TY - JOUR
T1 - Boron isotope composition of the cold-water coral Lophelia pertusa along the Norwegian margin
T2 - zooming into a potential pH-proxy by combining bulk and high-resolution approaches
AU - Jurikova, Hana
AU - Liebetrau, Volker
AU - Raddatz, Jacek
AU - Fietzke, Jan
AU - Trotter, Julie
AU - Rocholl, Alexander
AU - Krause, Stefan
AU - McCulloch, Malcolm
AU - Rüggeberg, Andres
AU - Eisenhauer, Anton
N1 - This project has received funding from the European Union's Horizon 2020 research and innovation programme under the Marie Sklodowska-Curie grant agreement No. 643084 (BASE-LiNE Earth) and the collaborative research initiative CHARON (DFG Forschergruppe 1644 - Phase II) funded by the German Research Foundation. J.R. acknowledges funding from DFG project ISOLDE DU 45/1 and 45/3 and ECHO RA 2156/1. J.T. and M.M. are supported by the Australian Research Council fellowship FL120100049, CE140100020 and acknowledge support from research project DP0986505.
PY - 2019/5/20
Y1 - 2019/5/20
N2 - High-latitude cold-water coral reefs are particularly vulnerable to climate change due to enhanced CO2
uptake in these regions. To evaluate their physiological functioning
and potential application as pH archives, we retrieved both recent and
fossil samples of Lophelia pertusa along the Norwegian margin from Oslofjord (59°N), over to Trondheimsfjord, Sula and Lopphavet (70.6°N). Boron isotope analyses (δ11B) were undertaken using solution-based and laser ablation multi-collector inductively coupled plasma mass spectrometry (MC-ICP-MS; LA-ICP-MS), and secondary ion mass spectrometry
(SIMS). Epi-fluorescence microscopy was employed to provide a rapid
pre-screening routine for structure-specific subsampling in the coral
skeleton. This integrated approach enabled us to assess heterogeneities
within single specimens, as well as to investigate the role of local
environmental influences including recent and past variations. All three
mass spectrometry methods show substantial differences in the δ11B
of the theca wall (TW) and the centres of calcification (COC's).
Micro-bulk subsamples milled from the theca wall of modern specimens
originating from different habitats but with comparable seawater pH
(8–8.16) gave consistent δ11B values averaging 26.7 (±0.2‰, 2σ, n = 4), while COC subsamples systematically deviated towards lower B/Ca (by ~40%) and depleted δ11B
values (minimum 22.7 ± 0.3‰, 2σ), implying a difference of at least 4‰
between TW and COC. SIMS and LA-ICP-MS measurements identified much
larger internal heterogeneities with maximum variation of ~10‰ between
the distinct skeletal structures; minimal SIMS δ11B
values of ~17.3 ± 1.2‰ (2σ) were associated with the pure COC material.
Our findings may be interpreted in terms of the occurrence of two main,
but likely different, biomineralisation mechanisms in L. pertusa,
with the COC's generally exhibiting minimal pH up-regulation,
potentially supporting the use of bicarbonate in the early stages of
biomineralisation. Furthermore, we highlight the potential utility of L. pertusa
for palaeo-proxy studies if targeting the compositionally homogenous TW
zones devoid of COC admixtures, which appear to provide highly
reproducible measurements.
AB - High-latitude cold-water coral reefs are particularly vulnerable to climate change due to enhanced CO2
uptake in these regions. To evaluate their physiological functioning
and potential application as pH archives, we retrieved both recent and
fossil samples of Lophelia pertusa along the Norwegian margin from Oslofjord (59°N), over to Trondheimsfjord, Sula and Lopphavet (70.6°N). Boron isotope analyses (δ11B) were undertaken using solution-based and laser ablation multi-collector inductively coupled plasma mass spectrometry (MC-ICP-MS; LA-ICP-MS), and secondary ion mass spectrometry
(SIMS). Epi-fluorescence microscopy was employed to provide a rapid
pre-screening routine for structure-specific subsampling in the coral
skeleton. This integrated approach enabled us to assess heterogeneities
within single specimens, as well as to investigate the role of local
environmental influences including recent and past variations. All three
mass spectrometry methods show substantial differences in the δ11B
of the theca wall (TW) and the centres of calcification (COC's).
Micro-bulk subsamples milled from the theca wall of modern specimens
originating from different habitats but with comparable seawater pH
(8–8.16) gave consistent δ11B values averaging 26.7 (±0.2‰, 2σ, n = 4), while COC subsamples systematically deviated towards lower B/Ca (by ~40%) and depleted δ11B
values (minimum 22.7 ± 0.3‰, 2σ), implying a difference of at least 4‰
between TW and COC. SIMS and LA-ICP-MS measurements identified much
larger internal heterogeneities with maximum variation of ~10‰ between
the distinct skeletal structures; minimal SIMS δ11B
values of ~17.3 ± 1.2‰ (2σ) were associated with the pure COC material.
Our findings may be interpreted in terms of the occurrence of two main,
but likely different, biomineralisation mechanisms in L. pertusa,
with the COC's generally exhibiting minimal pH up-regulation,
potentially supporting the use of bicarbonate in the early stages of
biomineralisation. Furthermore, we highlight the potential utility of L. pertusa
for palaeo-proxy studies if targeting the compositionally homogenous TW
zones devoid of COC admixtures, which appear to provide highly
reproducible measurements.
KW - Aragonite precipitation
KW - Biomineralisation
KW - Diagenesis
KW - Isotope geochemistry
KW - Laser ablation
KW - MC-ICP-MS
KW - Ocean acidification
KW - pH and carbon cycle reconstruction
KW - SIMS
U2 - 10.1016/j.chemgeo.2019.01.005
DO - 10.1016/j.chemgeo.2019.01.005
M3 - Article
AN - SCOPUS:85060578513
SN - 0009-2541
VL - 513
SP - 143
EP - 152
JO - Chemical Geology
JF - Chemical Geology
ER -
