<<–2/”>a href=”https://exam.pscnotes.com/5653-2/”>h2>SST: Sea Surface Temperature
What is SST?
Sea surface temperature (SST) refers to the temperature of the ocean’s surface layer, typically measured at a depth of a few meters. It is a crucial variable in understanding and predicting various aspects of the Earth’s Climate system, including:
- Ocean circulation: SST influences the density of ocean water, driving currents and influencing global heat distribution.
- Weather patterns: SST variations impact Atmospheric Pressure, wind patterns, and Precipitation, influencing weather events like hurricanes and El Niño.
- Marine Ecosystems: SST directly affects the distribution and abundance of marine life, impacting Fisheries-2/”>Fisheries and Biodiversity-2/”>Biodiversity.
- Climate Change: SST is a key indicator of Global Warming, showing long-term trends and revealing the impact of human activities on the planet.
Measuring SST
SST is measured using various methods, each with its own advantages and limitations:
1. In-situ measurements:
- Buoys: These floating instruments directly measure SST at the surface. They are deployed in various locations and provide continuous data.
- Ships: Ships equipped with sensors can measure SST as they travel. This method provides data along specific routes.
- Argo floats: These autonomous underwater robots measure SST and other oceanographic parameters at various depths. They provide a global Network of data.
2. Remote sensing:
- Satellites: Satellites equipped with infrared sensors can measure the thermal radiation emitted from the ocean surface, providing a global view of SST. This method is particularly useful for monitoring large-scale patterns and changes.
Table 1: Advantages and Disadvantages of SST Measurement Methods
Method | Advantages | Disadvantages |
---|---|---|
In-situ Buoys | High accuracy, continuous data | Limited spatial coverage, expensive to maintain |
In-situ Ships | Provides data along specific routes | Limited spatial coverage, susceptible to weather conditions |
In-situ Argo floats | Global coverage, provides data at various depths | Limited spatial resolution, data availability can be delayed |
Remote sensing Satellites | Global coverage, frequent data acquisition | Susceptible to cloud cover, limited accuracy near coastlines |
SST Variability
SST is not constant and exhibits significant variability at different spatial and temporal scales:
1. Diurnal cycle: SST typically shows a daily cycle, with warmer temperatures during the day and cooler temperatures at night.
2. Seasonal cycle: SST varies significantly throughout the year, with warmer temperatures in summer and cooler temperatures in winter.
3. El Niño-Southern Oscillation (ENSO): This climate pattern involves fluctuations in SST in the central and eastern Pacific Ocean, impacting weather patterns worldwide.
4. Interdecadal variability: SST can exhibit long-term trends over decades, influenced by factors like ocean circulation and climate change.
Table 2: SST Variability at Different Scales
Scale | Description | Example |
---|---|---|
Diurnal | Daily fluctuations in SST | Warmer temperatures during the day, cooler temperatures at night |
Seasonal | Annual variations in SST | Warmer temperatures in summer, cooler temperatures in winter |
ENSO | Fluctuations in SST in the Pacific Ocean | El Niño and La Niña events |
Interdecadal | Long-term trends in SST over decades | Warming trends in the North Atlantic Ocean |
Importance of SST
SST plays a crucial role in various aspects of the Earth’s climate system and human activities:
- Climate regulation: SST influences the distribution of heat and moisture in the Atmosphere, impacting global weather patterns and climate.
- Ocean circulation: SST variations drive ocean currents, influencing the transport of heat, nutrients, and marine life.
- Marine ecosystems: SST directly affects the distribution and abundance of marine species, impacting fisheries and biodiversity.
- Weather forecasting: SST data is essential for predicting weather events like hurricanes, typhoons, and El Niño.
- Climate change monitoring: SST is a key indicator of global warming, showing long-term trends and revealing the impact of human activities on the planet.
SST and Climate Change
SST is a key indicator of climate change, showing a long-term warming trend over the past century. This warming is primarily attributed to human activities, particularly the emission of greenhouse gases.
- Global warming: The increase in global Average SST is a direct consequence of the warming of the planet.
- Ocean Acidification: As the ocean absorbs more carbon dioxide from the atmosphere, it becomes more acidic, impacting marine life.
- Sea level rise: Warming Oceans cause thermal expansion, contributing to sea level rise.
- Extreme weather events: Climate change is intensifying extreme weather events, including hurricanes, droughts, and floods.
Frequently Asked Questions (FAQs)
1. What is the average SST of the ocean?
The average SST of the global ocean is around 17°C (63°F). However, SST varies significantly depending on location, season, and other factors.
2. How is SST measured?
SST is measured using various methods, including in-situ instruments like buoys and ships, and remote sensing techniques using satellites.
3. Why is SST important?
SST is a crucial variable in understanding and predicting various aspects of the Earth’s climate system, including ocean circulation, weather patterns, marine ecosystems, and climate change.
4. How does SST affect weather?
SST influences atmospheric pressure, wind patterns, and precipitation, impacting weather events like hurricanes and El Niño.
5. How does SST relate to climate change?
SST is a key indicator of global warming, showing long-term trends and revealing the impact of human activities on the planet.
6. What are the consequences of rising SST?
Rising SST contributes to ocean acidification, sea level rise, and more intense extreme weather events.
7. What can be done to address the impact of rising SST?
Reducing greenhouse gas emissions through sustainable practices and transitioning to RENEWABLE ENERGY sources are crucial steps to mitigate climate change and its impact on SST.