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The iridescent nacre inside a Nautilus shell.
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Nacre pronounced /ˈneɪkər/[1] or "NAY-kər", also known as mother of pearl, is an organic-inorganic composite material produced by some mollusks as an inner shell layer; it is also what makes up pearls. It is very strong, resilient, and iridescent.

Nacre is found in some ancient lineages of bivalve gastropod and cephalopod. The inner layer in the great majority of mollusk shells is porcellaneous, not nacreous, frequently resulting in a non-iridescent shine or less commonly in non-nacreous iridescence such as flame structure (e.g. conch pearl).

Pearls and the inside layer of pearl oyster and freshwater pearl mussel shells are made of nacre. Many other families of mollusk also have a nacreous inner shell layer, including marine gastropods such as the Haliotidae, the Trochidae and the Turbinidae.



Nacre appears iridescent because the thickness of the aragonite platelets is close to the wavelength of visible light. This results in constructive and destructive interference of different wavelengths of light, resulting in different colors of light being reflected at different viewing angles.


Nacre is composed of hexagonal platelets of aragonite (a form of calcium carbonate) 10-20 µm wide and 0.5 µm thick,[citation needed] arranged in a continuous parallel lamina.[citation needed] These layers are separated by sheets of organic matrix composed of elastic biopolymers (such as chitin, lustrin and silk-like proteins). This mixture of brittle platelets and the thin layers of elastic biopolymers makes the material strong and resilient, with a Young's modulus of 70 GPa. Strength and resilience are also likely to be due to adhesion by the "brickwork" arrangement of the platelets, which inhibits transverse crack propagation. This design at multiple length sizes increases its toughness enormously, making it almost equivalent to that of silicon.

The crystallographic c-axis points perpendicular to the shell wall, but the direction of the other axes varies between groups. In bivalves and cephalopods, the b-axis points in the direction of shell growth, whereas in the monoplacophora it is the a-axis that is this way inclined.[2]


Nacre formation is mediated by the organic matrix, which controls the onset, duration and form of crystal growth.[3] Individual aragonite "bricks" quickly grow to the full height of the nacreous layer, and expand until they abut adjacent bricks.[2] Bricks nucleate on randomly-dispersed elements within the organic layer.[4] This produces the hexagonal close-packing characteristic of nacre.[2] Nacre differs from fibrous aragonite – a brittle mineral of the same form – in that the growth in the c-axis (i.e. perpendicular to the shell, in nacre) is slow in nacre, and fast in fibrous aragonite.[5]


Nacre is secreted by the epithelial cells of the mantle tissue of various molluscs. The nacre is continuously deposited onto the inner surface of the shell, the iridescent nacreous layer, commonly known as mother of pearl. The layers of nacre smooth the shell surface and help defend the soft tissues against parasites and damaging debris by entombing them in successive layers of nacre, forming either a blister pearl attached to the interior of the shell, or a free pearl within the mantle tissues. The process is called is encystation and it continues as long as the mollusk lives.


See Mollusc shell#Evolution for discussion of the evolution & convergence of nacre in disparate groups of mollusc.

The form of nacre varies from group to group. In bivalves, the nacre layer is formed of single crystals in a hexagonal close packing. In gastropods, crystals are twinned, and in cephalopods, they are pseudohexagonal monocrystals, which are often twinned.[2]

Commercial sources

Chief sources of mother of pearl are the pearl oyster, freshwater pearl mussels, and abalone. Also widely used for pearl buttons, especially during the 1900s, is the shell of the great green turban snail Turbo marmoratus.

Decorative uses

Nacre has been used over many centuries for all kinds of decorative purposes:



Both black and white nacre are used for architectural purposes. The natural nacre may be artificially tinted to almost any color. Nacre tesserae may be cut into shapes and laminated to a ceramic tile or marble base. The tesserae are hand-placed and closely sandwiched together, creating an irregular mosaic or pattern (such as a weave). The laminated material is typically about 2 mm thick. The tesserae are then lacquered and polished creating a durable and glossy surface.

Instead of using a marble or tile base, the nacre tesserae can be glued to fiberglass. The result is a lightweight material that offers a seamless installation and there is no limit to the sheet size. Nacre sheets may be used on interior floors, exterior and interior walls, countertops, doors and ceilings. Insertion into architectural elements, such as columns or furniture is easily accomplished.


Nacre pearl buttons are often used in clothing either for functional or decorative purposes. The Pearly Kings and Queens are an elaborate example of this.

Nacre is also used to decorate watches, knives, guns and jewelry.


Nacre inlay is often used for key touches and other decorative motifs on musical instruments. Many accordion and concertina bodies are completely covered in nacre, and some electric guitars use mother of pearl for neck dot inlays. Mother of pearl is used to make spoon like utensils for eating caviar, so as to not spoil the taste with metallic spoons.

See also


  1. ^ Definition of nacre at]
  2. ^ a b c d Checa, A.; Ramírez-Rico, J.; González-Segura, A.; Sánchez-Navas, A. (2009). "Nacre and false nacre (foliated aragonite) in extant monoplacophorans (=Tryblidiida: Mollusca)". Die Naturwissenschaften 96 (1): 111–122. doi:10.1007/s00114-008-0461-1. PMID 18843476.  edit
  3. ^ Jackson, D.; McDougall, C.; Woodcroft, B.; Moase, P.; Rose, R.; Kube, M.; Reinhardt, R.; Rokhsar, D. et al. (2010). "Parallel evolution of nacre building gene sets in molluscs". Molecular biology and evolution 27 (3): 591–608. doi:10.1093/molbev/msp278. PMID 19915030.  edit
  4. ^ Metzler, R.; Abrecht, M.; Olabisi, R.; Ariosa, D.; Johnson, C.; Frazer, B.; Coppersmith, S.; Gilbert, P. (2007). "Architecture of Columnar Nacre, and Implications for Its Formation Mechanism". Physical Review Letters 98: 268102. doi:10.1103/PhysRevLett.98.268102.  edit
  5. ^ Bruce Runnegar & S Bengtson. "1.4 Origin of Hard Parts — Early Skeletal Fossils".,%20Section%201.pdf. 



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