The COLEX process (or COLEX separation) is a chemical method of isotopic separation of

lithium-6 Naturally occurring lithium (3Li) is composed of two stable isotope ratio, stable isotopes, lithium-6 (6Li) and lithium-7 (7Li), with the latter being far more abundant on Earth. Both of the natural isotopes have an unexpectedly low nuclear bin ...

and lithium-7, based on the use of mercury. COLEX stands for column exchange. Since the beginning of the atomic era, a variety of lithium enrichments methods have been developed (such as chemical exchange, electromagnetic, laser, centrifugal) and the COLEX process has been the most extensively implemented method so far.

Early development

In the US, several chemical exchange methods for lithium isotope separation have been under investigation in the 1930s and 1940s to develop a process for lithium-6 production, so that

tritium Tritium () or hydrogen-3 (symbol T or H) is a rare and radioactive isotope of hydrogen with a half-life of ~12.33 years. The tritium nucleus (t, sometimes called a ''triton'') contains one proton and two neutrons, whereas the nucleus of the ...

could be obtained for thermonuclear weapons research. The system finally selected was the COLEX process, with aqueous

lithium hydroxide Lithium hydroxide is an inorganic compound with the formula LiOH. It can exist as anhydrous or hydrated, and both forms are white hygroscopic solids. They are soluble in water and slightly soluble in ethanol. Both are available commercially. While ...

(LiOH) contacted with lithium-mercury amalgam. This process was initially used in the US between 1955 and 1963 in the Y12 plant in

Oak Ridge, Tennessee Oak Ridge is a city in Anderson County, Tennessee, Anderson and Roane County, Tennessee, Roane counties in the East Tennessee, eastern part of the U.S. state of Tennessee, about west of downtown Knoxville, Tennessee, Knoxville. Oak Ridge's po ...

. The COLEX plants in Oak Ridge had a very rough start in 1955 with major problems in this entirely new, complicated, and potentially hazardous technology. Stockpiles of lithium-6 and lithium-7 from that period have been available until recently to meet the relatively small domestic and world demand Since then, due to environmental concerns, the US has stopped lithium enrichments operations in 1963.

South Africa South Africa, officially the Republic of South Africa (RSA), is the Southern Africa, southernmost country in Africa. Its Provinces of South Africa, nine provinces are bounded to the south by of coastline that stretches along the Atlantic O ...

also built a pilot plant using the COLEX method to make lithium-6 for its nuclear weapons program in the 1970s.

Lithium isotopes and uses

Natural lithium contains about 7.5% lithium-6 ( ), with the rest being lithium-7 ( ).

Natural lithium

Naturally occurring lithium has many non nuclear industrial uses, ranging from Li-ion batteries, ceramics, lubricants, to glass. In the beginning of the 21st century, the steady increase of lithium world production is mainly stimulated by the demand of Li-ion batteries for

electric vehicles An electric vehicle (EV) is a motor vehicle whose propulsion is powered fully or mostly by electricity. EVs encompass a wide range of transportation modes, including road vehicle, road and rail vehicles, electric boats and Submersible, submer ...

. The nuclear applications of lithium requires relatively small annual quantities of lithium, in the form of enriched lithium-6 and lithium-7.

Lithium-6

Lithium-6 is valuable as the source material for the production of tritium and as an absorber of neutrons in nuclear fusion reactions. Enriched lithium-6 is used as a neutron booster in thermonuclear bombs, and will be a key component in the tritium breeding modules (required enrichment from 7.5% to 30%-90%) of the future fusion reactors based on plasma confinement. The separation of lithium-6 has by now ceased in the large thermonuclear powers (notably USA, Russia, China), but stockpiles of it remain in these countries.

Lithium-7

Highly enriched lithium-7 (more than 99%) is used as a coolant in molten salt reactors (MSRs) and pH stabilizer in

pressurized water reactor A pressurized water reactor (PWR) is a type of light-water nuclear reactor. PWRs constitute the large majority of the world's nuclear power plants (with notable exceptions being the UK, Japan, India and Canada). In a PWR, water is used both as ...

s (PWRs).

Working principle

Lithium-6 has a greater affinity than lithium-7 for the element mercury. When an amalgam of lithium and mercury is added to aqueous lithium hydroxide, the lithium-6 becomes more concentrated in the amalgam and the lithium-7 more in the hydroxide solution. The COLEX separation method makes use of this by passing a counter-flow of lithium-mercury amalgam flowing down and aqueous lithium hydroxide flowing up through a cascade of stages. The fraction of lithium-6 is preferentially drained by the mercury, but the lithium-7 flows mostly with the hydroxide. At the bottom of the column, the lithium (enriched with lithium-6) is separated from the amalgam, and the mercury is recovered to be reused in the process. At the top, the lithium hydroxide solution is electrolyzed to liberate the lithium-7 fraction. The enrichment obtained with this method varies with the column length, the flow speed, and the

operating temperature An operating temperature is the allowable temperature range of the local ambient environment at which an electrical or mechanical device operates. The device will operate effectively within a specified temperature range which varies based on the de ...

Advantages and disadvantages

From a technical and economical point of view, the COLEX separation has been so far the only method that enables industrial scale production of enriched lithium at minimal costs. The technology is mature, and has changed little since its development in the 1950s and 1960s. The method is not without a number of drawbacks, the main of which are: * toxicity and large amounts of mercury, participating in the process * amalgam trend to decomposition in aqueous solutions * formation of dangerous mercury-containing waste * high energy consumption The technology has potentially disastrous environmental implications. A significant amount of mercury is required (24 million pounds were used in the U.S. between 1955 and 1963) and many opportunities for leaks into the environment exist. Cleanup remains extremely difficult and expensive. In spite of the health and environmental concerns associated with processes based on mercury, some research is still being done on the COLEX separation along with cleaner lithium enrichment methods.

COLEX separation facilities in the world

Nowadays, it seems that China is the only country in the world which officially employs the COLEX process to enrich lithium. Due to environmental concerns and relatively low demand for enriched lithium, further use of the COLEX process is officially banned in the USA since 1963, which strengthens China's nearly exclusive hold over the market of enriched lithium, followed by Russia. Russian enrichment capacities focus on lithium-7 production by electrolysis of an aqueous

lithium chloride Lithium chloride is a chemical compound with the formula Li Cl. The salt is a typical ionic compound (with certain covalent characteristics), although the small size of the Li+ ion gives rise to properties not seen for other alkali metal chlorid ...

solution using a mercury cathode, which is thus different from the COLEX process. Although the US nuclear industry relies heavily on Chinese and Russian enriched lithium, ecological concerns over the COLEX process may impede its future domestic use at industrial scale. However, with the upswing in research in the general area of fusion reactor technology (ITER, DEMO) there has been renewed interest during the last decade in better processes for ⁶Li-⁷Li separation, especially in Japan and the US. North Korea is assessed to have procured the means to build a lithium-6 enrichment plant based on the COLEX separation. No industrial-scale facilities exist today that could meet the future requirements of commercial fusion power plants.

References

{{Reflist Isotope separation