Vol.:(0123456789)1 3

Marine Biology          (2024) 171:29  
https://doi.org/10.1007/s00227-023-04344-8

ORIGINAL PAPER

Lophelia reefs off North and West Africa–Comparing environment 
and health

L. Buhl‑Mortensen1  · R. Houssa2 · B. M’bengue3 · E. S. Nyadjro4 · D. Cervantes1 · M. Idrissi2 · E. Mahu5 · A. S. Dia3 · 
M. Olsen1 · C. Mas1 · M. Chierici6

Received: 30 November 2022 / Accepted: 31 October 2023 
© The Author(s) 2023

Abstract
The health status of cold-water coral reefs on the West African coast was investigated with the main objective of obtain-
ing knowledge of the adaptive capacity of Lophelia pertusa to environmental stressors. Three coral sites were studied, in 
Northern Morocco, in the Morocco/Mauritania region (both in 2020) and, in the Ghana and Ivory coast region (visited in 
2012, 2017, and 2019). Area cover of live colonies, explored through underwater videos, was used as an indicator of reef 
health and compared with the environmental variables: reef position, depth, water mass, temperature, dissolved oxygen con-
centration (DO), carbonate chemistry (pH, aragonite saturation (ΩAr), macronutrients and particles (visual). For a broader 
picture of the adaptations presented by Lophelia our results were compared with reefs in contrasting environments.  Off 
Ghana and Mauritania healthy reefs (i.e., having areas with more than 20 % cover of live colonies) were found to reside at 
DO concentrations between 1.1 and 1.6 ml  L−1, in corrosive waters (pH 7.7 and ΩAr 1.0) with high nutrient concentrations. 
By contrast, the reefs off the North of Morocco, sitting in well-oxygenated waters with oversaturated ΩAr, had no or few 
live colonies. Our findings together with data from other studies show that Lophelia has a wide tolerance to hypoxia and 
acidification, and that in relation to climate change increased temperature and silting could pose more serious threats. These 
findings highlight the importance of continued studies of Lophelia reefs in contrasting environmental conditions to better 
understand their adaptation potential to climate change-related stressors.

Keywords Cold-water coral · Lophelia · West Africa · OMZ · Aragonite undersaturation

Introduction

Lophelia pertusa, synonymous with Desmophyllum per-
tusum (Addamo et al. 2016), is a cold-water Scleractinian 
coral found worldwide, and it is the major reef-forming coral 
in the North Atlantic (Davies and Guinotte 2011; Buhl-
Mortensen et al. 2015a, b; 2016). The greatest density of 
Lophelia reefs known so far has been found along the Nor-
wegian coast (Buhl-Mortensen et al. 2015a, b) but it occurs 
throughout the Atlantic and is present along the West Afri-
can coast (Buhl-Mortensen et al. 2017; Wienberg et al. 2018, 
Hanz et al. 2019; Hebbeln et al. 2020). Globally, Lophelia 
reefs occur within a wide depth range (39–3380 m). Region-
ally, however, it occurs in narrower depth zones parallel to 
the shelf break, or the rim of offshore banks and seamounts. 
It is most common at 200–1000 m in oceanic water (35 S), 
with temperatures between 4 and 12 °C (Teichert 1958; 
Zibrowius 1980; Frederiksen et al. 1992). Under favorable 
conditions, L. pertusa can form reefs that are tens of meters 

Responsible Regional Editor: Ciemon Frank Caballes.

 * L. Buhl-Mortensen 
 lenebu@hi.no

1 Institute of Marine Research, Bergen, Norway
2 Institut National de Recherche Halieutique (INRH), 

Casablanca, Morocco
3 Institut Mauritanien de Recherches Océanographiques et des 

Pêches (IMROP), Nouadhibou, Mauritanie
4 NOAA Northern Gulf Institute, Mississippi State University, 

1021 Balch Blvd, Stennis Space Center, MS 39529, USA
5 Marine Biogeochemistry, University of Ghana, Accra, Ghana
6 Institute of Marine Research, Framsenteret, Tromsø, Norway

http://crossmark.crossref.org/dialog/?doi=10.1007/s00227-023-04344-8&domain=pdf
http://orcid.org/0000-0003-0530-7119


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tall and hundreds of meters long, offering a wide range of 
habitats to other organisms (Mortensen et al. 1995; Wheeler 
et al. 2007; Buhl-Mortensen et al. 2010).

Previous studies on cold-water corals have shown that 
physical environmental factors such as temperature, salin-
ity, water velocity, substratum type and food availability 
are important drivers influencing the distribution of Lophe-
lia reefs (Strømgren 1971; Frederiksen et al. 1992; Frei-
wald et al. 1999; Mortensen et al. 2001; Dodds et al. 2007; 
Dullo et al. 2008). Few studies include information on their 
chemical environment such as the dissolved oxygen (DO) 
concentration, and aragonite saturation state (ΩAr) in the 
water column which is an indicator of potential limitation 
to calcification for Lophelia. The response of Lophelia reefs 
to climate change impacts, such as warming, deoxygena-
tion and ocean acidification (IPCC 2019) warrants further 
investigation.

Scientific literature on Lophelia reefs in Africa remains 
limited. Buhl-Mortensen et al. (2017) reported a substan-
tial reef on the Ghana/Ivory Coast shelf, and Coleman et al. 
(2005) and Wienberg et al. (2018) documented multiple 
mounds off the coast of Mauritania. The characteristics 
of these West African reefs differ from those of the North 
Atlantic reefs. These reefs, situated in an area that expe-
rienced minimal change during the last ice age, have sus-
tained ongoing growth. Additionally, they are marked by 
a significant oxygen minimum zone (OMZ). Nonetheless, 
there exists a deficiency of knowledge and data concerning 
carbonate chemistry in this African region. Such data are 
indispensable for describing the main state of ocean acidi-
fication, its variability, driving forces, and its impact on the 
condition of Lophelia reefs.

With the support of the Ecosystem Approach to Fish-
eries (EAF) Nansen program, multiple scientific surveys 
have been conducted to facilitate habitat mapping along the 
North-West (NW) African shelf and slope, as well as along 
Ghana-Ivory Coast. As part of these surveys, three cold-
water coral sites were studied: two along the Morocco and 
Mauritania coastline and one along Ghana-Ivory Coast.

The data collected during these scientific surveys have 
enabled a comprehensive study of the coral reef sites, 
covering the continental shelf/slope of the Mauritania-
Morocco coast and Ghana/Ivory Coast. Underwater videos 
and parameters such as landscape features (canyons/shelf-
slope), depth, water masses, currents, temperature fluctua-
tions, dissolved oxygen concentration, carbonate chemistry 
(pH, ΩAr), nutrient composition, and particle distribution 
have been assessed. The environmental conditions at reef 
sites were compared with the health status of reefs (level 
of cover of live and dead Lophelia colonies). The results 
from the study areas were compared with reports from other 
North Atlantic reefs. This comparative analysis of the health 
status of documented Lophelia reefs within highly divergent 

environmental contexts can offer valuable insights into their 
adaptive capacity to climate change. This study presents a 
rare insight into the range and spatial variability of ocean 
acidification state within this region, and its subsequent 
impact on the well-being of Lophelia coral reefs.

