https://smap.jpl.nasa.gov/
An orbiting observatory that measures the amount of water in the top 5 cm (2 inches) of soil everywhere on Earth’s surface will soon be placed in a polar orbit around Earth. It is called SMAP. This is an acronym made from the name of the satellite. SMAP stands for Soil Moisture Active Passive
The topsoil layer is the one in which the food we eat grows and where other vegetation lives. Moisture in the soil indirectly affects us in a variety of ways. In the course of its observations, SMAP will also determine if the ground is frozen or thawed in colder areas of the world.
SMAP is designed to measure soil moisture over a three-year period, every 2-3 days. This permits changes, around the world, to be observed over time scales ranging from major storms to repeated measurements of changes over the seasons.
Everywhere on Earth not covered with water or not frozen, SMAP measures how much water is in the top layer of soil. It also distinguishes between ground that is frozen or thawed. Where the ground is not frozen, SMAP measures the amount of water found between the minerals, rocky material, and organic particles found in soil everywhere in the world (SMAP measures liquid water in the top layer of ground but is not able to measure the ice.)
SMAP will produce global maps of soil moisture. Scientists will use these to help improve our understanding of how water and carbon (in its various forms) circulate. The water cycle involves more than the obvious processes cycling through the steps of evaporation from the oceans and land to condensation forming clouds that then drop rain or snow on the ground (precipitation), followed by the water flowing across the land before returning to the sea. For example, plants absorb water from the soil to grow, but they also “transpire” some of it straight back into the air.
The carbon cycle has more branches than the water cycle. It refers to the transfer of carbon between and among Earth’s atmosphere (air), pedosphere (soil), lithosphere (rock), hydrosphere (surface water: ocean, lakes, and rivers), and the cryosphere (all forms and places where ice is found on Earth including sea ice, snow, glaciers, and permafrost). For example, carbon (in the form carbon dioxide) is found in the air, dissolved in water, and emitted from underground sources as well everything that breathes. Carbonate minerals are found on the sea floor and in mountains, as well as the famous White Cliffs of Dover. Petroleum and coal are carbon that is trapped underground until it is pumped up or mined. All of these forms of carbon can cycle in various ways among the ‘spheres.
Weather and climate studies will use SMAP data as well. The amount of water that evaporates from the land surface into the atmosphere depends on the soil moisture. Soil moisture information is key to understanding the flows of water and heat energy between the surface and atmosphere that impact weather and climate. Currently, we know little about soil moisture variability at either regional or global scales. Frequent and reliable soil moisture measurements from SMAP will help improve the predictive capability of weather and climate models.
Learn about soil and how different kinds of soil hold moisture. See how NASA plans to use measurements from the SMAP mission to make our world a better place to live.
What is the connection between water, soil, and carbon cycles? The answer may be in the soil beneath your feet. See how NASA plans to measure soil moisture from space with the SMAP mission. Learn to calculate soil moisture in your own backyard and discover the real-world applications for this data
Learn how SMAP will use new technologies to help answer questions raised in the National Research Councils' Decadal Survey. See what kind of modeling and forecasting applications the data from this mission will provide as it measures the soil moisture that cools Earth's surface and provides water to the atmosphere and plants.
An orbiting observatory that measures the amount of water in the top 5 cm (2 inches) of soil everywhere on Earth’s surface will soon be placed in a polar orbit around Earth. It is called SMAP. This is an acronym made from the name of the satellite. SMAP stands for Soil Moisture Active Passive
The topsoil layer is the one in which the food we eat grows and where other vegetation lives. Moisture in the soil indirectly affects us in a variety of ways. In the course of its observations, SMAP will also determine if the ground is frozen or thawed in colder areas of the world.
SMAP is designed to measure soil moisture over a three-year period, every 2-3 days. This permits changes, around the world, to be observed over time scales ranging from major storms to repeated measurements of changes over the seasons.
Everywhere on Earth not covered with water or not frozen, SMAP measures how much water is in the top layer of soil. It also distinguishes between ground that is frozen or thawed. Where the ground is not frozen, SMAP measures the amount of water found between the minerals, rocky material, and organic particles found in soil everywhere in the world (SMAP measures liquid water in the top layer of ground but is not able to measure the ice.)
SMAP will produce global maps of soil moisture. Scientists will use these to help improve our understanding of how water and carbon (in its various forms) circulate. The water cycle involves more than the obvious processes cycling through the steps of evaporation from the oceans and land to condensation forming clouds that then drop rain or snow on the ground (precipitation), followed by the water flowing across the land before returning to the sea. For example, plants absorb water from the soil to grow, but they also “transpire” some of it straight back into the air.
The carbon cycle has more branches than the water cycle. It refers to the transfer of carbon between and among Earth’s atmosphere (air), pedosphere (soil), lithosphere (rock), hydrosphere (surface water: ocean, lakes, and rivers), and the cryosphere (all forms and places where ice is found on Earth including sea ice, snow, glaciers, and permafrost). For example, carbon (in the form carbon dioxide) is found in the air, dissolved in water, and emitted from underground sources as well everything that breathes. Carbonate minerals are found on the sea floor and in mountains, as well as the famous White Cliffs of Dover. Petroleum and coal are carbon that is trapped underground until it is pumped up or mined. All of these forms of carbon can cycle in various ways among the ‘spheres.
Weather and climate studies will use SMAP data as well. The amount of water that evaporates from the land surface into the atmosphere depends on the soil moisture. Soil moisture information is key to understanding the flows of water and heat energy between the surface and atmosphere that impact weather and climate. Currently, we know little about soil moisture variability at either regional or global scales. Frequent and reliable soil moisture measurements from SMAP will help improve the predictive capability of weather and climate models.
Learn about soil and how different kinds of soil hold moisture. See how NASA plans to use measurements from the SMAP mission to make our world a better place to live.
What is the connection between water, soil, and carbon cycles? The answer may be in the soil beneath your feet. See how NASA plans to measure soil moisture from space with the SMAP mission. Learn to calculate soil moisture in your own backyard and discover the real-world applications for this data
Learn how SMAP will use new technologies to help answer questions raised in the National Research Councils' Decadal Survey. See what kind of modeling and forecasting applications the data from this mission will provide as it measures the soil moisture that cools Earth's surface and provides water to the atmosphere and plants.
No comments:
Post a Comment