) The “Sardinian cold-water coral province” in the context of the Mediterranean coral ecosystems. Deep-Sea Res Part 2 Top Stud Oceanogr 145:61–78. https://doi.org/10.1016/j.dsr2.2015.12.008
Tesi T, Asioli A, Minisini D, et al (2017) Large-scale response of the Eastern Mediterranean thermohaline circulation to African monsoon intensification during sapropel S1 formation. Quat Sci Rev 159:139–154
Thiagarajan N, Adkins J, Eiler J (2011) Carbonate clumped isotope thermometry of deep-sea corals and implications for vital effects. Geochim Cosmochim Acta 75:4416–4425
Thil F, Blamart D, Assailly C, et al (2016) Development of laser ablation multi-collector inductively coupled plasma mass spectrometry for boron isotopic measurement in marine biocarbonates: new improvements and application to a modern Porites coral. Rapid Commun Mass Spectrom 30:359–371. https://doi.org/10.1002/rcm.7448
Titschack J, Fink HG, Baum D, et al (2016) Mediterranean cold-water corals - an important regional carbonate factory? Depos Rec 2:74–96. https://doi.org/10.1002/dep2.14
Touratier F, Goyet C (2011) Impact of the Eastern Mediterranean Transient on the distribution of anthropogenic CO2 and first estimate of acidification for the Mediterranean Sea. Deep-Sea Res Part 1 Oceanogr Res Pap 58:1–15
Trotter J, Montagna P, McCulloch M, et al (2011) Quantifying the pH “vital effect”in the temperate zooxanthellate coral Cladocora caespitosa: validation of the boron seawater pH proxy. Earth Planet Sci Lett 303:163–173
Tsimplis MN, Baker TF (2000) Sea level drop in the Mediterranean Sea: an indicator of deep water salinity and temperature changes? Geophys Res Lett 27:1731–1734
van de Flierdt T, Robinson LF, Adkins JF (2010) Deep-sea coral aragonite as a recorder for the neodymium isotopic composition of seawater. Geochim Cosmochim Acta 74:6014–6032
Vengosh A, Kolodny Y, Starinsky A, et al (1991) Coprecipitation and isotopic fractionation of boron in modern biogenic carbonates. Geochim Cosmochim Acta 55:2901–2910
Xie RC, Galer SJG, Abouchami W, et al (2015) The cadmium–phosphate relationship in the Western South Atlantic — the importance of mode and intermediate waters on the global systematics. Mar Chem 177:110–123. https://doi.org/10.1016/j.marchem.2015.06.011
Cross References
Lartaud F, Mouchi V, Chapron L, et al (this volume) Growth patterns of Mediterranean calcifying cold-water corals
Maier C, Weinbauer MG, Gattuso JP (this volume) Fate of Mediterranean scleractinian cold-water corals as a result of global climate change. A synthesis
Movilla J (this volume) A case study: variability in the calcification response of Mediterranean cold-water corals to ocean acidification
Orejas C, Taviani M, Ambroso S, et al (this volume) Cold-water coral in aquaria: advances and challenges. A focus on the Mediterranean
Taviani M, Vertino A, Angeletti L, et al (this volume) Paleoecology of Mediterranean cold-water corals
Vertino A, Corselli C (this volume) Did Quaternary climate fluctuations affect Mediterranean deep-sea coral communities?
Vertino A, Taviani M, Corselli C (this volume) Spatio-temporal distribution of Mediterranean cold-water corals
Wienberg C (this volume) A deglacial cold-water coral boom in the Alborán Sea: from coral mounds and species dominance
Acknowledgements
This chapter is dedicated to the lasting memory of Sergio Silenzi whose enthusiasm and action inspired the senior author to study geochemically the Mediterranean corals (Antonioli et al. 2014). The authors benefited from CWC collections sourced from various expeditions in the Mediterranean Sea within EU projects HERMES, HERMIONE and COCONET. This work contributes to the EU Framework Program VII Projects COCONET, (contract no. 287844), and EVER-EST (contract no. 674907), DG Environment program IDEM (grant agreement No 11.0661 /2017/750680/SUB/EN V.C2), the Flag Project RITMARE (Ricerca Italiana per il Mare) and the MISTRALS/PALEOMEX/COFIMED project.
The authors wish to thank Claudio Mazzoli, Malcolm McCulloch, Julie Trotter, Eric Douville, Nadine Tisnérat-Laborde, Edwige Pons-Branchu, Norbert Frank, Steven Goldstein, Christophe Colin and Matthias López Correa for continuous inspiration, support and collaboration in the study of coral geochemistry. This manuscript benefited from constructive suggestions by Eric Douville and Dierk Hebbeln and by the Editors. This paper is ISMAR-Bologna scientific contribution n. 1928.
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Montagna, P., Taviani, M. (2019). 11 Mediterranean Cold-Water Corals as Paleoclimate Archives. In: Orejas, C., Jiménez, C. (eds) Mediterranean Cold-Water Corals: Past, Present and Future. Coral Reefs of the World, vol 9. Springer, Cham. https://doi.org/10.1007/978-3-319-91608-8_11
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