Blogarchiv
Raumfahrt - NASA To Launch 4 Earth Science Missions in 2022

15.12.2021

jpss-2

NASA will launch four Earth science missions in 2022 to provide scientists with more information about fundamental climate systems and processes including extreme storms, surface water and oceans, and atmospheric dust. Scientists will discuss the upcoming missions at the American Geophysical Union’s (AGU) 2021 Fall Meeting, hosted in New Orleans between Dec. 13 and 17.

 

NASA has a unique view of our planet from space. NASA’s fleet of Earth-observing satellites provide high quality data on Earth’s interconnected environment, from air quality to sea ice.

 

These four missions will enhance the ability to monitor our changing planet:

  • TROPICS will use six small satellites to provide improved and rapid measurements of tropical cyclones.
  • EMIT will trace the origin and composition of mineral dust that can affect climate, ecosystems, air quality, and human health with an imaging spectrometer aboard the International Space Station.
  • NOAA’s JPSS-2 will help scientists predict extreme weather conditions including floods, wildfires, volcanoes and more.
  • SWOT will evaluate the world’s oceans and their role in climate change, as well as monitor lakes, rivers, and other surface waters.

 

NASA has a unique view of our planet from space. NASA’s fleet of Earth-observing satellites provide high quality data on different parts of Earth’s interconnected environment from air quality to sea ice. Take a tour of missions launching in 2022, including SWOT, TROPICS, EMIT, and JPSS-2.
Credits: NASA

Measuring Tropical Cyclones

 

Photograph of the rectangular TROPICS CubeSat Pathfinder satellite standing on one end with its solar panel perpendicular and horizontal to its left at the base.
The TROPICS Pathfinder satellite, pictured above, was launched on June 29. The satellite body measures approximately 10 cm X 10 cm X 36 cm and is identical to the six additional satellites that will be launched in the constellation in 2022. The golden cube at the top is the microwave radiometer, which measures the precipitation, temperature, and humidity inside tropical storms.
Credits: Blue Canyon Technologies

Time-Resolved Observations of Precipitation structure and storm Intensity with a Constellation of Smallsats (TROPICS)

 

NASA’s TROPICS mission aims to improve observations of tropical cyclones. Six TROPICS satellites will work in concert to provide microwave observations of a storm's precipitation, temperature, and humidity as quickly as every 50 minutes. Scientists expect the data will help them understand the factors driving tropical cyclone intensification and will contribute to weather forecasting models.

 

In June 2021, the first pathfinder, or proof of concept, satellite of the constellation started collecting data, including from Hurricane Ida in August 2021, that shows the promise of these small satellites. The TROPICS satellites will be deployed in pairs of two over three different launches, expected to be completed by July 31, 2022.

Each satellite is about the size of a loaf of bread and carries a miniaturized microwave radiometer instrument. Traveling in pairs in three different orbits, they will collectively observe Earth’s surface more frequently than current weather satellites making similar measurements, greatly increasing the data available for near real-time weather forecasts.

 

The TROPICS team is led by Principal Investigator Dr. William Blackwell at MIT’s Lincoln Laboratory in Lexington, Massachusetts, and includes researchers from NASA, the National Oceanic and Atmospheric Administration (NOAA), and several universities and commercial partners. NASA’s Launch Services Program, based at the agency’s Kennedy Space Center in Florida, will manage the launch service.

 

“The coolest part of this program is its impact on helping society,” Blackwell said. “These storms affect a lot of people. The higher frequency observations provided by TROPICS have the potential to support weather forecasting that may help people get to safety sooner.”

 

 

Studying Mineral Dust

 

True color satellite imagery of a large brown dust storm stretching from West Africa halfway across the Atlantic Ocean.
In June 2020, the "Godzilla" dust storm traveled from the Sahara desert across the Atlantic Ocean, as seen in this true color satellite imagery from the Visible Infrared Imaging Radiometer Suite (VIIRS) aboard the NASA-NOAA Suomi NPP satellite and the NOAA-20 satellite.
Credits: NASA / Scientific Visualization Studio

Earth Surface Mineral Dust Source Investigation (EMIT)

 

Winds kick up dust from Earth’s arid regions and transport the mineral particles around the world. The dust can influence the radiative forcing  or the balance between the energy that comes toward Earth from the Sun, and the energy that Earth reflects back out into space hence the temperature of the planet’s surface and atmosphere. Darker, iron-laden minerals tend to absorb energy, which leads to heating of the environment, while brighter, clay-containing particles scatter light in a way that may lead to cooling. In addition to affecting regional and global warming of the atmosphere, dust can affect air quality and the health of people worldwide, and when deposited in the ocean, can also trigger blooms of microscopic algae.

