Wood's metal

Wood's metal, also known as Lipowitz's alloy or by the commercial names Cerrobend, Bendalloy, Pewtalloy and MCP 158, is a metal alloy that is useful for soldering and making custom metal parts, but its fumes are toxic, as well as being toxic on skin exposure. The alloy is named for Barnabas Wood, who invented and patented the alloy in 1860.^[1]^[2] It is a eutectic, fusible alloy of 50% bismuth, 26.7% lead, 13.3% tin, and 10% cadmium by mass. It has a melting point of approximately 70 °C (158 °F).^[3]^[4]

Applications

Other uses include making custom-shaped apertures and blocks (for example, electron-beam cutouts and lung blocks) for medical radiation treatment, and making casts of keys that are hard to otherwise duplicate.^[5]^[6]

Like other fusible alloys, e.g. Rose's metal, Wood's metal can be used as a heat-transfer medium in hot baths. Hot baths with Rose's and Wood's metals are not used routinely but are employed at temperatures above 220 °C (428 °F).^[7]

At room temperature, Wood's metal has a modulus of elasticity of 12.7 GPa and a yield strength of 26.2 MPa.^[8]

Toxicity

Wood's metal is toxic because it contains lead and cadmium, and contamination of bare skin is considered harmful. Vapour from cadmium-containing alloys is also known to pose a danger to humans.^[9] Cadmium poisoning carries the risk of cancer, anosmia (loss of sense of smell), and damage to the liver, kidneys, nerves, bones, and respiratory system. Field's metal is a non-toxic alternative.

The dust may form flammable mixtures with air.^[9]

Related alloys

Alloy	Melting point	Eutectic?	Bismuth %	Lead %	Tin %	Indium %	Cadmium %	Thallium %	Gallium %	Antimony %
Rose's metal	98 °C (208 °F)	no	50	25	25	–	–	–	–	–
Cerrosafe	74 °C (165 °F)	no	42.5	37.7	11.3	–	8.5	–	–	–
Wood's metal	70 °C (158 °F)	yes	50	26.7	13.3	–	10	–	–	–
Field's metal	62 °C (144 °F)	yes	32.5	–	16.5	51	–	–	–	–
Cerrolow 136	58 °C (136 °F)	yes	49	18	12	21	–	–	–	–
Cerrolow 117	47.2 °C (117 °F)	yes	44.7	22.6	8.3	19.1	5.3	–	–	–
Bi-Pb-Sn-Cd-In-Tl	41.5 °C (107 °F)	yes	40.3	22.2	10.7	17.7	8.1	1.1	–	–
Gallium	30.0 °C (86 °F)	Pure metal	-	-	-	-	-	-	100	–
Galinstan	−19 °C (−2 °F)	no	<1.5	–	9.5–10.5	21–22	–	–	68–69	<1.5

References

^ Jensen, William B. (2010). "The Origin of the Name "Onion's Fusible Alloy"" (PDF). Journal of Chemical Education. 87 (10): 1050–1051. Bibcode:2010JChEd..87.1050J. doi:10.1021/ed100764f. Archived from the original (Archived Reprint) on 2012-04-03.
^ "Collection: Barnabas Wood Papers". SCOUT at University of Tennessee, Knoxville. Retrieved March 22, 2022.
^ G. W. A. Milne, ed. (2005). Gardner's Commercially Important Chemicals: Synonyms, Trade Names, and Properties. John Wiley & Sons. ISBN 978-0-471-73661-5.
^ Khan F. M., Gibbons J. P. "The Physics of Radiation Therapy, 5th ed". Wolters Kluwer.
^ DeviantOllam (2019-05-01), Copying Keys via a Mold and Cast Attack, archived from the original on 2021-12-22, retrieved 2019-05-04
^ The Modern Rogue (2019-10-04), Duplicating a Key Using Molten Metal (with LockPickingLawyer), archived from the original on 2021-12-22, retrieved 2020-11-09
^ Sambamurthy, K. (2007). Pharmaceutical Engineering. New Age International. ISBN 9788122411690.
^ Do-Gyoon, Kim (February 2006). "Evaluation of Filler Materials Used for Uniform Load Distribution at Boundaries During Structural Biomechanical Testing of Whole Vertebrae". Journal of Biomechanical Engineering. 128 (1): 161–165. CiteSeerX 10.1.1.721.5864. doi:10.1115/1.2133770. PMID 16532630.
^ ^a ^b "Wood's Metal Safety Data Sheet". Flinn Scientific. Retrieved 7 October 2024.

Bibliography

Birchon's Dictionary of Metallurgy, London, 1965
Experimental techniques in low-temperature physics, G. K. White, Oxford University Press, Third Edition

External links

Making your own low-melting point eutectic: Science Toys: A metal that melts in hot water
Burdakin et al., "Melting points of gallium and of binary eutectics with gallium", Metrologia, 2008
Media related to Wood's metal at Wikimedia Commons

[1] Jensen, William B. (2010). "The Origin of the Name "Onion's Fusible Alloy"" (PDF). Journal of Chemical Education. 87 (10): 1050–1051. Bibcode:2010JChEd..87.1050J. doi:10.1021/ed100764f. Archived from the original (Archived Reprint) on 2012-04-03.

[SCOUT-Wood-papers-2] "Collection: Barnabas Wood Papers". SCOUT at University of Tennessee, Knoxville. Retrieved March 22, 2022.

[CSTN-3] G. W. A. Milne, ed. (2005). Gardner's Commercially Important Chemicals: Synonyms, Trade Names, and Properties. John Wiley & Sons. ISBN 978-0-471-73661-5.

[Khan5e-4] Khan F. M., Gibbons J. P. "The Physics of Radiation Therapy, 5th ed". Wolters Kluwer.

[5] DeviantOllam (2019-05-01), Copying Keys via a Mold and Cast Attack, archived from the original on 2021-12-22, retrieved 2019-05-04

[6] The Modern Rogue (2019-10-04), Duplicating a Key Using Molten Metal (with LockPickingLawyer), archived from the original on 2021-12-22, retrieved 2020-11-09

[7] Sambamurthy, K. (2007). Pharmaceutical Engineering. New Age International. ISBN 9788122411690.

[8] Do-Gyoon, Kim (February 2006). "Evaluation of Filler Materials Used for Uniform Load Distribution at Boundaries During Structural Biomechanical Testing of Whole Vertebrae". Journal of Biomechanical Engineering. 128 (1): 161–165. CiteSeerX 10.1.1.721.5864. doi:10.1115/1.2133770. PMID 16532630.

[Flinn_SDS-9] "Wood's Metal Safety Data Sheet". Flinn Scientific. Retrieved 7 October 2024.

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