HF • Atomic Number 72
Hafnium
Hafnium is a hard, ductile metal with a bright silver luster. It is relatively resistant to acids. Its chemical properties are very similar to zirconium; in fact, the chemical behavior of hafnium and zirconium is more alike than any other known element pair.
The main applications of hafnium include control rods in pressurized water reactors, supercapacitors, semiconductors, superalloys for aerospace industries, and high-temperature ceramics. Tantalum-hafnium carbide, with a melting point of 4,215 °C (7,619 °F), is one of the most refractory substances known.
Hafnium is obtained exclusively as a byproduct of zirconium refining. The leading global exporters of zirconium mineral concentrates are Australia and South Africa.
The global hafnium market is estimated at about 80 tons annually. Production is concentrated in a few countries: China, France, the USA, and Russia.
Framatome, a subsidiary of the French electricity company EDF, dominates the market for nuclear-grade hafnium.
Hafnium is considered a critical raw material in major industrial countries and China.
Hafnium was discovered in 1923 by Dutch physicist Dirk Coster and Hungarian-Swedish chemist George Charles von Hevesy. They identified it in zirconium minerals from Norway and Greenland by analyzing their X-ray spectra. The element was named after the Neo-Latin name for Copenhagen, Hafnia, the city where it was discovered.
The discovery history of hafnium involved a long search. Dmitri Mendeleev had predicted in 1869 an element with properties similar to titanium and zirconium. Many scientists searched unsuccessfully, including Georges Urbain and Henry Moseley. Misinterpretations led to false claims of discovery, such as “Celtium” in 1911, which was later identified as lutetium.
In the 1940s, the U.S. nuclear industry began using hafnium for control rods in nuclear reactors because, unlike zirconium, hafnium strongly absorbs neutrons.
The largest application area for hafnium is the aerospace industry. It is used in superalloys for components such as engines and in the form of hafnium-containing coatings for high-temperature components.
Another significant consumer of hafnium is the nuclear power industry. Due to its high neutron absorption cross-section and excellent mechanical properties, hafnium is used in control rods in nuclear reactors.
Hafnium also plays a role in microelectronics and the semiconductor industry. In capacitors, hafnium is used as a high-k dielectric. It can replace silicon dioxide, enabling thinner insulating layers, which improves the performance and miniaturization of semiconductor devices.
New findings regarding the properties of hafnium oxide suggest that these materials could play a key role in the development of new memory technologies. Due to the ferroelectricity of hafnium oxide, data can be stored for extended periods without power. These memory applications could pave the way for larger and faster computer systems by reducing the heat generated through continuous data transfer to volatile memory.
The most important minerals for the commercial extraction of hafnium are zircon and baddeleyite, which occur as by-products during the extraction of titanium minerals. In nature, hafnium is always bound to zirconium compounds and is difficult to separate.
Due to the strong chemical similarity between hafnium and zirconium, separating the two elements from each other is very complex and expensive. The preferred methods for separating hafnium and zirconium are ion exchange and solvent extraction techniques. However, for some applications, separation of the two elements is not necessary.
The main producing countries for hafnium-containing zirconium minerals are Australia and South Africa, where they are obtained from mineral sands and river gravels. By far the largest reserves are located in Australia.
The Australian mining company Iluka Resources is the world's largest producer of zirconium ores, followed by the US company Tronox and the British-Australian mining corporation Rio Tinto.
Framatome, a subsidiary of the French electricity company EDF, dominates the market for nuclear-grade hafnium. Allegheny Technologies Incorporated is the leading US manufacturer of hafnium for the aerospace and nuclear industries, producing highly pure hafnium for turbine blades.
China National Nuclear Corporation is China's largest producer of hafnium.
Chepetsky Mechanical Plant, a subsidiary of the state-owned corporation Rosatom, is an important Russian manufacturer supplying hafnium for the domestic nuclear and defense industries.
In 2024, the global sales volume of hafnium (Hf) is estimated at around 80 tons; however, the exact quantity cannot be determined with certainty due to secrecy in the nuclear and military sectors.
Developments in the electronics industry, increased investments in the defense sector, and the expansion of nuclear power plants are driving the growing demand for hafnium.
In alloys, hafnium can be replaced by magnesium, cobalt, chromium, niobium, and tantalum. In certain superalloys, hafnium is interchangeable with zirconium.
In control rods of nuclear reactors, boron or cadmium-silver-indium alloys can be used instead of metallic hafnium.
Critical and Strategic Metals
