Technetium is a chemical element it has symbol Tc and atomic number 43 It is the lightest element whose isotopes are all

Technetium is a chemical element it has symbol Tc and atomic number 43 It is the lightest element whose isotopes are all radioactive Technetium and promethium are the only radioactive elements whose neighbours in the sense of atomic number are both stable All available technetium is produced as a synthetic element Naturally occurring technetium is a spontaneous fission product in uranium ore and thorium ore the most common source or the product of neutron capture in molybdenum ores This silvery gray crystalline transition metal lies between manganese and rhenium in group 7 of the periodic table and its chemical properties are intermediate between those of both adjacent elements The most common naturally occurring isotope is 99Tc in traces only Technetium 43TcTechnetiumPronunciation t ɛ k ˈ n iː ʃ i e m wbr tek NEE sh ee em Appearanceshiny gray metalMass number 97 data not decisive Technetium in the periodic tableHydrogen HeliumLithium Beryllium Boron Carbon Nitrogen Oxygen Fluorine NeonSodium Magnesium Aluminium Silicon Phosphorus Sulfur Chlorine ArgonPotassium Calcium Scandium Titanium Vanadium Chromium Manganese Iron Cobalt Nickel Copper Zinc Gallium Germanium Arsenic Selenium Bromine KryptonRubidium Strontium Yttrium Zirconium Niobium Molybdenum Technetium Ruthenium Rhodium Palladium Silver Cadmium Indium Tin Antimony Tellurium Iodine XenonCaesium Barium Lanthanum Cerium Praseodymium Neodymium Promethium Samarium Europium Gadolinium Terbium Dysprosium Holmium Erbium Thulium Ytterbium Lutetium Hafnium Tantalum Tungsten Rhenium Osmium Iridium Platinum Gold Mercury element Thallium Lead Bismuth Polonium Astatine RadonFrancium Radium Actinium Thorium Protactinium Uranium Neptunium Plutonium Americium Curium Berkelium Californium Einsteinium Fermium Mendelevium Nobelium Lawrencium Rutherfordium Dubnium Seaborgium Bohrium Hassium Meitnerium Darmstadtium Roentgenium Copernicium Nihonium Flerovium Moscovium Livermorium Tennessine Oganesson Mn Tc Remolybdenum technetium rutheniumAtomic number Z 43Groupgroup 7Periodperiod 5Block d blockElectron configuration Kr 4d5 5s2Electrons per shell2 8 18 13 2Physical propertiesPhase at STPsolidMelting point2430 K 2157 C 3915 F Boiling point4538 K 4265 C 7709 F Density at 20 C 98Tc 11 359 g cm3 99Tc 11 475 g cm3Heat of fusion33 29 kJ molHeat of vaporization585 2 kJ molMolar heat capacity24 27 J mol K Vapor pressure extrapolated P Pa 1 10 100 1 k 10 k 100 kat T K 2727 2998 3324 3726 4234 4894Atomic propertiesOxidation statescommon 4 7 1 1 2 3 5 6ElectronegativityPauling scale 1 9Ionization energies1st 686 9 kJ mol2nd 1470 kJ mol3rd 2850 kJ molAtomic radiusempirical 136 pmCovalent radius147 7 pmVan der Waals radius205 pmSpectral lines of technetiumOther propertiesNatural occurrencefrom decayCrystal structure hexagonal close packed hcp hP2 Lattice constantsa 274 12 pm c 439 90 pm at 20 C Thermal expansion8 175 10 6 K at 20 C Thermal conductivity50 6 W m K Electrical resistivity200 nW m at 20 C Magnetic orderingParamagneticMolar magnetic susceptibility 270 0 10 6 cm3 mol 298 K Speed of sound thin rod16 200 m s at 20 C CAS Number7440 26 8HistoryNamingafter Greek texnhtos artificial for being the first artificially produced elementPredictionDmitri Mendeleev 1871 Discovery and first isolationEmilio Segre and Carlo Perrier 1937 Isotopes of technetiumveMain isotopes Decayabun dance half life t1 2 mode pro duct95mTc synth 61 96 d b 95MoIT 95Tc96Tc synth 4 28 d b 96Mo97Tc synth 4 21 106 y e 97Mo97mTc synth 91 1 d IT 97Tce 97Mo98Tc synth 4 2 106 y b 98Ru99Tc trace 2 111 105 y b 99Ru99mTc synth 6 01 h IT 99Tcb 99Ru Category Technetium viewtalkedit references Many of technetium s properties had been predicted by Dmitri Mendeleev before it was discovered Mendeleev noted a gap in his periodic table and gave the undiscovered element the provisional name ekamanganese Em In 1937 technetium became the first predominantly artificial element to be produced hence its name from the Greek technetos artificial ium One short lived gamma ray emitting nuclear isomer technetium 99m is used in nuclear medicine for a wide variety of tests such as bone cancer diagnoses The ground state of the nuclide technetium 99 is used as a gamma ray free source of beta particles Long lived technetium isotopes produced commercially are byproducts of the fission of uranium 235 in nuclear reactors and are extracted from nuclear fuel rods Because even the longest lived isotope of technetium has a relatively short half life 4 21 million years the 1952 detection of technetium in red giants helped