Methods and data

Study area

Multiple cruises were conducted in the years 2012, 2017, 
2019, and 2020 in the NW Africa shelf and slope, as well as 
the Ghana-Ivory Coast region, aboard the Research Vessel 
(RV) Dr. Fridtjof Nansen (DFN) as part of the EAF Nansen 
Program. This program is the outcome of a collaborative 
effort involving two prominent Norwegian institutions: the 
Norwegian Agency for Development Cooperation (Norad) 
and the Institute for Marine Research (IMR) in Bergen, 
Norway, in partnership with the United Nations' Food and 
Agriculture Organization (FAO) and NW African countries. 
These surveys successfully documented three sites with 
cold-water coral formations: Area A in northern Morocco, 
Area B at the Morocco-Mauritania border, and Area C in the 
waters of Ghana and Ivory Coast (Fig. 1).

Oceanographically, the study area is influenced in the 
north by the Canary Current System (CCS), which extends 
from the Strait of Gibraltar to the south of Guinea-Bissau 
(Bakun 1990), and in the south by the Guinea Current Sys-
tem (GCS) extending from Cape López near the equator to 
Cape Palmas at 7° W longitude. With the exception of Area 
A, Area B and C are subjected to upwelling. The CCS, one 
of the world’s four major upwelling ecosystems, is charac-
terized by seasonal variability of the trade winds between 
winter and summer inducing pronounced coastal sea surface 
temperature (SST) anomalies with a high seasonal contrast, 
mainly in the southern part of the system (BenAzzouz et al. 
2015; Arístegui et al. 2009; Barton et al. 2013). During the 
last three decades, the CCS has warmed above the perma-
nent thermocline.  The more marked warming tendencies are 
observed in the Senegalo-Mauritanian tropical sector (Kifani 
et al. 2018; Pörtner et al. 2014; Vélez-Belchí et al. 2015; 
deCastro et al. 2014; Lima and Wethey 2012; Stramma et al. 
2008).

In the Canary Current system (CCS), the core of the Oxy-
gen Minimum Zone (OMZ) extends to the surface, and the 
upwelling of older, oxygen-depleted waters with low dis-
solved oxygen (DO) content is typically accompanied by 
high concentrations of DIC (i.e.,  CO2) and consequently, 
low ΩAr and pH levels. These conditions are expected to 
be enhanced as ocean acidification progresses due to the 
increase in atmospheric  CO2 (Kifani et al. 2018; Pörtner 
et al. 2014; IPCC 2019). The Guinea Current System (GCS) 



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originates from two sources: the North Equatorial Counter-
current (NECC) and the Canary Current (CC), which flows 
into the Gulf of Guinea from the west-northwest (see Fig. 1). 
The Guinea Current (GC) follows an easterly path along 
the western coast of Africa at depths ranging from approxi-
mately 20 to 50 m, within the latitudinal range of 3°N to 
5°N (Henin et al. 1986). As it enters the Gulf of Guinea, its 
velocities can reach nearly 100 cm/s near 5°W (Richardson 
and Reverdin 1987). The seasonal variability of the source 
currents plays a role in influencing the seasonal patterns of 
the Guinea Current. It experiences a minimum flow during 
the winter months (November–February) and a maximum 
flow during the summer months (May–September) (Ing-
ham 1970). Notably, the GCS is characterized by areas of 
upwelling (Bakun 1978) and heightened biological produc-
tivity (Binet 1997). This upwelling is in geostrophic balance, 
with isotherms tilting upward towards the northern coast. As 

the current's intensity increases, this slope becomes steeper, 
bringing the thermocline closer to the coastal surface. Con-
sequently, the coastal upwelling and the summer intensi-
fication of the Guinea Current are interconnected (Philan-
der 1979). However, the Guinea Current stands out among 
upwelling regions due to the unique characteristic of exhibit-
ing minimal correlation between sea surface temperature and 
wind patterns on a seasonal time scale. This suggests that 
remote factors, such as Kelvin waves, likely contribute to 
the dynamics of the region (Longhurst 1962; Bakun 1978).

Geomorphologically, Area A belongs to the “Strait of 
Gibraltar‐Gulf of Cadiz” domain (Gibbons and Moreno 
2002). It is characterized by a variety of geomorphological 
features (allochthones units, sediment wave, mega ripples, 
and mud volcanoes) that provide dynamic and diverse envi-
ronments generating a variety of marine habitats (Agudo‐
bravo and Mangas 2015). In this zone, the continental shelf 

Fig. 1  Current systems and oceanographic features influencing 
the study areas: CC, Canary Current; GC, Guinea Current; NEC, 
North Equatorial Current; NECC, North Equatorial Countercurrent; 
nSEC, northern South Equatorial Current; NEUC, North Equatorial 

Undercurrent; SEUC, South Equatorial Undercurrent; EUC, Equato-
rial Undercurrent; sSEC, southern South Equatorial Current; GUC 
, Guinea Undercurrent; OMZ, Oxygen Minimum Zone. Green stars 
represent sampling areas



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is 40 to 50 km wide, the continental slope starts at 200 m 
and ranges from 1500 to 2000 m depth and the upwelling 
activities are seasonal (Fig. 1). Area B, is located on the 
border region between Morocco and Mauritania, between 
21°N and 20°N. It is part of the Cape Blanc‐Timiris Canyon 
landslide domain. The continental shelf is very wide as the 
result of strong sedimentation from an ancient paleo-river 
system (watershed, Tamanrasset); it extends to 140 km at 
the Banc d'Arguin. Between Cap Blanc and Cap Timiris, 
there are two groups of canyons, which converge at the foot 
of the slope and continue into the deep ocean (Agudo‐Bravo 
and Mangas 2018). In this area, the upwelling activity is 
strong and permanent with a maximum intensity in sum-
mer and early fall (Fig. 1). Area C is situated on the upper 
continental slope at around 400 m depth in the vicinity of a 
canyon, and just off the narrow continental slope off Ghana 
at 4° 46 N and 3°09 W (Buhl-Mortensen et al. 2017). Gener-
ally, the configuration of the continental shelf is controlled 
by various breach systems that appear to extend to the edge 
of the slope (Cudjoe and Khan 1972). The region where 
the reef is located falls within the maximum width region, 
approximately 100 km offshore. The slope in this area is 
steep, extending seaward along an elongated and sediment-
starved marginal ridge, the Ghana/Ivory Coast Marginal 
Ridge, which is aligned with the Romanche Fracture Zone. 
The reef is oriented perpendicular to the coast occurs within 
the depth range dominated by South Atlantic Central Water 
(SACW)–the source water mass that feeds the West African 
upwelling.

Oceanographic data

Data on hydrography and the chemical environment were 
collected during scientific cruises carried out by the FAO´s 
regional EAF Nansen program and the National Maurita-
nian marine-surveys program. During EAF Nansen surveys, 
vertical hydrography profiles and water sampling were con-
ducted using a CTD-Rosette system with 12-niskin bottles. 
In 2019, four CTD surveys were performed in Area A and 
B, which provided a high resolution of physical and chemi-
cal conditions and supported the habitat mapping survey 
conducted on cruise 2020401. The summary of the sources 
with cruise ID, sampling dates, main study area, collected 
variables and survey program are listed in Supplementary 
information ESM 1.

CTD sensors for vertical profiles and water sampling

Hydrographical conditions were documented using a CTD 
(pressure) sensor (Seabird911, SBE3plus, SBE 4c) mounted 
to a 12-Niskin bottle Rosette. Additional sensors were 
mounted on the CTD-Rosette system for measurements of 
dissolved oxygen (DO) (SBE-53), chlorophyll fluorescence 

(WET Labs ECO-FL) and Photosynthetically Active Radia-
tion (PAR, LOG CSW).

