Nepheline Explained

Nepheline
Category:Tectosilicate, feldspathoid
Formula:(Na,K)AlSiO4
Imasymbol:Nph[1]
Molweight:146.08 g/mol
Strunz:9.FA.05
System:Hexagonal
Class:Pyramidal (6)
H–M symbol: (6)
Symmetry:P63
Color:White, gray, brown, brownish gray, or reddish white
Habit:Massive granular to prismatic
Twinning:On [1010], [3365], and [1122]
Cleavage:[1010] Poor
Fracture:Subconchoidal
Mohs:6
Luster:Vitreous to greasy
Refractive:nω = 1.529–1.546
nε = 1.526–1.542
Opticalprop:Uniaxial (−)
Birefringence:δ = 0.003–0.004
Streak:White
Gravity:2.55–2.65 (average: 2.59)
Other:non-radioactive, non-magnetic, non-fluorescent
References:[2] [3]

Nepheline, also called nephelite, is a rock-forming mineral in the feldspathoid groupa silica-undersaturated aluminosilicate, Na3KAl4Si4O16, that occurs in intrusive and volcanic rocks with low silica, and in their associated pegmatites. It is used in glass and ceramic manufacturing and other industries, and has been investigated as an ore of aluminium.

Description and properties

Nepheline crystals are rare and belong to the hexagonal system, usually having the form of a short, six-sided prism terminated by the basal plane.[4] The crystals appear to have more symmetry than they actually possess,[5] but unsymmetrical etched figures produced artificially on the prism faces indicate that the crystals are hemimorphic and tetartohedral, the only element of symmetry being a polar hexad axis.[6] Nepheline is found in compact, granular aggregates, and can be white, yellow, gray, green, or reddish. Its hardness on the Mohs scale is 5.5 to 6, and its specific gravity 2.60–2.65. It is often translucent with a greasy luster.[4]

The low index of refraction and the feeble double refraction in nepheline are nearly the same as in quartz; but since the sign of the double refraction is negative in nepheline, while it is positive in quartz, the two minerals are readily distinguished under the microscope.[4] An important determinative character of nepheline is the ease with which it is decomposed by hydrochloric acid, with separation of gelatinous silica (which may be readily stained by coloring matters) and cubes of salt.[7] For this reason, a clear crystal of nepheline becomes cloudy when immersed in acid.[4]

The mineral is prone to alteration to zeolites (especially natrolite), sodalite, kaolin, or compact muscovite.[7]

Structure and composition

The aluminosilicate backbone of nepheline has a fairly open structure of interlocked six-member rings. This resembles the structure of tridymite, with aluminum substituting for every other silicon atom. This structure produces one nearly hexagonal interstitial site and three irregular interstitial sites per unit cell. In ideal nepheline, the hexagonal sites are occupied by potassium ions and the irregular sites by smaller sodium ions, yielding an atomic ratio of sodium to potassium of 3:1. This corresponds to an ideal weight percentage of K2O of 8.1% The range of compositions seen in natural nepheline is 3% to 12% K2O. Small amounts of calcium may be present as well.

At elevated temperature, nepheline forms a complete solid solution series with kalsilite, KAlSiO4. At temperatures below about 1000C, there is a wide miscibility gap between nepheline and kalsilite, similar to the miscibility gap between microcline and albite. A composition falling in this gap will experience exsolution as it cools, where nepheline and kalsilite separate into separate microscopic layers (lamellae).[4]

Occurrence

Nephelinite is a rock-forming mineral found in silica-poor igneous rocks. These include nepheline syenite, foidite, and phonolite. It is often found along with leucite, sodalite, potassium feldspars, and sodium-rich plagioclase, amphiboles, or pyroxenes, but almost never in association with quartz. Notable outcrops of nepheline-bearing rocks are found on the Kola Peninsula; in Norway and South Africa; and at Litchfield, Maine; Magnet Cove, Arkansas; and Beemerville, New Jersey, in the United States. Syenites found near Bancroft, Ontario contain large deposits of high-purity nepheline.

Elaeolite (a name given by M. H. Klaproth 1809, from Greek words for oil [ἔλαιον] and stone [λίθος]; German: Fettstein)[7] is a massive form of translucent nepheline with a darker color and greasy luster.[8]

Uses

Because of its high alumina content, iron-free nepheline is valued for use in glass manufacturing in place of feldspar. Most of the nepheline used for this purpose comes from Ontario. Nepheline produced as a byproduct of apatite mining in the Kola Peninsula has found uses in ceramics, leather, rubber, textiles, wood, and the oil industry. It can be used as a filler in paints, plastics, foam rubber, and sorbent.[9] Nepheline of Kiya Shaltyr deposit (Kemerovo Region, Russia) is also used as a raw material for aluminium manufacturing.[10]

Notes and References

  1. Warr. L.N.. 2021. IMA–CNMNC approved mineral symbols. Mineralogical Magazine. 85. 3. 291–320. 10.1180/mgm.2021.43. 2021MinM...85..291W. 235729616. free.
  2. Web site: Anthony . John W. . Bideaux . Richard A. . Bladh . Kenneth W. . Nichols . Monte C. . Nepheline . Handbook of Mineralogy . Mineral Data Publishing . 13 August 2022 . 2005.
  3. Web site: Barthelmy. David. 2014. Nepheline Mineral Data. 13 August 2022. Webmineral.com.
  4. Book: Klein . Cornelis . Hurlbut . Cornelius S. Jr. . Manual of Mineralogy (after James D. Dana) . 1993 . Wiley . New York . 047157452X . 546–547 . 21st.
  5. Book: Nesse . William D. . Introduction to mineralogy . 2000 . Oxford University Press . New York . 9780195106916 . 35.
  6. Book: Borchardt-Ott . Walter . Crystallography . 1995 . Springer . Berlin . 3540594787 . 159 . 2nd.
  7. Nepheline . 19 . 383 . Spencer . Leonard James.
  8. Book: 2009 . 298 . 10.1007/978-3-540-72816-0_7337. 978-3-540-72795-8 . Eleolite . Dictionary of Gems and Gemology .
  9. Zosin . A. P. . Priimak . T. I. . Koshkina . L. B. . Masloboev . V. A. . 2005 . Sorption-Active Materials Based on an Acid-Nonresistant Aluminosilicate Nepheline, Used for Defluorination of Industrial Sewage . . en . 78 . 7 . 1077–1083 . 10.1007/s11167-005-0453-2 . 91524499 . 1070-4272.
  10. Book: Government report on the state and use of mineral and raw resources of the Russian Federation in 2019 . Ministry of natural resources and environment of the Russian Federation . 2020 . Kiselev . E.A. . Moscow . 139–145 . RU . 2023-04-05 . 2021-09-24 . https://web.archive.org/web/20210924131359/https://www.mnr.gov.ru/docs/o_sostoyanii_i_ispolzovanii_mineralno_syrevykh_resursov_rossiyskoy_federatsii/gosudarstvennyy_doklad_o_sostyanii_i_ispolzovanii_mineralno_syrevykh_resursov_rossiyskoy_federatsii/ . dead .