to prove that stars can produce heavier elements HistoryEarly assumptions From the 1860s through 1871 early forms of the periodic table proposed by Dmitri Mendeleev contained a gap between molybdenum element 42 and ruthenium element 44 In 1871 Mendeleev predicted this missing element would occupy the empty place below manganese and have similar chemical properties Mendeleev gave it the provisional name eka manganese from eka the Sanskrit word for one because it was one place down from the known element manganese Early misidentifications Many early researchers both before and after the periodic table was published were eager to be the first to discover and name the missing element Its location in the table suggested that it should be easier to find than other undiscovered elements This turned out not to be the case due to technetium s radioactivity Year Claimant Suggested name Actual material1828 Gottfried Osann Polinium Iridium1845 Heinrich Rose Pelopium Niobium tantalum alloy1847 R Hermann Ilmenium Niobium tantalum alloy1877 Serge Kern Davyum Iridium rhodium iron alloy1896 Prosper Barriere Lucium Yttrium1908 Masataka Ogawa Nipponium Rhenium which was the unknown dvi manganeseIrreproducible results Periodisches System der Elemente Periodic system of the elements 1904 1945 now at the Gdansk University of Technology lack of elements polonium 84Po though discovered as early as in 1898 by Maria Sklodowska Curie astatine 85At 1940 in Berkeley francium 87Fr 1939 in France neptunium 93Np 1940 in Berkeley and other actinides and lanthanides Uses old symbols for argon 18Ar here A technetium 43Tc Ma masurium xenon 54Xe X radon 86Rn Em emanation German chemists Walter Noddack Otto Berg and Ida Tacke reported the discovery of element 75 and element 43 in 1925 and named element 43 masurium after Masuria in eastern Prussia now in Poland the region where Walter Noddack s family originated This name caused significant resentment in the scientific community because it was interpreted as referring to a series of victories of the German army over the Russian army in the Masuria region during World War I as the Noddacks remained in their academic positions while the Nazis were in power suspicions and hostility against their claim for discovering element 43 continued The group bombarded columbite with a beam of electrons and deduced element 43 was present by examining X ray emission spectrograms The wavelength of the X rays produced is related to the atomic number by a formula derived by Henry Moseley in 1913 The team claimed to detect a faint X ray signal at a wavelength produced by element 43 Later experimenters could not replicate the discovery and it was dismissed as an error Still in 1933 a series of articles on the discovery of elements quoted the name masurium for element 43 Some more recent attempts have been made to rehabilitate the Noddacks claims but they are disproved by Paul Kuroda s study on the amount of technetium that could have been present in the ores they studied it could not have exceeded 3 10 11 mg kg of ore and thus would have been undetectable by the Noddacks methods Official discovery and later history The discovery of element 43 was finally confirmed in a 1937 experiment at the University of Palermo in Sicily by Carlo Perrier and Emilio Segre In mid 1936 Segre visited the United States first Columbia University in New York and then the Lawrence Berkeley National Laboratory in California He persuaded cyclotron inventor Ernest Lawrence to let him take back some discarded cyclotron parts that had become radioactive Lawrence mailed him a molybdenum foil that had been part of the deflector in the cyclotron Segre enlisted his colleague Perrier to attempt to prove through comparative chemistry that the molybdenum activity was indeed from an element with the atomic number 43 In 1937 they succeeded in isolating the isotopes technetium 95m and technetium 97 disputed discuss University of Palermo officials wanted them to name their discovery panormium after the Latin name for Palermo Panormus In 1947 element 43 was named after the Greek word technetos texnhtos meaning artificial since it was the first element to be artificially produced Segre returned to Berkeley and met Glenn T Seaborg They isolated the metastable isotope technetium 99m which is now used in some ten million medical diagnostic procedures annually In 1952 the astronomer Paul W Merrill detected the spectral signature of technetium specifically wavelengths of 403 1 nm 423 8 nm 426 2 nm and 429 7 nm in light from S type red giants The stars were near the end of their lives but were rich in the short lived element which indicated that it