For validation and calibration of conductivity and DO 
sensors, water was collected from low-gradient depths at 
selected CTD stations for analysis. A Guildline Portasal 
Salinometer 8410A was used to measure the samples col-
lected for conductivity (salinity), whereas the DO water 
samples were measured using a Metrohm 916 Ti-Touch 
potentiometric titrator performing automated Winkler 
titrations (Grasshoff et al. 1983). Additional water column 
hydrography data (salinity, temperature, DO) were collected 
along the Mauritania coast and shelf on cruises conducted 
by the Mauritanian Institute IMROP as part of their national 
monitoring surveys between 2010 and 2012 (Supplementary 
information ESM 1).

Determination of carbonate chemistry including pH 
and aragonite saturation

Water samples were collected and analyzed for pH and total 
alkalinity (AT) onboard following the general procedures 
described in Dickson et al. (2007). AT was determined 
using potentiometric titration (Metrohm) with 0.1 N hydro-
chloric acid in an open cell. Precision for AT was between 
±2 and ±5 µmol kg −1 based on triplicate analysis of each 
sample. The accuracy was controlled using Certified Refer-
ence Material (CRM) provided by Dickson laboratory (SIO, 
USA). pH was determined on a total scale using a spectro-
photometric method and m-cresol purple as pH-sensitive 
indicator in a 1-cm pathlength quartz cuvette (Clayton and 
Byrne 1993). The perturbation from the indicator pH was 
corrected according to Chierici et al. (1999). The preci-
sion was between ±0.001 and ±0.005, based on triplicate 
measurements. The full carbonate chemistry including 
total dissolved inorganic carbon (DIC), ΩAr and in situ pH 
 (pHT), were calculated based on measured AT and pH, and 
CTD data using the carbonate system calculation program 
CO2SYS (Pierrot et al. 2006). The calculations were per-
formed on the total hydrogen ion scale, using the carbonate 
system dissolution constants from Mehrbach et al. (1973) 
refit by Dickson and Millero (1987), and the hydrogen sul-
phate  (HSO4

-) dissociation constant of Dickson (1990). The 
concentration of calcium  (Ca2+) is assumed to be propor-
tional to the salinity according to Mucci (1983; 10.28 × 
S/35 µmol  kg−1). The thermodynamic solubility products 
for aragonite and calcite (Ksp) are from Mucci (1983).

Nutrients

Seawater samples for nutrient analyses (nitrite, nitrate, sili-
cate and phosphate) were collected at each water column 
sampling station in 20 ml polyethylene vials. Samples were 
preserved with 0.2 ml chloroform and kept refrigerated and 



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dark until being sent to the Institute of Marine Research 
(IMR), Bergen, Norway for analysis. Analyses were per-
formed using a Skalar San++ Continuous Flow Analyser 
while following the procedures explained in detail by Gun-
dersen et al. (2022).

Surface ocean data from remotely sensed resources

We obtained daily sea surface temperature (SST) data on a 
0.25° × 0.25° grid from the National Oceanic and Atmos-
pheric Administration (NOAA) National Centers for Envi-
ronmental Information (NCEI) Optimum Interpolation Sea 
Surface Temperature (OISST) v2.1 product. The OISST 
product is produced by combining observations from ship 
measurements, Argo floats, buoys, and satellites (e.g., from 
the Advanced Very High-Resolution Radiometer -AVHRR- 
infrared satellite) (Reynolds et al. 2007). Six-hourly Ocean 
gap-free 0.25° × 0.25° gridded surface wind data were 
obtained from the Remote Sensing Systems’ (RSS) Cross-
Calibrated Multi-Platform (CCMP) v2.0 product (Mears 
et al. 2019). This product is produced by combining cross-
calibrated satellite microwave winds and instrument obser-
vations. Surface velocity currents at a spatial resolution of 
1° × 1° and representing mean currents in the upper 30 m 
of the ocean were obtained from the Ocean Surface Current 
Analyses Real-Time (OSCAR) data set (Bonjean and Lager-
loef 2002). OSCAR currents are produced by combining 
satellite-derived ocean surface heights, surface winds, and 
SST using a diagnostic model of ocean currents based on 
frictional and geostrophic dynamics. Monthly mean values 
are computed from daily mean values. Seasonal anomalies 
were computed as the difference between monthly climatolo-
gies and the data mean, where means are computed over the 

common period of the datasets (i.e., January 1988–Decem-
ber 2020).

Visual mapping of reef sites

In total twelve video transects targeting coral reefs were con-
ducted (Table 1 and Fig. 3), three in Area A and six in Area 
B in 2020 at cruise 2020401, and three in Area C in 2012 on 
cruise 2012407 targeting a large reef off Ghana. The posi-
tioning of video transects was selected based on bathymetry 
and acoustic backscatter gained from prior multibeam map-
ping. Positions, depth range and length of the video transects 
are provided in Table 1.

The video transect surveys were conducted using a 
Remotely Operated Vehicle (ROV) that is part of the IMR 
Video Assisted Multi Sampler (VAMS) (Buhl-Mortensen 
et al. 2017). During dives, the VAMS was towed by the DFN 
vessel at a speed of ~0.3 knots, and the ROV was remotely 
driven in front of VAMS. The benthic community compo-
nents of the seabed encountered during video recording were 
annotated using the “CampodLogger” program developed by 
IMR. It allows for selecting bottom types from a drop-down 
menu while entering taxon names and comments manually. 
These entries are automatically ‘tagged’ with date, time, 
depth (both from the ship’s echosounder and the ROV depth 
sensor), latitude and longitude (from both the ship and the 
ROV). The annotated occurrences of coral skeletons (rubble 
and blocks) and live Lophelia colonies were together with 
the bathymetry, used to identify coral reefs and their extent. 
The occurrence and cover of live coral colonies were used as 
an indicator of reef status as follows: “Dead” when no live 
colonies were observed, “Poor” when live coral colonies 
were present but never covered more than 5%, and “Healthy” 
when there were areas with a cover of live coral colonies 

Table 1  Sampling information for the 12 video transect surveys conducted on mounds and coral reefs off West Africa by R/V Dr. Fridtjof 
Nansen including station number, date, start and stop positions, depth range and length of the transect (see also Fig. 3)

Area Station Date START STOP Depth range Transect length

Deg Min Deg Min Deg Min Deg Min (m) (m)

A A5-7 18.02.2020 35 10.673 N 6 46.415 W 35 10.526 N 6 46.198 W 679–696 430
A5-8 19.02.2020 35 00.141 N 6 48.882 W 34 59.910 N 6 48.900 W 574–675 400
A5-9 19.02.2020 34 51.335 N 6 45.892 W 34 51.266 N 6 46.087 W 169–245 400

B B6-1B 01.02.2020 20 14.798 N 17 40.200 W 20 14.227 N 17 40.250 W 486–597 1200
B6-2 02.02.2020 20 14.996 N 17 42.380 W 20 15.174 N 17 42.288 W 520–581 280
B6-3 03.02.2020 20 45.862 N 17 42.262 W 20 45.974 N 17 42.091 W 452–542 300
B6-3B 03.02.2020 20 45.850 N 17 42.702 W 20 45.892 N 17 42.727 W 533–551 300
B6-4 03.02.2020 20 48.326 N 17 42.281 W 20 48.173 N 17 42.263 W 503–575 300
B6-5 03.02.2020 21 04.325 N 17 40.699 W 21 04.196 N 17 40.581 W 489–583 300

C 219 17.11.2012 4 45.681 N 3 09.181 W 4 45.850 N 3 09.253 W 385–423 277
312 23.11.2012 4 45.846 N 3 09.246 W 4 46.231 N 3 08.819 W 375–442 349
313 23.11.2012 4 46.237 N 3 08.816 W 4 46.361 N 3 08.379 W 373–402 275



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exceeding 20%. The presence of trawl marks was used as an 
indicator of physical damage from fisheries.

