African Coelacanth Ecosystem Programme (ACEP) (86)
Agulhas System Climate Array (ASCA) (8)
Anchovy Recruitment Survey (20)
Conservation Physiology Programme (155)
Gliders in the Agulhas (GINA) (13)
Hybrid Coordinate Ocean Model (HYCOM) (1)
Integrated Ecosystem Programme: Southern Benguela (IEP: SB) (85)
International Indian Ocean Expedition 2 (IIOE2) (5)
Long-term monitoring of nearshore temperatures around Southern Africa (938)
Marion Island Relief Voyage (50)
Port St Johns CTD and Bathymetry Survey (1)
Shelf Circulation Patterns off Port Edward (40)
South African National Antarctic Expedition (SANAE) (19)
South Atlantic Meridional Overturning Circulation (SAMOC-SA) (96)
South Atlantic Meridional Overturning Circulation Basin-wide Array (SAMBA) (18)
South Coast Demersal Biomass Survey (17)
South Coast Moorings and Monitoring Lines Cruise (18)
Southern Ocean Seasonal Cycle Experiment (SOSCEx) (3)
Underwater Temperature Recorder Mooring Network (2)
Walters Shoal (1)
Weather stations (13)
West Coast Cetacean Distribution and Abundance Survey (5)
West Coast Physical Oceanography (10)
Winter Cruise (6)
ANTARCTICA (6)
GOUGH ISLAND (7)
INDIAN OCEAN (1100)
SOUTH AFRICA (9)
SOUTH ATLANTIC OCEAN (747)
SOUTHERN OCEAN (45)
ADCP (209)
AWS (6)
CO2 ANALYZERS (2)
CTD (295)
NISKIN BOTTLES (19)
PIES (5)
PROFILERS (12)
SADCP (3)
SDS (1)
THERMOSALINOGRAPH (129)
UTR (936)
XBT (23)
Seawater temperature in the microhabitats of intertidal marine invertebrates in Sea Point, 01 to 28 September 2022
To better understand the physiological effects of marine invertebrates to changing environmental conditions, long-term monitoring which captures the natural variability of environmental parameters is required. In this way, experimental findings can be related back to field conditions, and better predictions can be made as to how marine invertebrates, particularly in the harsh intertidal, will fair with rising temperature. In May 2020, Cape Sea Urchins, Parechinus angulosus, were collected...
Seawater temperature in the microhabitats of intertidal marine invertebrates in Sea Point, 01 to 31 August 2022
To better understand the physiological effects of marine invertebrates to changing environmental conditions, long-term monitoring which captures the natural variability of environmental parameters is required. In this way, experimental findings can be related back to field conditions, and better predictions can be made as to how marine invertebrates, particularly in the harsh intertidal, will fair with rising temperature. In May 2020, Cape Sea Urchins, Parechinus angulosus, were collected...
Sun exposed temperature data from Sea Point, 11 February to 11 March 2021
To better understand the physiological effects of marine invertebrates to changing environmental conditions, long-term monitoring which captures the natural variability of environmental parameters is required. In this way, experimental findings can be related back to field conditions, and better predictions can be made as to how marine invertebrates, particularly in the harsh intertidal, will fair with rising temperature. In May 2020, Cape Sea Urchins, Parechinus angulosus, were collected...
Sun exposed temperature data from Sea Point, 03 January to 11 February 2021
To better understand the physiological effects of marine invertebrates to changing environmental conditions, long-term monitoring which captures the natural variability of environmental parameters is required. In this way, experimental findings can be related back to field conditions, and better predictions can be made as to how marine invertebrates, particularly in the harsh intertidal, will fair with rising temperature. In May 2020, Cape Sea Urchins, Parechinus angulosus, were collected...
Seawater temperature in the microhabitats of intertidal marine invertebrates in Sea Point, 01 February to 18 March 2022
To better understand the physiological effects of marine invertebrates to changing environmental conditions, long-term monitoring which captures the natural variability of environmental parameters is required. In this way, experimental findings can be related back to field conditions, and better predictions can be made as to how marine invertebrates, particularly in the harsh intertidal, will fair with rising temperature. In May 2020, Cape Sea Urchins, Parechinus angulosus, were collected...
Sun exposed temperature data from Sea Point, 21 to 30 April 2022
To better understand the physiological effects of marine invertebrates to changing environmental conditions, long term monitoring which captures the natural variability of environmental parameters is required. In this way, experimental findings can be related back to field conditions, and better predictions can be made as to how marine invertebrates, particularly in the harsh intertidal, will fair with rising temperature. In May 2020, Cape Sea Urchins, Parechinus angulosus, were collected...