was being produced in the stars by nuclear reactions That evidence bolstered the hypothesis that heavier elements are the product of nucleosynthesis in stars More recently such observations provided evidence that elements are formed by neutron capture in the s process Since that discovery there have been many searches in terrestrial materials for natural sources of technetium In 1962 technetium 99 was isolated and identified in pitchblende from the Belgian Congo in very small quantities about 0 2 ng kg where it originates as a spontaneous fission product of uranium 238 The natural nuclear fission reactor in Oklo contains evidence that significant amounts of technetium 99 were produced and have since decayed into ruthenium 99 CharacteristicsPhysical properties Technetium is a silvery gray radioactive metal with an appearance similar to platinum commonly obtained as a gray powder 25 The crystal structure of the bulk pure metal is hexagonal close packed Atomic technetium has characteristic emission lines at wavelengths of 363 3 nm 403 1 nm 426 2 nm 429 7 nm and 485 3 nm The unit cell parameters of the orthorhombic Tc metal were reported when Tc is contaminated with carbon a 0 2805 4 b 0 4958 8 c 0 4474 5 nm for Tc C with 1 38 wt C and a 0 2815 4 b 0 4963 8 c 0 4482 5 nm for Tc C with 1 96 wt C The metal form is slightly paramagnetic meaning its magnetic dipoles align with external magnetic fields but will assume random orientations once the field is removed Pure metallic single crystal technetium becomes a type II superconductor at temperatures below 7 46 K 265 69 C 446 24 F Below this temperature technetium has a very high magnetic penetration depth greater than any other element except niobium Chemical properties Technetium is located in group 7 of the periodic table between rhenium and manganese As predicted by the periodic law its chemical properties are between those two elements Of the two technetium more closely resembles rhenium particularly in its chemical inertness and tendency to form covalent bonds This is consistent with the tendency of period 5 elements to resemble their counterparts in period 6 more than period 4 due to the lanthanide contraction Unlike manganese technetium does not readily form cations ions with net positive charge Technetium exhibits nine oxidation states from 1 to 7 with 4 5 and 7 being the most common Technetium dissolves in aqua regia nitric acid and concentrated sulfuric acid but not in hydrochloric acid of any concentration 25 Metallic technetium slowly tarnishes in moist air and in powder form burns in oxygen When reacting with hydrogen at high pressure it forms the non stoichiometric hydride TcH1 3 and while reacting with carbon it forms Tc6C with cell parameter 0 398 nm Technetium can catalyse the destruction of hydrazine by nitric acid and this property is due to its multiplicity of valencies This caused a problem in the separation of plutonium from uranium in nuclear fuel processing where hydrazine is used as a protective reductant to keep plutonium in the trivalent rather than the more stable tetravalent state The problem was exacerbated by the mutually enhanced solvent extraction of technetium and zirconium at the previous stage and required a process modification CompoundsPertechnetate and other derivatives Pertechnetate is one of the most available forms of technetium It is structurally related to permanganate The most prevalent form of technetium that is easily accessible is sodium pertechnetate Na TcO4 The majority of this material is produced by radioactive decay from 99MoO4 2 99MoO4 2 99mTcO4 e Pertechnetate TcO 4 is only weakly hydrated in aqueous solutions and it behaves analogously to perchlorate anion both of which are tetrahedral Unlike permanganate MnO 4 it is only a weak oxidizing agent Related to pertechnetate is technetium heptoxide This pale yellow volatile solid is produced by oxidation of Tc metal and related precursors 4 Tc 7 O2 2 Tc2O7 It is a molecular metal oxide analogous to manganese heptoxide It adopts a centrosymmetric structure with two types of Tc O bonds with 167 and 184 pm bond lengths Technetium heptoxide hydrolyzes to pertechnetate and pertechnetic acid depending on the pH Tc2O7 2 OH 2 TcO4 H2O Tc2O7 H2O 2 HTcO4 HTcO4 is a strong acid In concentrated sulfuric acid TcO4 converts to the octahedral form TcO3 OH H2O 2 the conjugate base of the hypothetical triaquo complex TcO3 H2O 3 Other chalcogenide derivatives Technetium forms a dioxide disulfide diselenide and ditelluride An ill defined Tc2S7 forms upon treating pertechnate with hydrogen sulfide It thermally decomposes into disulfide and elemental sulfur Similarly the