Results

Water mass distribution

Three water masses can be identified off the coasts of Mau-
ritania and Morocco (Figs. 1 and 2): South Atlantic Cen-
tral Water (SACW), Eastern North Atlantic Central Water 
(ENACW) and Mediterranean Intermediate Water (MIW) 
(Fig. 2). In the upper water layer, the SACW and ENACW 
are dominant, with the well-oxygenated ENACW mixing 
with the salty sub - 11°C MIW coming from the Strait of 
Gibraltar (Area A). A frontal zone is located off Cape Blanc 
at 21°N (Area B) that separates the SACW and ENACW 
where mixing occurs. The ENACW has a salinity maxi-
mum of 36.7 PSU, whereas the SACW has a lower salin-
ity maximum of 35.8 PSU (Emery 2001). The less saline 
SACW of Area B is also characterized by its DO deficiency 
with concentrations just above 1 ml  L−1 qualifying as a pro-
nounced oxygen minimum zone (OMZ) (Glessmer et al. 
2009). SACW is also rich in nutrients and, exhibits a linear 
temperature–salinity relationship. During the survey, the 
measured temperature range in the vicinity of the coral reef 
was 8.5–9 °C and the salinity range was 34.8–34.85 psu. 
The water surrounding the Ghana reef (Area C) (Fig. 2) is 
mostly dominated by SACW with its characteristic tempera-
ture between 5°C and 18°C and salinity between 34.3 and 
35.8 PSU (Emery 2001). However, it is only the low DO 
concentration of the SACW below 1.5 ml  L−1 between 300 
and 500 m that can be observed near the Ghana reef. The 
SACW can be seen mixing with the Antarctic Intermediate 
Water (AAIM) at 550 m where salinity and DO concentra-
tions begin to increase.

Characteristics of reef sites and coral status

Area A

In Area A, off the northern Moroccan Atlantic coast, the 
observed corals are located around 35° N, between 200 and 
700 m depth (Fig. 3a). In this Area, three video transect 
surveys were conducted at structures that potentially could 
be coral reefs. Table 2 and Supplementary information ESM 
2 provide, respectively, information on coral observations 
and bathymetry of the surroundings of the coral mounds 
including the position of the video transects. Three transects 
showed remnants of coral reefs buried in the sediments and 
with few visible coral skeletons (Table 2 and Supplementary 
information ESM 2) and Fig. 4 presents examples of coral 
observations from the transects. On the mound at station 

A5-7, a 430 m long transect was conducted at 692 to 700 m 
depth uncovering soft bottom with coral skeletons occurring 
in depressions. Bathymetry revealed several mounds indicat-
ing the presence of a silted large coral reef. A 400 m long 
transect was conducted at A5-8 on the continental slope at 
574 to 661 meters depth (Supplementary information ESM 
2). The detailed bathymetry reveals a large reef area with 
several visible mounds. The dense occurrence of rubble and 
coral blocks with few signs of silting indicates that the reef 
died relatively recent. The 400-meter-long transect carried 
out at A5-9 spanned depths of 169 to 245 m on a shallow 
mound characterized by bathymetric features suggesting 
the presence of a submerged reef that is entirely covered 
by sediment. The observations revealed a mixed sediment 
setting consisting of gravel, bedrock and boulders, and 47% 
soft sediment. Coral rubble and blocks that look old, gray 
colored and corroded, are present at 213-243 meters depth.

Area B

In Area B, the observed corals were located between 21°N 
and 20°N (Fig. 3b) at a depth between 400 m and 600 m. Six 
video transect surveys were recorded on mounds that indi-
cating the presence of reefs (B6-1 to B6-5) (Supplementary 
information ESM 3). At all mounds, “coral rubble” and/or 
“coral blocks” were observed and live Lophelia coral were 
found on three of these (Table 2; Supplementary informa-
tion ESM 3 and Figs. 4, 5, 6, 7). Further north the targeted 
mounds were dead reefs with coral rubble scattered over 
large areas, while lost fishing gear and trawl marks indicated 
damage by trawling. On the mound at station B6-1, a 1200 m 
long video transect was conducted covering depths from 526 
to 590 m. Here, large areas of healthy and living L. perstusa 
colonies were observed on a 70 m tall reef situated on the 
side of a canyon (Figs. 3b, 4d, 5). At station B6-2, a 280 m 
long video transect, was conducted on a 50 m tall and 350 m 
long reef, situated at 538 to 573 m depth. This reef had only 
a few scattered live L. pertusa colonies and large blocks of 
dead corals dominating the summit of the reef (Figs. 4e, 6). 
On the mound at station B6-3, a ~300 m long video tran-
sect was conducted at 453 to 540 m depth on a reef, that 
consisted mainly of dead corals. Only a single small colony 
of live L. pertusa was observed in an area with many coral 
blocks (Figs. 4f, 7). On a small mound near the larger reef 
at B6-3, at station B6-3B, a ~300 m long video transect was 
conducted between 536 and 560 m depth (Fig. 7, Supple-
mentary information ESM 3; ESM 4). Some coral rubble 
was observed but no live colonies. On the mound at B6-4 a 
~300 m long transect was conducted between 503 and 569 m 
depth, here large areas were covered with coral rubble and 
no live colonies were found (Supplementary information 



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EMS 3; ESM 4). At station B6-5 a transect was conducted 
from 492 to 583 m depth on a mound that was partly covered 
with a thick layer of coral rubble (Supplementary informa-
tion EMS 3; ESM 4).

Area C

The location of the Ghana reef site is shown in Fig. 2c. 
The multibeam bathymetric mapping conducted in 2009 
indicates that the reef is 70 m high and1400 m long and 

Fig. 2  Properties of the main water masses off the coasts of Morocco 
(Area A), Mauritania (Area B) and Ghana (Area C). a and b based 
on depth as indicated with color scale to the right. c and d based 
on dissolved oxygen concentration (ml  L−1) as indicated with color 

scale to the right. The water masses are: South Atlantic Central Water 
(SACW), Eastern North Atlantic Central Water (ENACW), Mediter-
ranean Intermediate Water (MIW), and Antarctic Intermediate Waters 
(AAIW)



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Fig. 3  Bathymetry map with isobaths showing coral reef sites. a. Area A north of Morocco. b. Area B around Morocco-Mauritania. c. Area C 
the Ghana reef at the Ghana-Ivory coast. Red dot: Reef with no live coral colonies. Blue stars: Reefs with live colonies

Table 2  Depth (m) range of Lophelia occurrences at the 12 video 
transects conducted on mounds and coral reefs of West Africa in 
areas A, B and C by RV-DFN. Coral presence is listed as the depth 

range of Dead coral (rubble and blocks), Dead blocks, Live colony 
cover. less than 5%, 5 to 20%, and more than 20%

 The occurrence of trawl marks and fishing gear at the stations is marked with x. Reef status is indicated as: Dead: only coral skeleton present, 
Poor: live corals covering < 5% in any area along the transect, Healthy: areas with a coral cover off > 20%

Area Station Dead coral Dead blocks Live <5% Live
5–20%

Live >20% Trawl marks Fishing gear Reef status

A5-7 692–700 x Dead
A A5-8 574–661 580–583 x Dead

A5-9 213–243 213–228 x x Dead
B6-1B 515–597 559–597 538–562 Healthy
B6-2 535–576 525–536 x Poor

B B6-3 454–536 457–511 469–515 x x Poor
B6-3B 538–554 x x Dead
B6-4 505–585 x x Dead
B6-5 490–577 519–556 x Dead
219 385–423 385–423 385–403 Poor

C 312 374–442 374–428 374–428 375–377 Healthy
313 373–402 373–393 373–375 375–374 Healthy



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around 250 m wide at the base. In this Area C, a large and 
healthy reef was located on the outer shelf on the eastern 
side of a canyon to the right side (Figs. 4g–i, 8). This 70 m 
high and 1400 m long reef is curve-shaped and located at 
400 m depth. All three video transect surveys (219, 312, 
and 313) that were conducted on the reef showed the pres-
ence of healthy and live corals from 375 to 428 meters 
depth (Table 2).