Raw seawater temperature data from the long-term monitoring of the microhabitats of intertidal invertebrates in Sea Point, 01 August to 28 September 2022
To better understand the physiological effects of marine invertebrates to changing environmental conditions, long-term monitoring which captures the natural variability of environmental parameters is required. In this way, experimental findings can be related back to field conditions, and better predictions can be made as to how marine invertebrates, particularly in the harsh intertidal, will fair with rising temperature. In May 2020, Cape Sea Urchins, Parechinus angulosus, were collected...
Raw temperature data for long-term observations of bottom temperatures at Mossel Bay (January 1993 - May 1993)
Here we present raw temperatures from Underwater Temperature Recorders (UTRs) located at a depth of 8m off Mossel Bay (34.1767°S 22.1463°E), along the south coast of South Africa, between 18 January 1993 and 24 May 1993. Note that the data that falls outside of these dates is not from the deployment. At selected sites around Southern Africa, UTRs have been used to obtain long-term records of bottom temperature in the nearshore environment, at depths ranging from 2m to 34m.
Raw temperature data for long-term observations of bottom temperatures at Mossel Bay (March 1995 - July 1995)
Here we present raw temperatures from Underwater Temperature Recorders (UTRs) located at a depth of 8m off Mossel Bay (34.1767°S 22.1463°E), along the south coast of South Africa, between 20 March 1995 and 03 July 1995. Note that the data that falls outside of these dates is not from the deployment. At selected sites around Southern Africa, UTRs have been used to obtain long-term records of bottom temperature in the nearshore environment, at depths ranging from 2m to 34m.
Long-term observations of hourly bottom temperatures at Mossel Bay (November 2010 - October 2011)
Here we present processed hourly subsurface temperatures from Underwater Temperature Recorders (UTRs) located at a depth of 8m off Mossel Bay (34.1767°S 22.1463°E), along the south coast of South Africa, between 17 November 2010 and 24 October 2011. At selected sites around Southern Africa, UTRs have been used to obtain long-term records of bottom temperature in the nearshore environment, at depths ranging from 2m to 34m.
Raw temperature data for long-term observations of bottom temperatures at Mossel Bay (May 1996 - August 1996)
Here we present raw temperatures from Underwater Temperature Recorders (UTRs) located at a depth of 8m off Mossel Bay (34.1767°S 22.1463°E), along the south coast of South Africa, between 02 May 1996 and 15 August 1996. Note that the data that falls outside of these dates is not from the deployment. At selected sites around Southern Africa, UTRs have been used to obtain long-term records of bottom temperature in the nearshore environment, at depths ranging from 2m to 34m.
Raw temperature data for long-term observations of bottom temperatures at Mossel Bay (January 1998 - July 1998)
Here we present raw temperatures from Underwater Temperature Recorders (UTRs) located at a depth of 8m off Mossel Bay (34.1767°S 22.1463°E), along the south coast of South Africa, between 27 January 1998 and 13 July 1998. Note that the data that falls outside of these dates is not from the deployment. At selected sites around Southern Africa, UTRs have been used to obtain long-term records of bottom temperature in the nearshore environment, at depths ranging from 2m to 34m.
Raw temperature data for long-term observations of bottom temperatures at Mossel Bay (July 1998 - November 1998)
Here we present raw temperatures from Underwater Temperature Recorders (UTRs) located at a depth of 8m off Mossel Bay (34.1767°S 22.1463°E), along the south coast of South Africa, between 13 July 1998 and 13 November 1998. Note that the data that falls outside of these dates is not from the deployment. At selected sites around Southern Africa, UTRs have been used to obtain long-term records of bottom temperature in the nearshore environment, at depths ranging from 2m to 34m.
Raw temperature data for long-term observations of bottom temperatures at Hout Bay (July 1996 - December 1996)
Here we present raw temperatures from Underwater Temperature Recorders (UTRs) located at a depth of 28m off Hout Bay (34.05°S 18.3167°E), along the west coast of South Africa, between 24 July 1996 and 10 December 1996. Note that the data that falls outside of these dates is not from the deployment. At selected sites around Southern Africa, UTRs have been used to obtain long-term records of bottom temperature in the nearshore environment, at depths ranging from 2m to 34m.
Processed CTD data from the Walters Shoal Cruise on Algoa Voyage 207, May 2014
This is processed Conductivity, Temperature, Depth (CTD) data collected on the Walters Shoal Cruise on Algoa Voyage 207, 15 May to 11 June 2014. The purpose of this cruise was to survey the oceanographic conditions and plankton distributions around Walter Shoal seamount, from beyond the 1000m contour line across the plateau. This dataset was processed using older standards which may not align with international best practices and the standards currently adhered to by the Department of...