dioxide can be produced by reduction of the Tc2O7 Unlike the case for rhenium a trioxide has not been isolated for technetium However TcO3 has been identified in the gas phase using mass spectrometry Simple hydride and halide complexes Technetium forms the complex TcH2 9 The potassium salt is isostructural with ReH2 9 At high pressure formation of TcH1 3 from elements was also reported TcCl4 forms chain like structures similar to the behavior of several other metal tetrachlorides The following binary containing only two elements technetium halides are known TcF6 TcF5 TcCl4 TcBr4 TcBr3 a TcCl3 b TcCl3 TcI3 a TcCl2 and b TcCl2 The oxidation states range from Tc VI to Tc II Technetium halides exhibit different structure types such as molecular octahedral complexes extended chains layered sheets and metal clusters arranged in a three dimensional network These compounds are produced by combining the metal and halogen or by less direct reactions TcCl4 is obtained by chlorination of Tc metal or Tc2O7 Upon heating TcCl4 gives the corresponding Tc III and Tc II chlorides TcCl4 a TcCl3 1 2 Cl2 TcCl3 b TcCl2 1 2 Cl2 The structure of TcCl4 is composed of infinite zigzag chains of edge sharing TcCl6 octahedra It is isomorphous to transition metal tetrachlorides of zirconium hafnium and platinum Chloro containing coordination complexes of technetium 99Tc in various oxidation states Tc III Tc IV Tc V and Tc VI represented Two polymorphs of technetium trichloride exist a and b TcCl3 The a polymorph is also denoted as Tc3Cl9 It adopts a confacial bioctahedral structure It is prepared by treating the chloro acetate Tc2 O2CCH3 4Cl2 with HCl Like Re3Cl9 the structure of the a polymorph consists of triangles with short M M distances b TcCl3 features octahedral Tc centers which are organized in pairs as seen also for molybdenum trichloride TcBr3 does not adopt the structure of either trichloride phase Instead it has the structure of molybdenum tribromide consisting of chains of confacial octahedra with alternating short and long Tc Tc contacts TcI3 has the same structure as the high temperature phase of TiI3 featuring chains of confacial octahedra with equal Tc Tc contacts Several anionic technetium halides are known The binary tetrahalides can be converted to the hexahalides TcX6 2 X F Cl Br I which adopt octahedral molecular geometry More reduced halides form anionic clusters with Tc Tc bonds The situation is similar for the related elements of Mo W Re These clusters have the nuclearity Tc4 Tc6 Tc8 and Tc13 The more stable Tc6 and Tc8 clusters have prism shapes where vertical pairs of Tc atoms are connected by triple bonds and the planar atoms by single bonds Every technetium atom makes six bonds and the remaining valence electrons can be saturated by one axial and two bridging ligand halogen atoms such as chlorine or bromine Coordination and organometallic complexes Technetium 99mTc sestamibi Cardiolite is widely used for imaging of the heart Technetium forms a variety of coordination complexes with organic ligands Many have been well investigated because of their relevance to nuclear medicine Technetium forms a variety of compounds with Tc C bonds i e organotechnetium complexes Prominent members of this class are complexes with CO arene and cyclopentadienyl ligands The binary carbonyl Tc2 CO 10 is a white volatile solid In this molecule two technetium atoms are bound to each other each atom is surrounded by octahedra of five carbonyl ligands The bond length between technetium atoms 303 pm is significantly larger than the distance between two atoms in metallic technetium 272 pm Similar carbonyls are formed by technetium s congeners manganese and rhenium Interest in organotechnetium compounds has also been motivated by applications in nuclear medicine Technetium also forms aquo carbonyl complexes one prominent complex being Tc CO 3 H2O 3 which are unusual compared to other metal carbonyls IsotopesTechnetium with atomic number Z 43 is the lowest numbered element in the periodic table for which all isotopes are radioactive The second lightest exclusively radioactive element promethium has atomic number 61 Atomic nuclei with an odd number of protons are less stable than those with even numbers even when the total number of nucleons protons neutrons is even and odd numbered elements have fewer stable isotopes The most stable radioactive isotopes are technetium 97 with a half life of 4 21 0 16 million years and technetium 98 with 4 2 0 3 million years current measurements of their half lives give overlapping confidence intervals corresponding to one standard deviation and therefore do not allow a definite assignment of