Physical and chemical environment of the water 
column in the NW Africa reef sites

Area A

In Area A temperature, salinity, DO, chlorophyll a flu-
orescence (Chl a), pH and aragonite saturation (ΩAr) 
decreased from surface to bottom, while total dissolved 

Fig. 4  Photos from the video transect surveys conducted on coral 
reefs, for positions of transects see Table 1 and Supplementary EMS 
1–3. From Area A: a. At A5-7 coral rubble on top of a mound (black 
arrow) was buried under soft sediment. b. At A5-8 a thick carpet of 
coral rubbles and blocks indicating an old reef. c. At A5-9 at a reef 
almost totally covered by sediment with coral blocks and debris. 
From Area B: d. At B6-1 photo from an area with > 30 % cover of 
live L. pertusa colonies from a 70 m tall and healthy reef with a rich 
fauna. e. At B6-2 a thick cover of coral skeletons and blocks was pre-

sent together with a few live colonies of L. pertusa. f. At B6-3 a small 
colony of live L. pertusa was found on a dead coral block (see also 
Fig. 5, 6, 7). At B6-3B, B6-4 and B6-5 dead reefs with coral rubble 
was observed (see Supplementary information EMS 4). From Area C 
at the large Ghana reef live L. pertusa colonies and a rich associated 
fauna was observed: g. from station 219. h. station 312 at the sumit 
of the reef. i. at station 313 (see Fig. 8 for details on video transect 
surveys)



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Fig. 5  In Area B the video transect survey at station B6-1 revealed a 
70 m tall live and healthy Lophelia reef. Above: the position of the 
transect is marked as a white line on a 3D bathymetry map (colors 

indicating depth). Below: the depth profile of the transect with the 
presence of Lophelia along the transect



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Fig. 6  In Area B the video transect survey at station B6-2 showed 
a reef with a few live corals. Above: the position of the transect is 
marked as a white line on a 3D bathymetry map colors indicating 

depth. Below: the depth profile of the transect with the presence of 
Lophelia. Dashed line: no corals observed. Only a few colonies of 
live corals were observed, for details see Fig. 4



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inorganic carbon (DIC) and nitrate  (NO3) increased 
(Figs.  9a–d; 10). This is likely caused by a gradually 
decreasing influence by the ENACW as it mixes with the 
MIW. In the upper 200 m, the warmest and most saline 
water was found mid-section at about 34.8 N, where the 

bottom shoals (Fig. 10a, b). At this point, the DO, DIC, 
ΩAr and  NO3 have lower concentrations than the sur-
rounding water and further decreased with depth (Fig. 10c, 
e, f–h). The lowest DO, observed close to the seabed at 
the seabed at the northernmost station, was below 3.9 

Fig. 7  In Area B the video transect surveys at station B6-3 covered 
two reefs. Above: the position of the transects is marked as a white 
line on a 3D bathymetry map with colors indicating depth, B6-3 to 

the right and B6-3B to the left. Below: The depth profile of transect 
B6-3 with the presence of Lophelia along the transect. Only a small 
colony of live coral was observed at B6-3, for details see Fig. 4



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ml  L−1. Here, we also found the highest  NO3 concentra-
tions (>17 µmol/L, Fig. 10h), suggesting the influence of 
MIW. DIC in the bottom is high over the whole section 
(>2170 µmol/kg) and increases towards the south to maxi-
mum values near 2200 µmol/kg (Fig. 10g), while pH and 
ΩAr decreased going south with minimum values of 7.93 
and 1.65, respectively (Fig. 10e, f).

Area B

The surface layer in Area B is ventilated by the Maurita-
nia Current and consists of relatively warm (15–22 °C) and 
salty (35.6-36.4 PSU) waters with a high DO concentration 
(4-6.8 ml  L−1) (Figs. 9e, f, 11a, b, f). Below the surface layer 
(~50m), the DO decreased considerably (minimum ~0.5 ml 

Fig. 8  The Lophelia reef on the Ghanian shelf in Area C. a. The posi-
tion of the 70 m high and 1400 m long reef. The reef is curved and is 
located at 400 m depth on the continental slope off Ghana (colours 

indicates depth in meters). b. Shaded relief showing the position of 
three video transect surveys with station number



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 L−1), as well as the temperature (<15°C). Salinity dropped 
slightly to ~35 PSU. A poorly ventilated upper thermocline 
was clearly visible between 450 and 600m depth (Figs. 9, 
11a), that is occupied by relatively old South Atlantic Cen-
tral Water (SACW). This is also the location of the observed 
coral reefs where the along-slope vertical distributions show 
relatively low DO (<1.5 ml  L−1) (Figs. 9, 11c). At the reef 
locations temperature is between 8 and 10 °C, the pH is very 
low, ΩAr values are near dissolution (~1), and coincide with 
high DIC (>2200 µmol/kg) and high  NO3 (Fig. 11e–h).

Area C

In Area C, the temperature and salinity distribution in the 
upper 800 m is presented in Figs. 9i, j and 12a, b. The upper 
40 m of the water column from coast to offshore was rela-
tively warm (>15°C), fresh, and salty (30.6-36.1 PSU) and 
DO concentrations ranging between 2 and 6 ml  L−1 (Fig. 9k) 
and highest Chl a observed in all areas (Fig. 9l). A shallow 
thermocline at ~50 m separated cooler and low DO water 
from this upper layer. Below, the cooler (<15°C), salty (~35 

Fig. 9  Vertical profiles in the upper 800 m of, temperature (°C), prac-
tical salinity (Salinity, psu), dissolved oxygen (DO, ml  L−1), and chlo-
rophyll a fluorescence (Chl a, mg  m−3) for the three areas A to C. The 

depth interval indicated with a gray shade is the depth zone where 
coral reefs were observed in the study areas



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PSU), and low DO waters (minimum ~1.1 ml  L−1) char-
acteristic of the SACW dominates the water column. The 
SACW that is most visible between 200 and 600 m depth 
extends offshore and has low pH, and ΩAr values near or 
at dissolution concentration (<1), and high DIC and  NO3 

concentrations (Fig. 12) that are especially visible on the 
slope between 300 and 400 m in 4.7 N and 4.8 N (Fig. 12f).