Sun exposed temperature data from Sea Point, 01 May to 01 June 2022
To better understand the physiological effects of marine invertebrates to changing environmental conditions, long term monitoring which captures the natural variability of environmental parameters is required. In this way, experimental findings can be related back to field conditions, and better predictions can be made as to how marine invertebrates, particularly in the harsh intertidal, will fair with rising temperature. In May 2020, Cape Sea Urchins, Parechinus angulosus, were collected...
Raw sun exposed temperature data from Sea Point, 01 August to 28 September 2022
To better understand the physiological effects of marine invertebrates to changing environmental conditions, long-term monitoring which captures the natural variability of environmental parameters is required. In this way, experimental findings can be related back to field conditions, and better predictions can be made as to how marine invertebrates, particularly in the harsh intertidal, will fair with rising temperature. In May 2020, Cape Sea Urchins, Parechinus angulosus, were collected...
Sun exposed temperature data from Sea Point, 30 June to 01 August 2022
To better understand the physiological effects of marine invertebrates to changing environmental conditions, long-term monitoring which captures the natural variability of environmental parameters is required. In this way, experimental findings can be related back to field conditions, and better predictions can be made as to how marine invertebrates, particularly in the harsh intertidal, will fair with rising temperature. In May 2020, Cape Sea Urchins, Parechinus angulosus, were collected...
Seawater temperature in the microhabitats of intertidal marine invertebrates in Sea Point, 30 June to 01 August 2022
To better understand the physiological effects of marine invertebrates to changing environmental conditions, long-term monitoring which captures the natural variability of environmental parameters is required. In this way, experimental findings can be related back to field conditions, and better predictions can be made as to how marine invertebrates, particularly in the harsh intertidal, will fair with rising temperature. In May 2020, Cape Sea Urchins, Parechinus angulosus, were collected...
Sun exposed temperature data from Sea Point, 01 to 31 August 2022
To better understand the physiological effects of marine invertebrates to changing environmental conditions, long-term monitoring which captures the natural variability of environmental parameters is required. In this way, experimental findings can be related back to field conditions, and better predictions can be made as to how marine invertebrates, particularly in the harsh intertidal, will fair with rising temperature. In May 2020, Cape Sea Urchins, Parechinus angulosus, were collected...
Sun exposed temperature data from Sea Point, 01 to 30 June 2022
To better understand the physiological effects of marine invertebrates to changing environmental conditions, long-term monitoring which captures the natural variability of environmental parameters is required. In this way, experimental findings can be related back to field conditions, and better predictions can be made as to how marine invertebrates, particularly in the harsh intertidal, will fair with rising temperature. In May 2020, Cape Sea Urchins, Parechinus angulosus, were collected...
Raw sun exposed temperature data from Sea Point, 02 December 2020 to 11 February 2021
To better understand the physiological effects of marine invertebrates to changing environmental conditions, long-term monitoring which captures the natural variability of environmental parameters is required. In this way, experimental findings can be related back to field conditions, and better predictions can be made as to how marine invertebrates, particularly in the harsh intertidal, will fair with rising temperature. In May 2020, Cape Sea Urchins, Parechinus angulosus, were collected...
Seawater temperature in the microhabitats of intertidal marine invertebrates in Sea Point, 01 to 30 June 2022
To better understand the physiological effects of marine invertebrates to changing environmental conditions, long-term monitoring which captures the natural variability of environmental parameters is required. In this way, experimental findings can be related back to field conditions, and better predictions can be made as to how marine invertebrates, particularly in the harsh intertidal, will fair with rising temperature. In May 2020, Cape Sea Urchins, Parechinus angulosus, were collected...
Sun exposed temperature data from Sea Point, 02 December 2020 to 02 January 2021
To better understand the physiological effects of marine invertebrates to changing environmental conditions, long-term monitoring which captures the natural variability of environmental parameters is required. In this way, experimental findings can be related back to field conditions, and better predictions can be made as to how marine invertebrates, particularly in the harsh intertidal, will fair with rising temperature. In May 2020, Cape Sea Urchins, Parechinus angulosus, were collected...
Seawater temperature in the microhabitats of intertidal marine invertebrates in Sea Point, 02 December 2020 to 02 January 2021
To better understand the physiological effects of marine invertebrates to changing environmental conditions, long-term monitoring which captures the natural variability of environmental parameters is required. In this way, experimental findings can be related back to field conditions, and better predictions can be made as to how marine invertebrates, particularly in the harsh intertidal, will fair with rising temperature. In May 2020, Cape Sea Urchins, Parechinus angulosus, were collected...