Ocean Monitoring Satellites and Their Opportunities, Challenges, and Applications (Especially for GATE-Geospatial 2022)

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Ocean-observing monitoring satellites are important for global and regional scale monitoring of ocean pollution and health, and assist scientists in understanding the influence and impact of the oceans on the global climate system and are amazing tools for observing the Earth and the big blue ocean that covers more than 70 percent of our planet.

Need for Satellite Ocean Monitoring: Opportunities and Challenges

  • By remotely sensing from their orbits high above the Earth, satellites provide us much more information than would be possible to obtain solely from the surface. Using satellites, NOAA researchers closely study the ocean. Information gathered by satellites can tell us about ocean bathymetry, sea surface temperature, and ocean color, coral reefs, and sea and lake ice.
  • Scientists also use data collection systems on satellites to relay signals from transmitters on the ground to researchers in the field — used in applications such as measuring tidal heights and the migration of whales. Transmitters on satellites also relay position information from emergency beacons to help save lives when people are in distress on boats, airplanes, or in remote areas. Ocean acidification (OA) is a relatively new field of research.
  • While this area has gained considerable attention over the last decade, there are many challenges in acquiring high quality datasets which can be used to better predict the implications of decreasing pH in the oceans.
  • As the ocean covers approximately 360 million sq. km. of the Earth՚s surface, difficulties surveying this enormous range confines studies to individual sites. In 2012, the Global Ocean Acidification Observing Network (GOA-ON) was formed with the aims to improve global observations and expertise.
  • Monitoring efforts are currently dominated by in situ measurements taken from research vessels, moorings and other platforms. While these methods are vital for OA research, challenging and remote regions can be difficult to access, causing low spatial and temporal resolution.

Applications of Sea Monitoring

Satellite Altimetry

Satellite altimetry is (one of) the most essential observing technique required to monitor, understand, and forecast the state of the ocean.

Ocean Surface Topography


  • Temperature of the sea surface can tell scientists a lot about what՚s happening in and around the ocean. Temperature changes influence the behavior of fish, can cause the bleaching of corals, and affect weather along the coast.
  • Satellite images of sea surface temperature also show patterns of water circulation. Examples include locations of upwelling, characterized by cold waters that rise up from the depths, often near the coasts; and warm water currents, such as the Gulf Stream.
  • The most commonly used instrument to collect sea surface temperatures is the Visible Infrared Imaging Radiometer Suite (VIIRS) instrument aboard the NOAA/NASA Suomi NPP satellite.
  • This sensor captures new data every day, allowing scientists to piece together series of maps that show sea surface temperature variations over time for different regions around the globe.

Color of the Ocean

  • Satellites also provide information about the color of the ocean. The Nimbus-7 satellite, launched in 1978, carried the first sensor, the Coastal Zone Colour Scanner (CZCS) , specifically intended for monitoring the Earth՚s oceans and water bodies.
  • The primary objective of this sensor was to observe ocean colour and temperature, particularly in coastal zones, with sufficient spatial and spectral resolution to detect pollutants in the upper levels of the ocean and to determine the nature of materials suspended in the water column. For example, color data helps researchers determine the impact of floods along the coast, detect river plumes, and locate blooms of harmful algae that can contaminate shellfish and kill other fish and marine mammals.
  • Ocean color data from satellites allows us not only to identify where an algal bloom is forming, but also to predict where it might drift in the future. Treatment plants also use algal bloom forecasts created by NOAA to decide when to change their water treatment formula to handle the algae.

Sea Level Rise

  • One of the most significant potential impacts of climate change is sea level rise, which can cause inundation of coastal areas and islands, shoreline erosion, and destruction of important ecosystems such as wetlands and mangroves. Satellite altimeter radar measurements can be combined with precisely known spacecraft orbits to measure sea level on a global basis with unprecedented accuracy.
  • The measurement of long-term changes in global mean sea level provides a way to test climate models՚ predictions of global warming.
Sea Level Change

Mapping Features in the Water

  • Satellite imagery may also be used to map features in the water, such as coral reefs. Sea floor geology is far simpler than the geology of the continents because erosion rates are lower, and also because the continents have suffered multiple collisions associated with the opening and closing of ocean basins. Despite its relative youth and geologic simplicity, most of this deep seafloor has remained poorly understood because it is masked by the ocean. To date, ships have charted only a small fraction of the seafloor.
  • But thanks to gravity, the ocean surface has broad bumps and dips that mimic the topography of the ocean floor. These bumps and dips can be mapped using a very accurate radar altimeter mounted on a satellite. The ocean plays a major role in regulating the planet՚s weather and climate.

Weather Data

  • Weather data is perhaps the most well-known application of satellite technology. NOAA՚s operational weather satellite system is composed of two types of satellites: geostationary operational environmental satellites (GOES) for short-range forecasts, warnings, and observations; and polar-orbiting satellites for longer-term forecasting. Both types of satellite are necessary to provide a complete global weather-monitoring system.
  • Satellites providing environmental imagery may also be used jointly with other organizations that receive data from various sensors. For example, marine animals, such as sea turtles and manatees, can be fitted with transmitters that relay information about their locations to orbiting satellites.

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