Rob Gutro March 6, 2003
Goddard Space Flight Center, Greenbelt, Md.
(Phone: 301-286-4044)
RELEASE: 03-21
CHANGES IN THE EARTH'S ROTATION ARE IN THE WIND
Because of Earth's dynamic climate, winds and atmospheric
pressure systems experience constant change. These fluctuations may
affect how our planet rotates on its axis, according to NASA-funded
research that used wind and satellite data.
NASA's Earth Science Enterprise (ESE) mission is to understand the
Earth system and its response to natural and human-induced changes for
better prediction of climate, weather and natural hazards, such as
atmospheric changes or El Niņo events that may have contributed to the
affect on Earth's rotation.
"Changes in the atmosphere, specifically atmospheric pressure around
the world, and the motions of the winds that may be related to such
climate signals as El Niņo are strong enough that their effect is
observed in the Earth's rotation signal," said David A. Salstein, an
atmospheric scientist from Atmospheric and Environmental Research,
Inc., of Lexington, Mass.who led a recent study.
>From year to year, winds and air pressure patterns change, causing
different forces to act on the solid Earth. During El Niņo years, for
example, the rotation of the Earth may slow ever so slightly because of
stronger winds, increasing the length of a day by a fraction of a
millisecond (thousandth of a second).
Issac Newton's laws of motion explain how those quantities are related
to the Earth's rotation rate (leading to a change in the length of day)
as well as the exact position in which the North Pole points in the
heavens (known also as polar motion, or Earth wobble).
To understand the concept of angular momentum, visualize the Earth
spinning in space. Given Earth's overall mass and its rotation, it
contains a certain amount of angular momentum. When an additional force
acting at a distance from the Earth's rotational axis occurs, referred
to as a torque, such as changes in surface winds, or the distribution
of high and low pressure patterns, especially near mountains, it can
act to change the rate of the Earth's rotation or even the direction of
the rotational axis.
Because of the law of "conservation of angular momentum," small but
detectable changes in the Earth's rotation and those in the rotation of
the atmosphere are linked. The conservation of angular momentum is a
law of physics that states the total angular momentum of a rotating
object with no outside force remains constant regardless of changes
within the system.
An example of this principle occurs when a skater pulls his or her arms
inward during a spin (changing the mass distribution to one nearer the
rotation axis, reducing the "moment of inertia," and speeds up
(increasing the skater's spin); because the moment of inertia goes
down, the spin rate must increase to keep the total angular momentum of
the system unchanged.
"The key is that the sum of the angular momentum (push) of the solid
Earth plus atmosphere system must stay constant unless an outside force
(torque) is applied," Salstein said. "So if the atmosphere speeds up
(stronger westerly winds) then the solid Earth must slow down
(length-of-day increases).Also if more atmosphere moves to a lower
latitude (further from the axis of rotation), and atmospheric pressure
increases, it also gains angular momentum and the Earth would slow down
as well."
Other motions of the atmosphere such as larger mass in one hemisphere
than the other can lead to a wobble (like a washing machine with
clothes off-balance) and the poles move, in accordance to the law of
the conservation of angular momentum.
Salstein looked at wind and pressure measurements from a National
Weather Service analysis that makes use of a combination of
ground-based, aircraft, and space-based observations.The measurements
for the Earth's motions come from a variety of space-based measurements
including satellites, like those in the Global Positioning System
(GPS), the geodetic satellites that included records from NASA's older
LAGEOS satellite, and observations of distant astronomical objects
using a technique known as Very Long Baseline Interferometry.
Understanding the atmospheric pressure patterns, moreover, is essential
to interpret results from NASA's Gravity Recovery and Climate
Experiment (GRACE).
The fact that the two vastly different systems, namely the
meteorological and the astronomical, are in good agreement according to
the conservation of angular momentum gives us assurance that both these
types of measurements must be accurate. It shows, moreover, that
changes in climate signals can have global implications on Earth's
overall rotation.
NASA's ESE research focuses on the changes and variability in the Earth
system, including atmospheric, oceanic, and geodetic areas. This
research was recently presented at the annual meeting of the American
Meteorological Society in Long Beach, Calif.
For more information and images, see:
0000,0000,FFFFhttp://www.gsfc.nasa.gov/topstory/2003/0210rotation.html
Special Bureau for the Atmosphere of the
International Earth Rotation Service (IERS), at Atmospheric and
Environmental Research, Inc.
0000,0000,FFFFhttp://www.aer.com/groups/diag/sb.html
The LAGEOS 1 & 2 Satellites:
0000,0000,FFFFhttp://msl.jpl.nasa.gov/QuickLooks/lageosQL.html
Gravity Recovery and Climate Experiment
(GRACE) satellite:
0000,0000,FFFFhttp://www.csr.utexas.edu/grace/
NASA's Earth Science Enterprise:
0000,0000,FFFFhttp://earth.nasa.gov
-end-0000,0000,FFFF
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