technetium s most stable isotope The next most stable isotope is technetium 99 which has a half life of 211 100 years Thirty four other radioisotopes have been characterized with mass numbers ranging from 86 to 122 Most of these have half lives that are less than an hour the exceptions being technetium 93 2 73 hours technetium 94 4 88 hours technetium 95 20 hours and technetium 96 4 3 days The primary decay mode for isotopes lighter than technetium 98 98Tc is electron capture producing molybdenum Z 42 For technetium 98 and heavier isotopes the primary mode is beta emission the emission of an electron or positron producing ruthenium Z 44 with the exception that technetium 100 can decay both by beta emission and electron capture Technetium also has numerous nuclear isomers which are isotopes with one or more excited nucleons Technetium 97m 97mTc m stands for metastability is the most stable with a half life of 91 days and excitation energy 0 0965 MeV This is followed by technetium 95m 61 days 0 03 MeV and technetium 99m 6 01 hours 0 142 MeV Technetium 99 99Tc is a major product of the fission of uranium 235 235U making it the most common and most readily available isotope of technetium One gram of technetium 99 produces 6 2 108 disintegrations per second in other words the specific activity of 99Tc is 0 62 GBq g Occurrence and productionTechnetium occurs naturally in the Earth s crust in minute concentrations of about 0 003 parts per trillion Technetium is so rare because the half lives of 97Tc and 98Tc are only 4 2 million years More than a thousand of such periods have passed since the formation of the Earth so the probability of survival of even one atom of primordial technetium is effectively zero However small amounts exist as spontaneous fission products in uranium ores A kilogram of uranium contains an estimated 1 nanogram 10 9 g equivalent to ten trillion atoms of technetium Some red giant stars with the spectral types S M and N display a spectral absorption line indicating the presence of technetium 25 These red giants are known informally as technetium stars Fission waste product In contrast to the rare natural occurrence bulk quantities of technetium 99 are produced each year from spent nuclear fuel rods which contain various fission products The fission of a gram of uranium 235 in nuclear reactors yields 27 mg of technetium 99 giving technetium a fission product yield of 6 1 Other fissile isotopes produce similar yields of technetium such as 4 9 from uranium 233 and 6 21 from plutonium 239 An estimated 49 000 TBq 78 metric tons of technetium was produced in nuclear reactors between 1983 and 1994 by far the dominant source of terrestrial technetium Only a fraction of the production is used commercially Technetium 99 is produced by the nuclear fission of both uranium 235 and plutonium 239 It is therefore present in radioactive waste and in the nuclear fallout of fission bomb explosions Its decay measured in becquerels per amount of spent fuel is the dominant contributor to nuclear waste radioactivity after about 104 106 years after the creation of the nuclear waste From 1945 1994 an estimated 160 TBq about 250 kg of technetium 99 was released into the environment during atmospheric nuclear tests The amount of technetium 99 from nuclear reactors released into the environment up to 1986 is on the order of 1000 TBq about 1600 kg primarily by nuclear fuel reprocessing most of this was discharged into the sea Reprocessing methods have reduced emissions since then but as of 2005 the primary release of technetium 99 into the environment is by the Sellafield plant which released an estimated 550 TBq about 900 kg from 1995 to 1999 into the Irish Sea From 2000 onwards the amount has been limited by regulation to 90 TBq about 140 kg per year Discharge of technetium into the sea resulted in contamination of some seafood with minuscule quantities of this element For example European lobster and fish from west Cumbria contain about 1 Bq kg of technetium Fission product for commercial use The metastable isotope technetium 99m is continuously produced as a fission product from the fission of uranium or plutonium in nuclear reactors U92238 sfI53137 Y3999 201n displaystyle ce 238 92 U gt ce sf 137 53 I 99 39 Y 2 1 0 n Y3999 1 47sb Zr4099 2 1sb Nb4199 15 0sb Mo4299 65 94hb Tc4399 211 100yb Ru4499 displaystyle ce 99 39 Y gt beta 1 47 ce s 99 40 Zr gt beta 2 1 ce s 99 41 Nb gt beta 15 0 ce s 99 42 Mo gt beta 65 94 ce h 99 43 Tc gt beta 211 100 ce y 99 44 Ru Because used fuel is allowed to stand for several years before reprocessing all molybdenum 99 and technetium 99m is decayed by the time that the fission