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di dalam
bulan masih panas : pasang
surut Penghangat Ruangan dikedalaman mantel lunar
Para ilmuwan
telah menemukan bahwa ada lapisan sangat lembut dalam bulan dan panas secara
efektif dihasilkan dalam lapisan oleh gravitasi bumi. Temuan ini menunjukkan
bahwa interior bulan tidak didinginkan dan mengeras, dan juga bahwa itu masih
menjadi dipanaskan oleh efek bumi di bulan. Penelitian ini menyediakan
kesempatan untuk mempertimbangkan bagaimana bumi dan bulan telah berkembang
sejak kelahiran mereka melalui saling pengaruh sampai sekarang.............
Still hot inside the Moon: Tidal heating in the deepest part of the lunar
mantle
Date:
August 8,
2014
Source:
National Astronomical Observatory of
Japan
Summary:
Scientists have found that there is
an extremely soft layer deep inside the Moon and that heat is effectively
generated in the layer by the gravity of the Earth. These findings suggest that
the interior of the Moon has not yet cooled and hardened, and also that it is
still being warmed by the effect of the Earth on the Moon. This research provides
a chance to reconsider how both the Earth and the Moon have been evolving since
their births through mutual influence until now.
............................
An international research team, led by Dr. Yuji Harada from
Planetary Science institute, China University of Geosciences, has found that
there is an extremely soft layer deep inside the Moon and that heat is
effectively generated in the layer by the gravity of Earth.
The results
were derived by comparing the deformation of the Moon as precisely measured by
Kaguya (SELENE, Selenological and Engineering Explorer) and other probes with
theoretically calculated estimates. These findings suggest that the interior of
the Moon has not yet cooled and hardened, and also that it is still being
warmed by the effect of Earth on the Moon. This research provides a chance to
reconsider how both Earth and the Moon have been evolving since their births
through mutual influence until now.
When it
comes to clarifying how a celestial body like a planet or a natural satellite
is born and grows, it is necessary to know as precisely as possible its
internal structure and thermal state. How can we know the internal structure of
a celestial body far away from us? We can get clues about its internal
structure and state by thoroughly investigating how its shape changes due to
external forces. The shape of a celestial body being changes by the
gravitational force of another body is called tide. For example, the ocean tide
on Earth is one tidal phenomenon caused by the gravitational force between the
Moon and the Sun, and Earth. Sea water is so deformable that its desplacement
can be easily observed. How much a celestial body can be deformed by tidal
force, in this way, depends on its internal structure, and especially on the hardness
of its interior. Conversely, it means that observing the degree of deformation
enables us to learn about the interior, which is normally not directly visible
to the naked eye.
The Moon is
no exception; we can learn about the interior of our natural satellite from its
deformation caused by the tidal force of Earth. The deformation has already
been well known through several geodetic observations (*1). However, models of
the internal structure of the Moon as derived from past research could not
account for the deformation precisely observed by the above lunar exploration
programs.
Therefore,
the research team performed theoretical calculations to understand what type of
internal structure of the Moon leads to the observed change of the lunar shape.
What the
research team focused on is the structure deep inside the Moon. During the
Apollo program, seismic observations (*2) were carried out on the Moon. One of
the analysis results concerning the internal structure of the Moon based upon
the seismic data indicates that the satellite is considered to consist mainly
of two parts: the "core," the inner portion made up of metal, and the
"mantle," the outer portion made up of rock. The research team has
found that the observed tidal deformation of the Moon can be well explained if
it is assumed that there is an extremely soft layer in the deepest part of the
lunar mantle. The previous studies indicated that there is the possibility that
a part of the rock at the deepest part inside the lunar mantle may be molten. This
research result supports the above possibility since partially molten rock
becomes softer. This research has proven for the first time that the deepest
part of the lunar mantle is soft, based upon the agreement between observation
results and the theoretical calculations.
Furthermore,
the research team also clarified that heat is efficiently generated by the
tides in the soft part, deepest in the mantle. In general, a part of the energy
stored inside a celestial body by tidal deformation is changed to heat. The
heat generation depends on the softness of the interior. Interestingly, the
heat generated in the layer is expected to be nearly at the maximum when the
softness of the layer is comparable to that which the team estimated from the
above comparison of the calculations and the observations. This may not be a
coincidence. Rather, the layer itself is considered to be maintained as the
amount of the heat generated inside the soft layer is exquisitely well balanced
with that of the heat escaping from the layer. Whereas previous research also
suggests that some part of the energy inside the Moon due to the tidal
deformation is changed to heat, the present research indicates that this type
of energy conversion does not uniformly occur in the entire Moon, but only
intensively in the soft layer. The research team believes that the soft layer
is now warming the core of the Moon as the core seems to be wrapped by the
layer, which is located in the deepest part of the mantle, and which
efficiently generates heat. They also expect that a soft layer like this may
efficiently have warmed the core in the past as well.