Interestingly, the observed coral reef occurs in the area 
with the lowest DO (Fig. 12d), pH (Fig. 12e), and ΩAr 
(Fig. 12f), and the highest DIC (Fig. 12g) (i.e., high  CO2, 

Fig. 10  Water column properties on reef sites from north to south in 
area A. a. Temperature (°C), b. Salinity (psu), c. Dissolved oxygen 
(DO, ml  L−1), d. chlorophyll a fluorescence (Chl a, mg  m−3), e. pH 

on total scale (pHT), f. aragonite saturation (ΩAr), g. total dissolved 
inorganic carbon (DIC, µmol  kg−1) and h. nitrate (µmol  L−1)



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low pH) values (Fig. 9 i–l, grey shaded area). The water sub-
sequently cools to <5°C from 600 m and below, a signature 
of the Antarctic Intermediate Water (AAIW). This water 
mass contains more DO and  NO3, and higher pH values 
than in SACW, but still, the ΩAr concentrations are at the 
minimum and are undersaturated (<1) (Fig. 12d).

Environmental parameters at coral sites

There is a clear contrast between the carbonate chemistry 
including the aragonite saturation in Area A and B. In gen-
eral, the environmental settings in Area A appeared to be 
more favorable to aragonite-forming corals than Area B. In 

Fig. 11  Water column properties on reef sites from coast to offshore 
(east to west) in area B. a. temperature (°C), b. salinity (psu), c. dis-
solved oxygen (DO, ml  L−1) d. chlorophyll a fluorescence (Chl a, 

mg  m−3), e. pH on total scale (pHT), f. aragonite saturation (ΩAr), 
g. total dissolved inorganic carbon (DIC, µmol  kg−1) and h. nitrate 
(µmol  L−1)



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Area A the DO concentrations are relatively high (>3 ml 
 L−1) and DIC and  CO2 are at moderate concentrations and 
ΩAr is relatively high (Table 3). In Area B DO concentra-
tions are low and between 1.30 and 1.65 ml  L−1, the DIC 
concentrations are among the highest in the study with a 
mean value of >2230 µmol/kg. Below 400m, ΩAr is under-
saturated (<1) favoring the dissolution of the aragonite 
mineral (Fig. 16f). The mean values for the total alkalinity 

(AT) were similar in Area A and B, 2340 and 2320 µmol/kg, 
respectively. Since the mean values for AT are similar, we 
suggest that it is the higher DIC concentrations that result in 
the low ΩAr at Area B. This means that there are likely other 
causes for the non-living reefs on both sites than existing 
environmental conditions. This is also confirmed when com-
paring environmental conditions between B and C, where 
the environmental conditions are similar. In both areas, 

Fig. 12  Water column properties on reef sites from coast to offshore 
(east to west) in area C. a. temperature (°C), b. salinity (psu), c. dis-
solved oxygen (ml  L−1), d. chlorophyll a fluorescence (Chl a, mg 

 m−3), e. pHT, f. aragonite saturation (ΩAr), g. total dissolved inor-
ganic carbon (DIC, µmol  kg−1) and h. nitrate (µmol  L−1)



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healthy coral reef sites are located in the SACW, with the 
lowest DO concentrations, a ΩAr close to or at dissolution 
concentrations (ΩAr < 1), high DIC values (>2230 µmol/
kg) and to AT (2330 µmol/kg, Table 3).

On a more local scale, the reefs with live Lophelia in 
Areas B and C were situated with their summit in the lower 
part of the oxygen minimum zone where the DO concentra-
tion start to increase with depth. Here the oxygen minimum 
zone stretched from 100 to 500 m with a slowly increasing 
DO concentration below 500 m (Figs. 9, 10, 11). The same 
feature was observed for the ΩAr which was lowest in the 
low oxygen zone, particularly evident in area B. The low 
DO concentration in this water mass coincides with a high 
concentration of DIC, nitrate and phosphate, suggesting a 
large influence from the decomposition of organic matter 
into  CO2 and nutrients (Figs. 9, 10, 11, 12).

In general, the oxygen minimum zone (OMZ) is related 
to the SACW which is an old water mass that makes lit-
tle contact with the atmosphere, where accumulation and 
decomposition of organic matter result in low DO, high 
DIC and inorganic nutrients. During the composition of 
organic matter, oxygen is consumed and inorganic carbon 
(DIC,  CO2) and nutrients (e.g. nitrate) are produced lead-
ing to low DO and high DIC concentrations. As a con-
sequence, the OMZ contains the lowest ΩAr concentra-
tions and in Area C and B undersaturation with regard to 
aragonite is found below 400 m (Figs. 11f; 12f). The high 
particle load in these areas was confirmed by the video 
observations at the sites with live corals in Area B (reef 
B6–1 and B6-2) where large quantities of marine snow 
were observed (Supplementary information ESM 5). A 
reef positioned in the lower realm of the OMZ may benefit 
from plenty of food particles while at the same time avoid-
ing the lower DO concentrations and higher temperatures 
at shallower depths. The Ghana reef in Area C was situated 
in a similar setting and in both Area B and C the healthy 
reefs were on the shelf slope break on the side of a canyon. 
It is also clear from ship and satellite data of Chl a as well 
as primary production (PP) data, that PP in upper water 
column was high at Area B and C (Figs. 11d, 12d, 14b, d). 
PP is seasonal and depends on the upwelling conditions 
along the coast (Fig. 13). Those sites are upwelling regions 
which are sites of high primary production, which may 
enhance the production in higher trophic concentrations 
and high vertical carbon transport to underlying water.

Primary production and potential food supply 
to corals based on satellite data

Area A

In Area A satellite data shows warm surface waters dur-
ing July-September and a sea surface temperature anomaly 

(SSTA) exceeding 3°C (Fig. 13a), surface winds are mainly 
northerly (Fig. 13a) and surface currents predominantly 
westward (Fig. 13c). This indicates possible remote forcing 
of the surface currents. The surface waters are most produc-
tive during summer, and off the coast of Morocco, primary 
production (PP) can exceed 400 g C  m−2  day-1 (Fig. 13c). 
During November-January the surface waters in Area A are 
cool with the winds becoming easterly and relatively weak 
offshore (Fig. 13b), meanwhile the surface currents are pre-
dominantly eastward, and the surface waters become less 
productive (Fig. 13d).

Area B

In Area B, the seasonal changes in surface oceanography are 
generally similar to those in Area A. The main difference 
between the two regions is that the winds and surface currents 
are stronger in Area B than in Area A leading to a higher pri-
mary production during summer (Fig. 13c).

Area C

In Area C the seasonal pattern of SSTA is opposite to pat-
terns observed in Areas A and B. During boreal summer it 
experiences surface temperatures that could go 3 °C lower 
than the seasonal average (Fig. 13a). This low SSTA is pri-
marily caused by wind-driven upwelling that brings cooler 
bottom waters to the surface and increases primary production 
especially off the coasts of Ivory Coast and Ghana (Fig. 13c) 
(Wiafe and Nyadjro 2015). Winds during this time are south-
westerly (Fig. 13a) and the surface Guinea Current is eastward 
(Fig. 13c). However, during boreal winter, the surface waters 
in Area C are anomalously warm and the winds are northeast-
erly (Fig. 13b), while the Guinea Current is westward, and the 
region is less productive (Fig. 13d).

Discussion

Contrasting reef conditions and vulnerability

To obtain knowledge on the physiological ranges and 
adaptive capacity of Lophelia reefs we compared the 
health status and environmental conditions of the coral 
reef sites on the Mauritania-Morocco and Ghana/Ivory 
coast and shelf/slope with information from other known 
reefs. In table 3, the health status of coral reefs from our 
study is listed together with the ocean chemistry informa-
tion from reef areas in other regions.