products are separated from the major actinides in conventional nuclear reprocessing The liquid left after plutonium uranium extraction PUREX contains a high concentration of technetium as TcO 4 but almost all of this is technetium 99 not technetium 99m The vast majority of the technetium 99m used in medical work is produced by irradiating dedicated highly enriched uranium targets in a reactor extracting molybdenum 99 from the targets in reprocessing facilities and recovering at the diagnostic center the technetium 99m produced upon decay of molybdenum 99 Molybdenum 99 in the form of molybdate MoO2 4 is adsorbed onto acid alumina Al2 O3 in a shielded column chromatograph inside a technetium 99m generator technetium cow also occasionally called a molybdenum cow Molybdenum 99 has a half life of 67 hours so short lived technetium 99m half life 6 hours which results from its decay is being constantly produced The soluble pertechnetate TcO 4 can then be chemically extracted by elution using a saline solution A drawback of this process is that it requires targets containing uranium 235 which are subject to the security precautions of fissile materials The first technetium 99m generator unshielded 1958 A Tc 99m pertechnetate solution is being eluted from Mo 99 molybdate bound to a chromatographic substrate Almost two thirds of the world s supply comes from two reactors the National Research Universal Reactor at Chalk River Laboratories in Ontario Canada and the High Flux Reactor at Nuclear Research and Consultancy Group in Petten Netherlands All major reactors that produce technetium 99m were built in the 1960s and are close to the end of life The two new Canadian Multipurpose Applied Physics Lattice Experiment reactors planned and built to produce 200 of the demand of technetium 99m relieved all other producers from building their own reactors With the cancellation of the already tested reactors in 2008 the future supply of technetium 99m became problematic Waste disposal The long half life of technetium 99 and its potential to form anionic species creates a major concern for long term disposal of radioactive waste Many of the processes designed to remove fission products in reprocessing plants aim at cationic species such as caesium e g caesium 137 and strontium e g strontium 90 Hence the pertechnetate escapes through those processes Current disposal options favor burial in continental geologically stable rock The primary danger with such practice is the likelihood that the waste will contact water which could leach radioactive contamination into the environment The anionic pertechnetate and iodide tend not to adsorb into the surfaces of minerals and are likely to be washed away By comparison plutonium uranium and caesium tend to bind to soil particles Technetium could be immobilized by some environments such as microbial activity in lake bottom sediments and the environmental chemistry of technetium is an area of active research An alternative disposal method transmutation has been demonstrated at CERN for technetium 99 In this process the technetium technetium 99 as a metal target is bombarded with neutrons to form the short lived technetium 100 half life 16 seconds which decays by beta decay to stable ruthenium 100 If recovery of usable ruthenium is a goal an extremely pure technetium target is needed if small traces of the minor actinides such as americium and curium are present in the target they are likely to undergo fission and form more fission products which increase the radioactivity of the irradiated target The formation of ruthenium 106 half life 374 days from the fresh fission is likely to increase the activity of the final ruthenium metal which will then require a longer cooling time after irradiation before the ruthenium can be used The actual separation of technetium 99 from spent nuclear fuel is a long process During fuel reprocessing it comes out as a component of the highly radioactive waste liquid After sitting for several years the radioactivity reduces to a level where extraction of the long lived isotopes including technetium 99 becomes feasible A series of chemical processes yields technetium 99 metal of high purity Neutron activation Molybdenum 99 which decays to form technetium 99m can be formed by the neutron activation of molybdenum 98 When needed other technetium isotopes are not produced in significant quantities by fission but are manufactured by neutron irradiation of parent isotopes for example technetium 97 can be made by neutron irradiation of ruthenium 96 Particle accelerators The feasibility of technetium 99m production with the 22 MeV proton bombardment of a