Science, Tech, Math › Science Rare Earth Metals Share Flipboard Email Print Jie Zhao/Contributor/Getty Images Science Chemistry Periodic Table Basics Chemical Laws Molecules Projects & Experiments Scientific Method Biochemistry Physical Chemistry Medical Chemistry Chemistry In Everyday Life Famous Chemists Activities for Kids Abbreviations & Acronyms Biology Physics Geology Astronomy Weather & Climate By Ryan Wojes Northwestern University Ryan Wojes wrote about commodities and metals for The Balance and worked as a metallurgist for more than 13 years. our editorial process LinkedIn LinkedIn Ryan Wojes Updated December 04, 2019 Rare earth metals are actually not as rare as their name might imply. They are critical to high-performance optics and lasers, and essential to the most powerful magnets and superconductors in the world. Rare earths are simply more expensive to mine than most metals when not mined with environmentally harmful chemicals. These metals are also traditionally not as profitable in the markets. This has made them less desirable in the past—until the world realized that China controlled much of the market. These difficulties, combined with the demand for the metals for use in high-tech applications, introduces economic and political complications that make some of the most interesting metals even more exciting for investors. Rare Earths in the Marketplace According to the United States Geological Survey, as of 2018, China produced around 80% of world demand for rare earth metals (down from 95% in 2010). Their ores are rich in yttrium, lanthanum, and neodymium. Since August of 2010, fears over Chinese dominance of crucial rare earth supplies have lingered as China restricted export quotas of the metals with no official explanation, immediately sparking debate over decentralization of world rare earth production. Great quantities of rare earth ores were found in California in 1949, and more are being sought throughout North America, but current mining is not significant enough to strategically control any portion of the global rare earths market (the Mountain Pass mine in California still has to ship its minerals to China to be processed). Rare earths are traded on the NYSE in the form of exchange-traded funds (ETFs) that represent a basket of supplier and mining stocks, as opposed to trading in the metals themselves. This is due to their rarity and price, as well as their almost strictly industrial consumption. Rare earth metals are not considered a good physical investment like precious metals, which hold low-tech intrinsic value. Rare Earth Metals and Their Applications In the periodic table of the elements, the third column lists the rare earth elements. The third row of the third column is expanded below the chart, listing the lanthanide series of elements. Scandium and Yttrium are listed as rare earth metals, although they are not part of the lanthanide series. This is due to the prevalence of the two elements being similar in part to the lanthanides. Column 3 of the Periodic Table of Elements Lists the Rare Earths. Todd Helmenstine In order of increasing atomic mass, the 17 rare earth metals and some of their common applications are given below. Scandium: Atomic weight 21. Used to strengthen aluminum alloys.Yttrium: Atomic weight 39. Used in superconductors and exotic light sources.Lanthanum: Atomic weight 57. Used in specialty glasses and optics, electrodes and hydrogen storage.Cerium: Atomic weight 58. Makes an excellent oxidizer, used in oil cracking during petroleum refining and is used for yellow coloring in ceramics and glass.Praseodymium: Atomic weight 59. Used in magnets, lasers and as green color in ceramics and glass.Neodymium: Atomic weight 60. Used in magnets, lasers and as purple color in ceramics and glass.Promethium: Atomic weight 61. Used in nuclear batteries. Only man-made isotopes have ever been observed on Earth, with a speculated 500-600 grams naturally occurring on the planet.Samarium: Atomic weight 62. Used in magnets, lasers and neutron capture.Europium: Atomic weight 63. Makes colored phosphors, lasers, and mercury-vapor lamps.Gadolinium: Atomic weight 64. Used in magnets, specialty optics, and computer memory.Terbium: Atomic weight 65. Used as green in ceramics and paints, and in lasers and fluorescent lamps.Dysprosium: Atomic weight 66. Used in magnets and lasers.Holmium: Atomic weight 67. Used in lasers.Erbium: Atomic weight 68. Used in steel alloyed with vanadium, as well as in lasers.Thulium: Atomic weight 69. Used in portable x-ray equipment.Ytterbium: Atomic weight 70. Used in infrared lasers. Also, works as a great chemical reducer.Lutetium: Atomic weight 71. Used in specialty glass and radiology equipment.