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Baddeleyite(ZrO2) is a rare mineral found in igneous rocks containing potassium feldspar and plagioclase. It has been reported to be a great Geochronometer . It is commonly found with Zircon (ZrSiO4), yet it forms in places with lower silica content, such as mafic rocks. This is because Baddeleyite tends to become Zircon where there is higher silica content, hence why both minerals can be found together. It belongs to the monoclinic-prismatic class, of the P21/c crystal system.

Composition
Baddeleyite belongs to the Oxide group, having a composition of ZrO2. Similar minerals belonging to the same group are the Rutile Group: Rutile (TiO2), Pyrolusite (MnO2), Cassiterite (SnO2), Uranite (UO2) and Thorianite (ThO2).Baddeleyite is chemically homogeneous, but it may contain impurities such as TiO2, HfO2, and FeO2 . Higher concentrations of TiO2 and FeO2 are restricted to mafic-ultramafic rocks.

Structure
There has been some dispute in the structure of Baddeleyite. Originally, the mineral was assigned to the 8-fold coordination by Naray Szabo. This structure was ruled out due to the inaccuracy of the data used to establish it.

Baddeleyite has the group symmetry P21/c with four ZrO2 in the unit cell. Baddeleyite has unit cell dimensions of: a = 5•169 b = 5•232  c = 5•341  Å  ( all ± 0•008 Å ) β =  99˚ 15ˊ±ˊ10.

The coordination number for ZrO2¬ has been found to be 7. The mineral has two types of separations. The first being the seven shortest Zr-O, ranging from 2•04 to 2•26 Å, and the second Zr-O separation is 3•77 Å. Because of this, the coordination of Baddeleyite was determined to be sevenfold. Baddeleyite’s structure is a combination of tetrahedrally coordinated oxide ions parallel to (100) with triangular coordinated oxide ions. This explains Baddeleyite’s tendency to twin along (100). It has been observed that Baddeleyite without twinning is extremely rare.

Physical Properties
Baddeleyite is black in color with a submetallic lustre. It has a 6.5 harness, and a brownish-white streak. Baddeleyite does not only come in a black color, it can also be brown, brownish black, green, and greenish brown. Its streak is white, or brownish white. It has a distinct cleavage along {001}, and it tends to twin along (100). It belongs to the monoclinic system, and it is part of the P21/c group.

Geologic Occurrence
Baddeleyite was first found in Sri Lanka, in 1892, yet this is not its only occurrence. Baddeleyite has been found in numerous terrestrial and lunar rocks. Some of these terrestrial rocks are carbonites, kimberlites, alkaline syenites, some rocks of layered mafic intrusions, diabase dikes,  gabbroid  sills,  anorthosites. Studies have shown that zircon and baddeleyite can be recovered from some anorthositic rocks in Proterozoic anorthosite complexes. . Places where these Proterozoic anorthosite complexes can be found are: the Laramie anorthosite complex in Wyoming, the Nain and Greenville provinces of Canada, the Vico Volcanic Complex in Italy, among others. . Baddeleyite forms in igneous rocks low in silica, it can be found in rocks containing potassium feldspar and plagioclase. It has been observed that Baddeleyite forms within thin sections of plagioclase grains.

Origin of the Name
Not much is known about Joseph Baddeley, the man who Baddeleyite is named after. The mineral was discovered in Rakwana, Ceylon, now known as Sri Lanka. Baddeley was a superintendent of a rail road project in Rakwana, and he was known for collecting every different pebble he could find while working. As redacted by J. J. H. Teall, Director of the British Geological Survey in the early 1900’s, Baddeleyite was discovered thanks to the discovery of Geikielite. Baddeley happened to send specimens of several pebbles to the Museum of Practical Geology in London, where Mr. Pringle examined them and attempted to classify them. According to Teall, the specimens were submitted to him by Pringle after he failed to assign them and compare them to other species, such as spinel, ilmenite, and so on. After analyzing the specimens, Teall concluded that the mineral was mainly composed of Titanic acid and Magnesia, with a very small percentage of Protoxide of Iron. Geikielite has the composition of MgTiO3. Concluding the various analyses, Teall and Pringle decided to name the new mineral Geikielite, taking the name after the Director General of the Geological Survey, Sir Archibald Geikie. Baddeley then decided to send more specimens to Teall in order to determine a proper specimen to be put in display at the Museum of Practical Geology. While trying to find the best specimen for display, as Teall relates, he noticed that one of the specimens was different from the rest. This new mineral as described was black in color, with a submetallic lustre and a hardness of 6.5. After analyzing the mineral, it was determined that its composition was not MgTiO3, as Geikielite’s, but it was ZrO2. Teall proposed that the new mineral should be named Baddeleyite, after Joseph Baddeley in order to honor the man who brought two new minerals to notice.