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| Images captured from the Jodrell Plank Observatory using the 127 mm. Meade Apo Refractor and the Seestar S30. Data and image credit: Pip Stakkert. |
"The other evening, our imaging technician Pip was using the Seestar S30 to photograph the waxing gibbous lunar disc. He noticed that the 'Terminator' or 'daybreak on the Moon' was about to cross the prominent feature Sinus Iridum - The Bay of Rainbows. Sunlight had just touched the peaks of the crater walls creating the effect known as the 'golden handle'. This can just be seen top left in the bottom image". - Joel Cairo CEO of the Jodrell Plank Observatory.
Key features of Sinus Iridum - Lunar notes - from Professor G.P.T Chat visiting astrophysicist at the JPO.
Sinus Iridum
(Latin for "Bay of Rainbows") is one of the most striking
basalt-flooded impact structures on the near side of the Moon. It forms a broad
semicircular embayment on the northwestern margin of Mare Imbrium and is
enclosed by the rugged arc of the Montes Jura mountain range. To lunar
observers it appears as a near-perfect luminous crescent when illuminated at
low solar angles, making it one of the most recognizable features on the lunar
disc.
Position on the Lunar Disc
Sinus Iridum
lies at approximately 44°N latitude and 31°W longitude on the Moon's near side.
Because it occupies the northwestern sector of Mare Imbrium, it appears in the
Moon's upper-left quadrant as viewed through most astronomical telescopes that
present an upright image. The feature is roughly 240–260 km in diameter and
opens southeastward into Mare Imbrium. The enclosing Jura Mountains are
remnants of the original crater rim, rising locally several kilometres above
the mare floor.
Origin as a Large Impact Basin
Sinus Iridum
began as a major impact crater formed during the late stages of the heavy
bombardment that shaped much of the lunar crust. The impact excavated a large
bowl-shaped basin and produced an elevated rim composed largely of anorthositic
highland material. The southeastern portion of the rim was later breached and
largely buried when extensive volcanic flooding associated with Mare Imbrium
spread into the crater.
The result
is not a true bay in the terrestrial sense, but rather the flooded remains of a
large impact structure whose interior became connected to the surrounding mare
plains. The surviving rim forms the dramatic semicircular wall visible today.
Geological Composition
The floor of
Sinus Iridum consists predominantly of mare basalts emplaced during multiple
volcanic episodes. Remote-sensing studies using data from the Clementine
mission, Chandrayaan-1, the Lunar Reconnaissance Orbiter, and China's Chang'E
program show that these lavas vary in composition and age across the basin.
Key
geological characteristics include:
- Basaltic mare plains rich in pyroxene-bearing
volcanic rocks.
- Progression from low-titanium
basalts in older lava units to medium-titanium basalts in
younger units.
- Evidence for increasing olivine
abundance in some younger volcanic materials.
- Wrinkle ridges, tectonic
deformation features caused by contraction of cooling lava plains.
- Small impact craters, crater
chains, and rilles recording later geological modification.
The
surrounding Montes Jura remain compositionally distinct from the mare floor,
consisting mainly of feldspathic highland crust excavated during the original
impact event.
Age and Volcanic History
Modern
crater-count dating reveals that Sinus Iridum experienced a prolonged history
of volcanic resurfacing rather than a single flooding event.
The oldest
exposed mare units have model ages of approximately 3.37 billion years,
corresponding to the Imbrian period. Younger lava flows continued entering the
basin from Mare Imbrium for more than two billion years afterward. Some of the
youngest recognized basaltic units have ages near 1.24 billion years,
making them among the youngest extensive mare volcanics on the Moon.
The sequence
is interpreted as repeated episodes of lava entering the partially enclosed
basin from the larger Imbrium volcanic province. Rather than being filled from
a single central vent, Sinus Iridum appears to have been resurfaced multiple
times by flows arriving from adjacent mare regions.
Tectonic Evolution
Following
emplacement of the mare basalts, the region underwent tectonic deformation
associated with cooling and subsidence of the volcanic plains.
Researchers
using data from the Japanese SELENE (Kaguya) mission and NASA's Lunar Reconnaissance
Orbiter identified wrinkle ridges and compressional structures whose formation
may have continued into relatively recent lunar history. These structures
reflect crustal shortening caused by the weight and contraction of the basaltic
fill.
Spacecraft Investigations
Several
lunar missions have studied Sinus Iridum in detail.
NASA Missions
- The Lunar Reconnaissance
Orbiter has provided high-resolution imagery, topographic measurements
from LOLA, and compositional information used in modern geological
mapping.
- Earlier missions including Clementine
supplied multispectral data that helped determine iron and titanium
abundances.
Japanese Investigations
- SELENE obtained detailed terrain and
imaging data used to investigate tectonic structures and wrinkle ridges
throughout northwestern Mare Imbrium and Sinus Iridum.
Chinese Investigations
- Chang'e 2 produced high-resolution
imagery used in detailed geological mapping and age determinations.
- Sinus Iridum was seriously
evaluated as a candidate landing area for later Chinese robotic and
sample-return missions because of its smooth terrain and geological
diversity.
Although no
spacecraft has yet landed within Sinus Iridum itself, it remains scientifically
attractive because it exposes the interaction between impact-basin formation,
mare volcanism, and tectonic deformation in a single locality.
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| Captured from the JPO and previously published on the blog |
