Technetium: the first artificial element that saved millions of lives

In Dmitrii Ivanovich Mendeleev's periodic table, there is a cell numbered 43. For many years, it remained empty. Its inhabitant did not yield to chemists of the 19th century, hiding from the most persistent hunters for elements. But it turned out that the matter was not in the complexity of separation, but in the very nature of this substance: it simply could not have survived on Earth since its formation. Today we know this element as technetium — the first element created artificially, and at the same time, the element that saves thousands of lives every day in hospitals around the world.

Technetium is the only element lighter than lead that does not have stable isotopes. Its place in the table is a triumph of the predictive power of science and a monument to human ingenuity.

43rd element: Mendeleev's prophecy

In 1869, when Dmitrii Ivanovich Mendeleev presented his periodic table to the world, it contained 63 elements and several empty spaces. He did not just leave gaps — he boldly predicted the properties of yet-to-be-discovered substances. For the element numbered 43, which was located under manganese in the seventh group, the scientist predicted properties, calling it "eka-manganese" (from Sanskrit "eka" — one).

In the following decades, chemists searched for the missing element in manganese ores, minerals, and complex chemical production residues. There were also loud statements about its discovery: the element was called "ilmium", "nipponium", "lurium". However, none of them were confirmed. Today we know why: technetium is radioactive, and its longest-lived isotopes with a half-life of about 4 million years have long disappeared from the Earth's crust since its formation.

Why "technetium"? The artificial origin of the name

The element received its name from the Greek word "τεχνητός" (technetos), which means "artificial". The name proved to be prophetic twice: technetium became the first chemical element obtained artificially, not extracted from natural raw materials.

History of discovery: molybdenum plate from Berkeley

In 1937, Italian physicist Emilio Segrè worked in the United States, in Ernest Lawrence's cyclotron laboratory — the inventor of the cyclotron. Segrè noticed the strange radioactivity of one of the spent parts of the accelerator — molybdenum foil, which served as a target for deuterons.

The scientist assumed that a new element with the number 43 was formed in molybdenum (atomic number 42) as a result of nuclear reactions. He took the foil with him to Palermo, where, together with mineralogist Carlo Perrier, he conducted a series of complex chemical operations. They managed to isolate the new radioactive element in pure, albeit microscopic, quantities.

Basic characteristic: the lightest element without stable isotopes

Technetium is the lightest element in the periodic table that does not have any stable isotopes. Its "long-lived" forms: Tc-97 (half-life of 2.6 million years), Tc-98 (4.2 million years), and the most accessible isotope — Tc-99 (half-life of 211,000 years).

At the same time, natural technetium does exist on Earth. In negligible trace amounts (about 1 nanogram per ton of uranium ore), it is formed in the process of spontaneous fission of uranium-235. At any given moment, there are about 18,000 tons of technetium in the Earth's crust — but this metal "dissolved" in vast amounts of rock formations.

Unexpected properties: from superconductivity to chemical cunning

Physical properties. Technetium is a silver-gray transition metal. Its crystal lattice under standard conditions is hexagonal, it is malleable and ductile. Surprisingly, at low temperatures, technetium becomes a superconductor.

Chemical versatility. Technetium has oxidation states from −1 to +7, and the most stable form is the seven-valent technetium (Tc⁷⁺). At the same time, chemists often compare it to rhenium. This versatility creates serious problems in the processing of spent nuclear fuel: unpredictable redox reactions involving technetium complicate the processes of uranium and plutonium separation.

Primary application today: nuclear medicine and technetium-99m

Today, the vast majority of technetium is extracted from nuclear industry waste — from spent fuel rods of nuclear reactors. The yield of the isotope Tc-99 during uranium-235 fission is about 6%. However, the focus is not on the long-lived Tc-99, but on its short-lived nuclear isomer — Tc-99m (m means metastable, nuclear excited state) with a half-life of only 6 hours.

This isotope is one of the cornerstones of modern nuclear medicine. Radiopharmaceuticals based on it are produced for diagnosing malignant tumors, assessing blood flow in the heart, and studying the functions of many internal organs. The mechanism is as follows: Tc-99m emits gamma rays that are easily detectable by special cameras. The isotope is introduced into the body (often in a bound form with molecules tropic to certain tissues) and sends a signal, allowing doctors to "see" a tumor, an inflammatory focus, or an area of myocardial ischemia.

The short half-life of the radioactive isotope allows for an accurate picture and quick excretion of the substance from the body, causing minimal radiation damage. More than 20 million diagnostic procedures using technetium-99m are performed worldwide each year. In Russia, the production of technetium-99m generators is carried out by enterprises of the Rosatom scientific division.

Risk and ecology: long-lived waste

The long-lived technetium-99 (T_1/2 = 211,000 years) represents a serious environmental problem. Its content in spent nuclear fuel reaches hundreds of grams per ton. This isotope is mobile in the environment and can accumulate in biological objects. Therefore, the disposal of Tc-99 is one of the tasks in creating repositories for radioactive waste. Its half-life and chemical mobility force the search for special matrices for reliable isolation.

The future of the element: catalysts, superconductors, and new radiopharmaceuticals

Today, technetium remains a niche but extremely important element in diagnostic medicine. However, its potential is broader. Technetium is a promising material for making catalysts (for example, for the dehydrogenation of organic compounds) and components of high-temperature superconducting alloys. Also, chemists are developing methods for separating technetium from liquid radioactive waste using sorbents and new compounds for targeted nuclear medicine, including theranostics (diagnosis and therapy with one molecule).

In the future, new methods of extracting Tc-99m from reactor and accelerator stockpiles may emerge, making diagnostics even more accessible. Also promising is the use of the isotope Tc-99 in nuclear batteries for devices that work for decades without recharging.

Conclusion: The 43rd element of the periodic system is a bridge between the predictive genius of the 19th century and the high technologies of the 21st century. Technetium, the first artificial element without stable isotopes, is the only metal that is used in millions of medical diagnostics every year in the form of the isomer Tc-99m.
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