Concerning
the future outlook for this research, Dr. Yuji Harada, the principle
investigator of the research team, said, "I believe that our research results
have brought about new questions. For example, how can the bottom of the lunar
mantle maintain its softer state for a long time? To answer this question, we
would like to further investigate the internal structure and heat-generating
mechanism inside the Moon in detail. In addition, another question has come up:
how has the conversion from the tidal energy to the heat energy in the soft
layer affected the motion of the Moon relative to the Earth, and also the
cooling of the Moon? We would like to resolve those problems as well so that we
can thoroughly understand how the Moon was born and has evolved."
Another
investigator, Prof. Junichi Haruyama of Institute of Space and Aeronautical
Science, Japan Aerospace Exploration Agency, mentioned the significance of this
research, saying, "A smaller celestial body like the Moon cools faster
than a larger one like the Earth does. In fact, we had thought that volcanic
activities on the Moon had already come to a halt. Therefore, the Moon had been
believed to be cool and hard, even in its deeper parts. However, this research
tells us that the Moon has not yet cooled and hardened, but is still warm. It
even implies that we have to reconsider the question as follows: How have the
Earth and the Moon influenced each other since their births? That means this
research not only shows us the actual state of the deep interior of the Moon,
but also gives us a clue for learning about the history of the system including
both the Earth and the Moon."
The
scientific paper on which this article is based appears in the Nature
Geoscience.
Strong tidal
heating in an ultralow-viscosity zone at the core-mantle boundary of the Moon.
Note:
*1: Geodetic
observation. (This is also called "selenodetic" observation as it is
for the Moon.)
Observational
results on gravity and rotation of the Moon are used in this research. Precise
measurements of the lunar gravity and rotation enable us to know how our
natural satellite is deformed by tidal forces.
The gravity
of the Moon can be measured by tracking the motion of a satellite orbiting the
Moon. This is because the motion of the satellite is influenced by lunar
gravity. The motion of the satellite orbiting the Moon can be determined by
using radio waves between the Earth and the satellite, and between multiple
satellites around the Moon. The gravity of the Moon changes when it deforms due
to tidal forces. The change in gravity caused by the lunar deformation due to
the tidal force is extremely small, but when the change in location of the
orbiter can be determined precisely enough, it is possible to accurately detect
the change in lunar gravity caused by the deformation due to the tidal force.
During the last several years, the degree of the lunar deformation caused by
the tidal forces has been determined by several orbiters, for example, Kaguya
from Japan, Chang'e-1 from China, and Lunar Reconnaissance Orbiter (LRO) and
Gravity Recovery and Interior Laboratory (GRAIL) from the USA.
The rotation
of the Moon can be observed by monitoring the change in position of a kind of
mirror placed in several locations on the lunar surface. The same side of the
Moon is almost always facing the Earth, but strictly speaking, it changes by a
slight amount according to the lunar orbit around the Earth. This means that
the locations of the mirrors with respect to the Earth also changes over time.
If this change in position is precisely measured, it can also be determined how
the direction of the lunar axis changes. This slight change of direction also
depends on the deformation caused by the tidal force. It can be seen,
therefore, how the Moon deforms due to the tidal force once the change in the
axis is measured precisely. Some of the above-mentioned mirrors have been left
on the surface of the Moon in the framework of the lunar exploration programs
led by the USA or the former USSR several decades ago, such as the Apollo
program. The degree of change in the location of each mirror on the Moon can be
determined by using laser beams emitted from the Earth. This experiment still
continues to be carried out even today.
*2: Seismic
observation. (Quakes on the Moon are also called "moonquakes." )
There are
seismic activities not only on the Earth, but also on the Moon. As part of the
Apollo program in the past, seismometers were placed on the lunar surface for
seismological measurements. Waves induced by quakes measured with seismometers
suggest what the internal structure of a celestial body is like. The behavior
of the seismic waves is very important for understanding how the hardness
inside the celestial body will change in accordance with the depth. In
particular, the present research considered the following two previous analysis
results in order to theoretically calculate the lunar deformation caused by the
tidal force.
The first
one is the existence of the area deep inside the Moon where the seismic waves
become drastically weaker. It is generally known that the energy of the seismic
waves tends to reduce more in softer solids, especially when they contain
liquids. Therefore, the deepest part of the lunar mantle is softer than the
shallower part. Also, a portion of the rocks is thought to be melted.
The second
one is the existence of areas deep inside the Moon whose interfaces reflect the
seismic waves. Three boundaries are considered to exist. Two of them are like
the ones in the Earth: one separating the solid inner core and the liquid outer
core, and the other one separating the outer core and the mantle. The last
boundary is considered to correspond to the one in the mantle separating the
solid area and the partially molten area mentioned above.
Story
Source:
The above
story is based on materials provided by National Astronomical Observatory of Japan. Note: Materials may be edited
for content and length.
Journal
Reference:
- Yuji Harada, Sander Goossens, Koji Matsumoto, Jianguo Yan, Jinsong Ping, Hirotomo Noda, Junichi Haruyama. Strong tidal heating in an ultralow-viscosity zone at the core–mantle boundary of the Moon. Nature Geoscience, 2014; 7 (8): 569 DOI: 10.1038/ngeo2211
