Reidite

Where it forms, where it's found

Geological setting: In upper Eocene impact ejecta layer, probably from the Chesapeake Bay impact structure.
Type locality: Deep Sea Drilling Project Site 612
Upper continental slope of New Jersey
Atlantic Ocean
38.8167°, -72.7833°

20recorded occurrences

Source · OpenStreetMap

Physical

Hardness: 1Talc
2Gypsum
3Calcite
4Fluorite
5Apatite
6Orthoclase
7Quartz
8Topaz
9Corundum
10Diamond
Colour: Colourless
Streak: white
Tenacity: brittle
Cleavage: None Observed
Fracture: Irregular/Uneven
Density: 5.2 g/cm³

Optical

Optical type: Uniaxial
Birefringence: 0.015
Pleochroism: Non-pleochroic

Michel-Lévy diagramhighlighted lineδ = 0.0150

Attainable Michel-Lévy rangeΔ ∈ [0, t·δ_max]150 nm1st order

Δ = 0Δ_max

Section thickness10 μmStage rotation0°

Thin-section mosaic70 grains · random 3D orientations

PPL

pleochroism per grain

XPL

independent extinctions · rotate the stage

Interference simulatorsingle grain · PPL ↔ XPL

PPL

pleochroism only · colour blends on rotation

XPL

interference colour · extinct every 90°

Retardation150 nm

Order1st order

XPL colour

Crystallography

Crystal system: Tetragonal
Space group: #136
Cell parameters: a = 4.738 Å · c = 10.506 Å
Unit cell volume: 235.84 Å³
Z: 4
Morphology: skeletal crystals up to 10 µm in length and 0.3 µm in width; also lamellar intergrowths in host zircon crystals.
Type-locality form: skeletal crystals replacing zircon. The crystals are up to 10 µm in length and 0.3 µm in width.

Chemical composition

Constituent elements: Mass composition breakdown
Element Atoms At. mass g/mol Mass g/mol Mass share
40ZrZirconium Zirconium 1 91.224 91.224
49.77%
8OOxygen Oxygen 4 15.999 63.996
34.91%
14SiSilicon Silicon 1 28.085 28.085
15.32%
Total 183.305 100.00%
Mass share = atoms × atomic mass ÷ molar mass × 100
From IMA formula

Mass composition breakdown
Element	Atoms	At. mass g/mol	Mass g/mol	Mass share
40ZrZirconium	Zirconium	1	91.224	91.224	49.77%
8OOxygen	Oxygen	4	15.999	63.996	34.91%
14SiSilicon	Silicon	1	28.085	28.085	15.32%
	Total	183.305	100.00%

Synonyms

IMA2001-013
Reidiet

In other languages

German: IMA 2001-013 · Reidit
Italian: Reidite
Portuguese: Reidite

Classification

Strunz

10th ed.

9.AD.45

9SilicatesClass
9.ANesosilicatesDivision
9.ADNesosilicates without additional anions; cations in [6] and/or greater coordinationGroup
9.AD.45ReiditeSpecies

Group, growth & confusion

5 members

1 mineral

ZirconZr(SiO₄)
Mineral
—

Literature, links & citation

Citations

1969Reid, A.F., Ringwood, A.E. (1969) Newly observed high pressure transformations in Mn3O4, CaAl2O4, and ZrSiO4. Earth and Planetary Science Letters, 6 (3) 205-208 doi:10.1016/0012-821x(69)90091-0DOI: 10.1016/0012-821x(69)90091-0
2002Glass, Billy P., Liu, Shaobin, Leavens, Peter B. (2002) Reidite: An impact-produced high-pressure polymorph of zircon found in marine sediments. American Mineralogist, 87 (4) 562-565 doi:10.2138/am-2002-0420DOI: 10.2138/am-2002-0420
2003Mandarino, Joseph A. (2003) New minerals. The Canadian Mineralogist, 41 (3) 803-828 doi:10.2113/gscanmin.41.3.803 DOI: 10.2113/gscanmin.41.3.803
2004Gucsik, A., Zhang, M., Koeberl, C., Salje, E. K. H., Redfern, S. A. T., Pruneda, J. M. (2004) Infrared and Raman spectra of ZrSiO₄ experimentally shocked at high pressures. Mineralogical Magazine, 68 (5) 801-811 doi:10.1180/0026461046850220DOI: 10.1180/0026461046850220
2008GLASS, Billy P., FRIES, Marc (2008) Micro-Raman spectroscopic study of fine-grained, shock-metamorphosed rock fragments from the Australasian microtektite layer. Meteoritics & Planetary Science, 43 (9) 1487-1496 doi:10.1111/j.1945-5100.2008.tb01023.xDOI: 10.1111/j.1945-5100.2008.tb01023.x

Cite this entry

@misc{mineral2026,
  author    = {Mineral Index editorial board},
  title     = {Reidite — Mineral Index},
  year      = {2026},
  url       = {https://mineralindex.org/minerals/reidite-11467},
  note      = {Accessed 2026-05-11}
}