molybdenum 100 target in medical cyclotrons following the reaction 100Mo p 2n 99mTc was demonstrated in 1971 The recent shortages of medical technetium 99m reignited the interest in its production by proton bombardment of isotopically enriched gt 99 5 molybdenum 100 targets Other techniques are being investigated for obtaining molybdenum 99 from molybdenum 100 via n 2n or g n reactions in particle accelerators ApplicationsNuclear medicine and biology Technetium scintigraphy of a neck of Graves disease patient Technetium 99m m indicates that this is a metastable nuclear isomer is used in radioactive isotope medical tests For example technetium 99m is a radioactive tracer that medical imaging equipment tracks in the human body It is well suited to the role because it emits readily detectable 140 keV gamma rays and its half life is 6 01 hours meaning that about 94 of it decays to technetium 99 in 24 hours The chemistry of technetium allows it to be bound to a variety of biochemical compounds each of which determines how it is metabolized and deposited in the body and this single isotope can be used for a multitude of diagnostic tests More than 50 common radiopharmaceuticals are based on technetium 99m for imaging and functional studies of the brain heart muscle thyroid lungs liver gall bladder kidneys skeleton blood and tumors The longer lived isotope technetium 95m with a half life of 61 days is used as a radioactive tracer to study the movement of technetium in the environment and in plant and animal systems Industrial and chemical Technetium 99 decays almost entirely by beta decay emitting beta particles with consistent low energies and no accompanying gamma rays Moreover its long half life means that this emission decreases very slowly with time It can also be extracted to a high chemical and isotopic purity from radioactive waste For these reasons it is a U S National Institute of Standards and Technology NIST standard beta emitter and is used for equipment calibration Technetium 99 has also been proposed for optoelectronic devices and nanoscale nuclear batteries Like rhenium and palladium technetium can serve as a catalyst In processes such as the dehydrogenation of isopropyl alcohol it is a far more effective catalyst than either rhenium or palladium However its radioactivity is a major problem in safe catalytic applications When steel is immersed in water adding a small concentration 55 ppm of potassium pertechnetate VII to the water protects the steel from corrosion even if the temperature is raised to 250 C 523 K For this reason pertechnetate has been used as an anodic corrosion inhibitor for steel although technetium s radioactivity poses problems that limit this application to self contained systems While for example CrO2 4 can also inhibit corrosion it requires a concentration ten times as high In one experiment a specimen of carbon steel was kept in an aqueous solution of pertechnetate for 20 years and was still uncorroded The mechanism by which pertechnetate prevents corrosion is not well understood but seems to involve the reversible formation of a thin surface layer passivation One theory holds that the pertechnetate reacts with the steel surface to form a layer of technetium dioxide which prevents further corrosion the same effect explains how iron powder can be used to remove pertechnetate from water The effect disappears rapidly if the concentration of pertechnetate falls below the minimum concentration or if too high a concentration of other ions is added As noted the radioactive nature of technetium 3 MBq L at the concentrations required makes this corrosion protection impractical in almost all situations Nevertheless corrosion protection by pertechnetate ions was proposed but never adopted for use in boiling water reactors Precautions and biological effectTechnetium plays no natural biological role and is not normally found in the human body 25 Technetium is produced in quantity by nuclear fission and spreads more readily than many radionuclides It appears to have low chemical toxicity For example no significant change in blood formula body and organ weights and food consumption could be detected for rats which ingested up to 15 mg of technetium 99 per gram of food for several weeks In the body technetium quickly gets converted to the stable TcO 4 ion which is highly water soluble and quickly excreted The radiological toxicity of technetium per unit of mass is a function of compound type of radiation for the isotope in question and the isotope s half life All isotopes of technetium must be handled carefully The most common isotope technetium 99 is a weak beta emitter such radiation