 

The goal of the Earth Surface Mineral Dust Source Investigation (EMIT) mission is to map where the dust originates and estimate its composition so that scientists can better understand how it affects the planet. Targeted to launch in 2022, EMIT has a prime mission of one year and will be installed on the International Space Station. EMIT will use an instrument called an imaging spectrometer that measures visible and infrared light reflecting from surfaces below. This data can reveal the distinct light-absorbing signatures of the minerals in the dust that helps to determine its composition.

 

“EMIT will close a gap in our knowledge about arid land regions of our planet and answer key questions about how mineral dust interacts with the Earth system,” said Dr. Robert Green, EMIT principal investigator at NASA’s Jet Propulsion Laboratory in Southern California.

 

Observing Earth’s Storms

 

An artists illustration of a satellite with a single extended solar panel in space above Earth.
An illustration of the Joint Polar Satellite System (JPSS). JPSS is a collaborative program between the National Oceanic and Atmospheric Administration (NOAA) and NASA. JPSS-2 is NOAA’s next-generation operational Earth observation program that acquires and distributes global environmental data primarily from multiple polar-orbiting satellites.
Credits: Orbital ATK/Northrop Grumman Innovation Systems

Joint Polar Satellite System (JPSS)

 

Forecasting extreme storms many days in advance requires capturing precise measurements of the temperature and moisture in our atmosphere, along with ocean surface temperatures. The NOAA/NASA Joint Polar Satellite System satellites provide this critical data, which is used by forecasters and first responders. The satellites also tell us about floods, wildfires, volcanoes, smog, dust storms, and sea ice.

“JPSS satellites are a vital component of the global backbone of numerical weather prediction,” said JPSS Program Science Adviser Dr. Satya Kalluri. 

The JPSS satellites circle Earth from the North to the South Pole, taking data and images as they fly. As Earth rotates under these satellites, they observe every part of the planet at least twice a day. 

The Suomi-NPP (National Polar orbiting-Partnership) and NOAA-20 satellites are currently in orbit. The JPSS-2 satellite is targeted to launch in 2022 from Vandenberg Space Force Base in California on a United Launch Alliance Atlas V rocket. Three more satellites will launch in coming years, providing data well into the 2030s. NASA's Launch Services Program, based at the agency's Kennedy Space Center in Florida, will manage the launch service.

Surveying Earth’s Surface Water and Oceans

Surface Water and Ocean Topography (SWOT)

 

The Surface Water and Ocean Topography (SWOT) mission will help researchers determine how much water Earth’s oceans, lakes, and rivers contain. This will aid scientists in understanding the effects of climate change on freshwater bodies and the ocean’s ability to absorb excess heat and greenhouse gases like carbon dioxide.

 

NASA’s Launch Services Program, based at the agency’s Kennedy Space Center in Florida, will manage the launch service, which is targeted for November 2022. SWOT will launch on a SpaceX Falcon 9 rocket from Vandenberg Space Force Base in California.

Illustration of the SWOT satellite taking measurements of water height over the ocean and freshwaters of Florida.
SWOT will collect data across a 75 mile (120 kilometer) wide swath, with a gap in the center for an altimetry track. This animation shows the collection of data over the state of Florida, which is rich with rivers, lakes and wetlands. Globally, measurements will be taken both over the ocean and over freshwater areas.
Credits: NASA/JPL-Caltech

The SUV-size satellite will measure the height of water using its Ka-band Radar Interferometer, a new instrument that bounces radar pulses off the water’s surface and receives the return signals with two different antennas at the same time. This measurement technique allows scientists to precisely calculate the height of the water. The data will help with tasks like tracking regional shifts in sea level, monitoring changes in river flows and how much water lakes store, as well as determining how much freshwater is available to communities around the world.

 

“SWOT will address the ocean’s leading role in our changing weather and climate and the consequences on the availability of freshwater on land,” said Dr. Lee-Lueng Fu, SWOT project scientist at NASA’s Jet Propulsion Laboratory in Southern California.

 

The mission is a collaboration between NASA and the French space agency Centre National d’Etudes Spatiales, with contributions from the Canadian Space Agency and the United Kingdom Space Agency.

Quelle: NASA

 

 

826 Views
Raumfahrt+Astronomie-Blog von CENAP 0