Filter by location

Filter by date range

DOI: 10.15493/DEA.MIMS.07172023
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...

DOI: 10.15493/DEA.MIMS.07162023
Raw sun exposed temperature data from Sea Point, 21 April 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...

DOI: 10.15493/DEA.MIMS.07572023
Seawater temperature in the microhabitats of intertidal marine invertebrates in 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...

DOI: 10.15493/DEA.MIMS.07152023
Seawater temperature in the microhabitats of intertidal marine invertebrates in Sea Point, 14 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...

DOI: 10.15493/DEA.MIMS.07142023
Raw seawater temperature data from the long-term monitoring of the microhabitats of intertidal invertebrates in Sea Point, 14 April 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...

DOI: 10.15493/DEA.MIMS.07132023
Sun exposed temperature data from Sea Point, 18 March to 21 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...

DOI: 10.15493/DEA.MIMS.07122023
Raw sun exposed temperature data from Sea Point, 18 March to 21 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...

DOI: 10.15493/DEA.MIMS.07112023
Seawater temperature in the microhabitats of intertidal marine invertebrates in Sea Point, 18 March to 14 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...

DOI: 10.15493/DEA.MIMS.07102023
Raw seawater temperature data from the long-term monitoring of the microhabitats of intertidal invertebrates in Sea Point, 18 March to 14 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...

DOI: 10.15493/DEA.MIMS.07092023
Sun exposed temperature data from 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...

DOI: 10.15493/DEA.MIMS.07082023
Raw sun exposed temperature data from 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...

DOI: 10.15493/DEA.MIMS.07072023
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...

DOI: 10.15493/DEA.MIMS.07062023
Raw seawater temperature data from the long-term monitoring of the microhabitats of intertidal 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...

DOI: 10.15493/DEA.MIMS.07052023
Sun exposed temperature data from Sea Point, 09 January to 01 February 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...

DOI: 10.15493/DEA.MIMS.07042023
Sun exposed temperature data from Sea Point, 09 December 2021 to 08 January 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...

DOI: 10.15493/DEA.MIMS.07032023
Sun exposed temperature data from Sea Point, 09 November to 08 December 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...

DOI: 10.15493/DEA.MIMS.07022023
Sun exposed temperature data from Sea Point, 08 October to 08 November 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...

DOI: 10.15493/DEA.MIMS.07012023
Raw sun exposed temperature data from Sea Point, 08 October 2021 to 01 February 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...

DOI: 10.15493/DEA.MIMS.07002023
Seawater temperature in the microhabitats of intertidal marine invertebrates in Sea Point, 09 January to 01 February 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...

DOI: 10.15493/DEA.MIMS.06992023
Seawater temperature in the microhabitats of intertidal marine invertebrates in Sea Point, 09 December 2021 to 08 January 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...

DOI: 10.15493/DEA.MIMS.06982023
Seawater temperature in the microhabitats of intertidal marine invertebrates in Sea Point, 09 November to 08 December 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...

DOI: 10.15493/DEA.MIMS.06972023
Seawater temperature in the microhabitats of intertidal marine invertebrates in Sea Point, 08 October to 08 November 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...

DOI: 10.15493/DEA.MIMS.06962023
Raw seawater temperature data from the long-term monitoring of the microhabitats of intertidal invertebrates in Sea Point, 08 October to 01 February 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...

DOI: 10.15493/DEA.MIMS.06952023
Sun exposed temperature data from Sea Point, 07 September to 08 October 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...

DOI: 10.15493/DEA.MIMS.06942023
Sun exposed temperature data from Sea Point, 07 August to 07 September 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...