is stopped by the walls of laboratory glassware The primary hazard when working with technetium is inhalation of dust such radioactive contamination in the lungs can pose a significant cancer risk For most work careful handling in a fume hood is sufficient and a glove box is not needed Being close to noble metals technetium is not very susceptible to corrosion and during biofouling its ability to self cleanse has been recorded due to its radiotoxic effect on biota NotesThe most stable isotope of technetium cannot be determined based on existing data due to overlapping measurement uncertainties for the half lives of the two longest lived isotopes The half life of 97Tc with an uncertainty corresponding to one standard deviation is 4 21 0 16 million years while that for 98Tc is 4 2 0 3 million years these measurements have overlapping confidence intervals Irregular crystals and trace impurities raise this transition temperature to 11 2 K for 99 9 pure technetium powder As of 2005 update technetium 99 in the form of ammonium pertechnetate is available to holders of an Oak Ridge National Laboratory permit 25 The anaerobic spore forming bacteria in the Clostridium genus are able to reduce Tc VII to Tc IV Clostridia bacteria play a role in reducing iron manganese and uranium thereby affecting these elements solubility in soil and sediments Their ability to reduce technetium may determine a large part of mobility of technetium in industrial wastes and other subsurface environments ReferencesKondev F G Wang M Huang W J Naimi S Audi G 2021 The NUBASE2020 evaluation of nuclear properties PDF Chinese Physics C 45 3 030001 doi 10 1088 1674 1137 abddae Arblaster John W 2018 Selected Values of the Crystallographic Properties of Elements Materials Park Ohio ASM International ISBN 978 1 62708 155 9 Greenwood Norman N Earnshaw Alan 1997 Chemistry of the Elements 2nd ed Butterworth Heinemann p 28 ISBN 978 0 08 037941 8 Mattolat C Gottwald T Raeder S Rothe S Schwellnus F Wendt K Thorle Pospiech P Trautmann N 24 May 2010 Determination of the first ionization potential of technetium Physical Review A 81 052513 doi 10 1103 PhysRevA 81 052513 Weast Robert 1984 CRC Handbook of Chemistry and Physics Boca Raton Florida Chemical Rubber Company 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Company Retrieved 24 May 2024 Emsley 2001 p 425 Ch 14 Separation Techniques PDF EPA 402 b 04 001b 14 final US Environmental Protection Agency July 2004 Archived PDF from the original on 8 March 2014 Retrieved 4 August 2008 Schwochau 2000 p 91 Desmet G Myttenaere C 1986 Technetium in the environment Springer pp 392 395 ISBN 978 0 85334 421 6 Schwochau 2000 pp 371 381 Schwochau 2000 p 40 Popova Nadezhda M Volkov Mikhail A Safonov Alexey V Panfilov Oleg E German Konstantin E 25 November 2024 Long term durability of Tc bulk and Tc coatings in various environmental conditions Biofouling 40 10 785 800 Bibcode 2024Biofo 40 785P doi 10 1080 08927014 2024 2413633 ISSN 0892 7014 PMID 39477809 S Garg and B Maheshwari et al Atomic Data and Nuclear Data Tables 150 101546 2023 https doi org 10 1016 j adt 2022 101546BibliographyEmsley J 2001 Nature s Building Blocks An A Z Guide to the Elements Oxford England UK Oxford University Press ISBN 978 0 19 850340 8 Greenwood N N Earnshaw A 1997 Chemistry of the Elements 2nd ed Oxford UK Butterworth Heinemann ISBN 978 0 7506 3365 9 Hammond C R 2004 The Elements Handbook of Chemistry and Physics 81st ed Boca Raton FL CRC press ISBN 978 0 8493 0485 9 Scerri Eric 2013 A Tale of Seven Elements Oxford UK Oxford University Press ISBN 9780195391312 Schwochau K 2000 Technetium Chemistry and radiopharmaceutical applications Weinheim DE Wiley VCH ISBN 978 3 527 29496 1 via Google books Further readingWikimedia Commons has media related to Technetium Choppin G Liljenzin J O Rydberg J 2002 Nuclear Mass and Stability Radiochemistry and Nuclear Chemistry 3rd ed Butterworth Heinemann pp 41 57 ISBN 978 0 7506 7463 8 via Google books Cotton F A Wilkinson G Murillo C A Bochmann M 1999 Advanced Inorganic Chemistry 6th ed New York NY John Wiley amp Sons ISBN 978 0 471 19957 1 Scerri E R 2007 The Periodic Table Its story and its significance Oxford University Press ISBN 978 0 19 530573 9 Wilson B J ed 1966 The Radiochemical Manual 2nd ed AEA Technology ISBN 978 0 7058 1768 4 Technetium EnvironmentalChemistry com Retrieved 1 December 2002 Nuclide chart Report National Nuclear Data Center Brookhaven NY Brookhaven National Laboratory Archived from the original on 28 April 2021 External linksLook up technetium in Wiktionary the free dictionary Technetium video The Periodic Table of Videos Nottingham UK University of Nottingham