Norway is one of the North Atlantic countries with the 
most occurrences of Lophelia reefs. In Fig. 14 we present 
the relation between coral health, temperature, and DO 



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Page 19 of 25    29 

concentration. Norwegian reefs are in areas with DIC and 
AT conditions resulting in relatively high ΩAr between 
1.7 and 2 (Table 3), and DO of about 5 ml  L−1 (Fig. 14). 
The largest contrast between Norwegian and West African 
reefs concerning the carbonate chemistry is observed in 
the DIC and ΩAr. In Areas B and C, the DIC mean values 
reached 2260 µmol/kg, nearly 100 µmolkg−1) higher than 
is considered to be the threshold for healthy reefs (Flögel 
et al. 2014; DIC of <2170 µmol/kg). High DIC values 
(2200 µmol/kg) were found on wall reefs in Norwegian 
fjords and are considered to be sentinels for future climate 

change (Juva et al., 2021). This suggests that the reef in 
Ghana may have some adaptive capacity, which has also 
been indicated for Lophelia reefs in the Mediterranean 
(Maier et al. 2013).

Before the present study, reefs off Mauritania were 
reported to be in a dormant state with only sporadic 
occurrences of live corals and at oxygen concentrations of 
1.1–1.4 mL  L−1 (Wienberg et al. 2018), which are similar 
concentrations to our study. The few live colonies present 
in the area were viewed as part of a re-colonization of 
old and long-dead coral mounds. Based on paleo studies, 

Fig. 13  a. and b. Anomalies for composite means of sea surface tem-
perature (°C; color shading) and surface winds  (ms−1; vectors) for 
July–September (JAS) and November–January (NDJ). c and d. Pri-

mary production  (gCm−2 day-1; color shading) and surface currents 
 (ms−1; vectors) for the same seasons. Pink stars mark the location of 
the reefs on the coast off Ghana/ Ivory Coast



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Wienberg et  al. (2018) and Tamborrino et  al. (2019) 
hypothesized that regional changes in water column struc-
ture during the last ~20,000 years had caused a collapse of 
these L. pertusa dominated ecosystems due to decreasing 
DO concentrations, an explanation that was supported by 
Portilho-Ramos et al. (2022).

This contrasts with our documentation of healthy reefs 
occurring under hypoxic conditions off Mauritania which 
agrees with reports from African reefs by Buhl-Mortensen 
et al (2017) and Hanz et al. (2019). The latter found that L. 

Table 3  Health status and depth of coral reefs listed together with the mean for ocean chemistry measurements conducted at depth relevant for 
reef sites in Area A, B, and C (data sources are listed in Supplementary information ESM 1)

Area/Station Reef 
status

Reef 
depth

Depth
m

Temp.
°C

Oxygen
ml/l

ΩAr pHT AT
µmol/kg

DIC
µmol/kg

pCO2
µatm

NO3
µmol/l

PO4
µmol/l

Area A
5–7 Dead 700–692 679 11.08 3.87 1.63 7.938 2340 2175 496 17.09 1.02

696 11.10 3.89 1.66 7.940 2346 2182 497 17.52 1.05
5–8 Dead 661–574 574 11.34 4.01 1.66 7.943 2346 2174 487 15.53 0.96

675 11.49 4.09 1.75 7.954 2348 2181 492 16.99
5–9 Dead 241–213 169 15.34 4.67 2.39 8.016 2373 2148 432 5.55 0.42

245 15.47 4.71 2.40 8.019 2378 2151 436 5.77 0.42
Area B
6–1B Healthy 562–538 486 9.66 1.48

Poor 597–559 597 9.96 1.52
6–2 Poor 536–525 520 9.95 1.38

581 10.45 1.48
6–3 Poor 515–469 452–542 9.68 1.31 1.04 7.740 2317 2236 812 30.88 1.81
6–3B Dead 577–490 533–551 10.53 1.51 1.12 7.746 2324 2236 841 32.20 1.87
6–4 Dead 585–505 503 10.30 1.34

575 11.02 1.46
6–5 Dead 577–490 489 10.12 1.64 1.10 7.761 2321 2230 781 28.41 1.69

583 10.20 1.65 1.20 7.764 2328 2232 801 30.79 1.89
Area C
219 Poor 403–485 385 9.54 1.47 1.00 7.724 2305 2230 830 33.34 2.08

423 9.76 1.53 1.04 7.736 2313 2238 879 34.08 2.10
312 Healthy 428–374 375 9.47 1.47 1.00 7.724 2305 2230 830 33.34 2.08

442 9.76 1.55 1.04 7.736 2313 2238 879 34.08 2.10
313 Healthy 375–373 373 9.70 1.47 1.00 7.724 2305 2230 830 33.34 2.08

402 9.76 1.48 1.04 7.736 2313 2238 879 34.08 2.10

Norway
Hola (1) Healthy 260 6.70 1.72 8.01 2314 2135 364 3.77 0.48

8.18 1.91 8.07 2332 2162 419 11.69 0.73
Wall (2) Healthy 80 –220 7.51 4.96 1.5 7.944 2300 2136 374 8.64 0.67

12.2 5.81 1.98 8.063 2330 2187 501 11.61 0.96
Banks (2) Healthy 190–220 7.53 5.07 1.56 7.968 2317 2135 356 10.40 0.69

8.35 5.75 2.01 8.081 2343 2192 506 11.37 0.89

Mauritania (3) Healthy 596–560 10.0–12.0 1.1–1.4
Namibia (4) Dead 260–160 11.8–13.2 0–0.15 8.010
Angola (4) Healthy 473–331 7.8–11.1 0.6–1.1 8.120

Poor 260–250 11.1–14.1 0.7–0.9
Gulf of Mexico (5) Healthy 600–500 6.6–11.6 2.7–2.8

 Reef status: “Dead” no observations of live colonies, “Poor” only few live colonies. and “Healthy” larger areas with live colonies. For comparison 
the lower part of the table includes information from Lophelia reefs in Norway, other regions off west Africa and the Gulf of Mexico with reported 
reef status and ocean chemistry measurements from literature. Sources are: (1) Järnegren and Kutti (2014), (2) Juva et al. (2021), (3) Phaeton 
report (2012), (4) Hanz et al. (2019), (5) Matos (2017)



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Fig. 14  Plot of the temperature 
and oxygen setting in Lophelia 
reef areas with health status 
indicated by symbols. Red cir-
cle: healthy reef with large areas 
having a dense cover of live 
colonies. Pink circle: poor reef 
with only a few occurrences of 
live colonies. Black circle: dead 
reef with only the presence of 
coral skeleton. Pink bar along 
the axis indicates range for the 
occurrence of live Lophelia. 
Reefs are encircled in accord-
ance with geographic area. 
Background data is provided in 
Table 3

pertusa could thrive in hypoxic and rather warm waters in 
the NE Atlantic off Angola. Hebbeln et al. (2020) stated 
that reefs appear to thrive at DO concentrations of 1 ml 
 L−1 and at temperatures up to 14.2 °C and the authors 
speculate that the negative effects of hypoxia and high 
temperature could be compensated for by enhanced food 
supply. This theory seems to be at odds with the general 
observation that increased feeding will increase respira-
tion rate (Maier et al. 2013) and thus the oxygen demand. 
In addition, an increased load of organic particles will 
demand more mucus production to clean the coral which 
in turn would increase respiration and oxygen demand 
(Buhl-Mortensen et al. 2015a, b).

The relationship between reef health and environmental 
conditions (Fig. 14) indicates that the tolerance window for 
hypoxia is larger than for temperature. This supports the 
view that L. pertusa as a species appears to have a high oxy-
gen tolerance, but individual populations could have limited 
adaptive capabilities to cope with reductions (Dodds et al. 
2007; Lunden et al. 2013). The tolerance to hypoxia could 
be related to the relatively low respiration rate of cold water 
Scleractinia (Buhl-Mortensen et al. 2007, Maier 2013). 
Maier et al. (2013) and Hebbeln (2020) suggest that local 
adaptation can affect tolerance to environmental stressors 

and highlights the need to compare reefs in contrasting 
settings.

Environmental conditions and age and growth of reefs

Both the Mauritanian and Ghanaian reefs are of substantial 
size and occurs in a region where the conditions during the 
last ice age allowed for continued growth. Reefs off Nor-
way have been aged using radiocarbon and Uranium/Tho-
rium techniques (Mikkelsen et al.1982; Mortensen 2000; 
Rokoengen and Østmo 1985), estimating a maximum age 
of around 9000 years. The vertical extension of a 30 m high 
and 9000-year-old reef indicates a reef growth of 3.3 mm 
 year-1. Applying this reef growth rate to the African reefs, 
heights of 60 to 70 m, indicates continuous growth for at 
least 20,000 years. This is in line with the U/Th-dating 
of deep-water corals from seamounts off NW-Africa by 
Schröder-Ritzrau et al. (2005) which showed that the cor-
als have had continuous growth over the last 53,000 years. 
This does not support the hypothesis that live colonies in the 
region represent a re-colonization of old and dead reefs pro-
posed by Wienberg et al. (2018), Tamborrino et al. (2019) 
and Portilho-Ramos et al. (2022). On the Norwegian shelf, 
the main temperatures in areas where thriving old reefs are 
located range from 4 to 12 °C. The temperature range of 



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8.5–9 °C recorded at the African reef sites examined in this 
study falls within this established range. Therefore, dispari-
ties in temperature are unlikely to account for the observed 
variations in size. Furthermore, reefs in both areas occur in 
highly productive upwelling settings with a good food sup-
ply. There is, however, a possibility that the reef growth was 
interrupted at some stage during the Holocene transgres-
sion or the Holocene itself. Ayers and Pilkey (1981) have 
dated some coral samples from the Florida–Hatteras slope 
and inner Blake Plateau, in the Western Atlantic. Their dead 
coral samples ranged in age from 5000 to 44,000 years old. 
The much younger age of Norwegian reefs reflects the strong 
glacial influence (Mortensen 2000). Verification of reef age 
will require the ageing of skeleton sampled by coring to 
the base of the reef. Cores have been collected from reef 
remnants in other areas of Africa but results on age have to 
our knowledge not yet been published (Westphal et al. 2012 
unpublished data).

Conclusions

Based on many studies from the North Atlantic the assumed 
lower limit of oxygen tolerance of L. pertusa ranges around 
a DO concentration of 2–3.7 ml  L−1. However, the first large 
and healthy reef off Atlantic Africa was found off Ghana 
in the OMZ zone (Buhl-Mortensen et al. 2017). Our study 
has shown that large and old thriving reefs occur off Africa 
in areas with low oxygen concentrations. Clearly, this spe-
cies has a broad tolerance for oxygen concentrations at least 
down to 1 ml  L−1, altering our view on oxygen demand for 
L. pertusa .

The African reefs are much older than the northern coun-
terpart which clearly shows that low DO consentration, pH, 
and low ΩAr are not hindering rich and healthy Lophelia 
reefs, this is in line with the observations by Maier et al. 
(2013) who found that Lophelia reefs in the Mediterranean 
are not affected by or may be adapted to corrosive aragonite 
conditions. However, studies show that calcifying organisms 
can calcify at corrosive conditions but to an energetic cost 
(Spalding et al. 2017).

The reefs in the OMZ co-occur with a rich load of organic 
particles and are probably more than double the age of 
northern reefs. The OMZ reefs will trap a lot of sediment 
during their growth. Likely both growth and aging patterns 
differ from the northern reefs as do tolerances to environ-
mental stressors: e.g., lower oxygen, pH, ΩAr, industrial 
activities resulting in physical damage and increased silt-
ing. Even though climatic changes causing a decrease in 
oxygenation might not be a serious threat to Lophelia reefs 
in general, in already hypoxic settings this might be differ-
ent. Even if smaller decreases in DO alone might not pose a 
serious threat to Lophelia reefs, they must be considered in 

concert with other changing environmental parameters that 
might form additional stressors such as increased tempera-
ture and physical pressure from silting and crushing related 
to industrial activities such as fisheries. The dead or almost 
dead reefs we observed in Area B near an old healthy and 
large reef had signs of physical damage that can be attributed 
to trawling.

Our findings highlight the importance of continued 
studies of Lophelia reefs in contrasting environmental 
conditions to improve our understanding of their resilience 
and adaptation potential in relation to climate change, 
ocean acidification, and other stressors.

Acknowledgements This paper uses data collected through scientific 
surveys with the research vessel Dr. Fridtjof Nansen as part of the 
collaboration between the Food and Agriculture Organization of the 
United Nations (FAO) on behalf of the EAF-Nansen Programme. The 
EAF-Nansen Programme is a partnership between the FAO, the Nor-
wegian Agency for Development Cooperation (Norad), and the Institute 
of Marine Research (IMR) in Norway for sustainable management of 
the fisheries in partner countries and regions. We are grateful to all 
cruises and their participants for their help and support during the 
data collection.

Funding Open access funding provided by Institute Of Marine 
Research. All authors certify that they have no affiliations with or 
involvement in any organization or entity with any financial interest 
or non-financial interest in the subject matter or materials discussed in 
this manuscript. The authors have no financial or proprietary interests 
in any material discussed in this article.

Data availability Data is available upon request.

Declarations 

Conflict of interest The authors have no relevant financial or non-fi-
nancial interests to disclose. The authors have no competing interests 
to declare that are relevant to the content of this article. No experimen-
tal use of organisms was part of this study.

Open Access This article is licensed under a Creative Commons Attri-
bution 4.0 International License, which permits use, sharing, adapta-
tion, distribution and reproduction in any medium or format, as long 
as you give appropriate credit to the original author(s) and the source, 
provide a link to the Creative Commons licence, and indicate if changes 
were made. The images or other third party material in this article are 
included in the article’s Creative Commons licence, unless indicated 
otherwise in a credit line to the material. If material is not included in 
the article’s Creative Commons licence and your intended use is not 
permitted by statutory regulation or exceeds the permitted use, you will 
need to obtain permission directly from the copyright holder. To view a 
copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.

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https://doi.org/10.1130/G46672.1
https://doi.org/10.1007/s00531-006-0130-6
https://doi.org/10.1007/s00531-006-0130-6

	Lophelia reefs off North and West Africa–Comparing environment and health
	Abstract
	Introduction
	Methods and data
	Study area
	Oceanographic data
	CTD sensors for vertical profiles and water sampling
	Determination of carbonate chemistry including pH and aragonite saturation
	Nutrients
	Surface ocean data from remotely sensed resources

	Visual mapping of reef sites

	Results
	Water mass distribution
	Characteristics of reef sites and coral status
	Area A
	Area B
	Area C

	Physical and chemical environment of the water column in the NW Africa reef sites
	Area A
	Area B
	Area C

	Environmental parameters at coral sites
	Primary production and potential food supply to corals based on satellite data
	Area A
	Area B
	Area C


	Discussion
	Contrasting reef conditions and vulnerability
	Environmental conditions and age and growth of reefs


	Conclusions
	Acknowledgements 
	References