Hassium: Difference between revisions

Hassium, ₁₀₈Hs

Hassium
Pronunciation	/ˈhæsiəm/ ⓘ[1] ​(HASS-ee-əm)
Mass number	[271] (data not decisive)[a]
Hassium in the periodic table
Hydrogen Helium Lithium Beryllium Boron Carbon Nitrogen Oxygen Fluorine Neon Sodium Magnesium Aluminium Silicon Phosphorus Sulfur Chlorine Argon Potassium Calcium Scandium Titanium Vanadium Chromium Manganese Iron Cobalt Nickel Copper Zinc Gallium Germanium Arsenic Selenium Bromine Krypton Rubidium Strontium Yttrium Zirconium Niobium Molybdenum Technetium Ruthenium Rhodium Palladium Silver Cadmium Indium Tin Antimony Tellurium Iodine Xenon Caesium 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 Radon Francium 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 Os ↑ Hs ↓ (Uhb) bohrium ← hassium → meitnerium
Atomic number (Z)	108
Group	group 8
Period	period 7
Block	d-block
Electron configuration	[Rn] 5f14 6d6 7s2[4]
Electrons per shell	2, 8, 18, 32, 32, 14, 2
Physical properties
Phase at STP	solid (predicted)[5]
Density (near r.t.)	27–29 g/cm3 (predicted)[6][7]
Atomic properties
Oxidation states	(+2), (+3), (+4), (+6), +8[8][9][10] (parenthesized: prediction)
Ionization energies	1st: 730 kJ/mol 2nd: 1760 kJ/mol 3rd: 2830 kJ/mol (more) (predicted)[11]
Atomic radius	empirical: 126 pm (estimated)[12]
Covalent radius	134 pm (estimated)[13]
Other properties
Natural occurrence	synthetic
Crystal structure	​hexagonal close-packed (hcp) (predicted)[5]
CAS Number	54037-57-9
History
Naming	after Hassia, Latin for Hesse, Germany, where it was discovered[14]
Discovery	Gesellschaft für Schwerionenforschung (1984)
Isotopes of hassium v e
Main isotopes[15] Decay abun­dance half-life (t1/2) mode pro­duct 269Hs synth 12 s α 265Sg 270Hs synth 7.6 s α 266Sg 271Hs synth 46 s α 267Sg 277mHs synth 130 s SF –
Category: Hassium view talk edit | references

Hassium is a chemical element with symbol Hs and atomic number 108, named after the German state of Hesse. It is a synthetic element (an element that can be created in a laboratory but is not found in nature) and radioactive; the most stable known isotope, ²⁶⁹Hs, has a half-life of approximately 9.7 seconds, although an unconfirmed metastable state, ^277mHs, may have a longer half-life of about 11 minutes. More than 100 atoms of hassium have been synthesized to date.^[16]

In the periodic table of the elements, it is a d-block transactinide element. It is a member of the 7th period and belongs to the group 8 elements. Chemistry experiments have confirmed that hassium behaves as the heavier homologue to osmium in group 8. The chemical properties of hassium are characterized only partly, but they compare well with the chemistry of the other group 8 elements. In bulk quantities, hassium is expected to be a silvery metal that reacts readily with oxygen in the air, forming a volatile tetroxide.

History

See also: Discovery of the chemical elements

2011 Hessentag fair and festival in Hesse

The synthesis of element 108 was first attempted in 1978 by a Russian research team led by Yuri Oganessian and Vladimir Utyonkov at the Joint Institute for Nuclear Research (JINR) in Dubna, using reactions that would generate the isotopes hassium-270 and hassium-264. The data was uncertain and they carried out new experiments on hassium five years later, where these two isotopes as well as hassium-263 were produced; the hassium-264 experiment was repeated again and confirmed in 1984.^[16]

Hassium was officially discovered in 1984 by a German research team led by Peter Armbruster and Gottfried Münzenberg at the Institute for Heavy Ion Research (Gesellschaft für Schwerionenforschung) in Darmstadt. The team bombarded a target of lead-208 with accelerated nuclei of iron-58 to produce 3 atoms of the isotope hassium-265.^[17]

Due to this issue, a controversy arose over who should be recognized as the official discoverer of the element. The IUPAC/IUPAP Transfermium Working Group (TWG) recognised the GSI collaboration as official discoverers in their 1992 report. They stated that the GSI collaboration was "more detailed and, of itself, carries conviction", and that while the combined data from Dubna and Darmstadt confirmed that hassium had been synthesized, the major credit was awarded to the GSI. This statement came in spite of the combined data also supporting the Russian 1983 discovery claim and the TWG also acknowledging that "very probably element 108 played a role in the Dubna experiment."^[16][18]

The name hassium was proposed by Peter Armbruster and his colleagues, the officially recognised German discoverers, in 1992, derived from the Latin name (Hassia) for the German state of Hesse where the institute is located.^[16][19] Using Mendeleev's nomenclature for unnamed and undiscovered elements, hassium should be known as eka-osmium or dvi-ruthenium. In 1979, during the Transfermium Wars (but before the synthesis of hassium), IUPAC published recommendations according to which the element was to be called unniloctium (with the corresponding symbol of Uno),^[20] a systematic element name as a placeholder, until the element was discovered (and the discovery then confirmed) and a permanent name was decided on. The recommendations were mostly ignored among scientists, who either called it "element 108", with the symbol of (108) or even simply 108, or used the proposed name "hassium".^[21]

In 1994 a committee of IUPAC recommended that element 108 be named hahnium (Hn) after the German physicist Otto Hahn, after an older suggestion of ottohahnium (Oh)^[22] in spite of the long-standing convention to give the discoverer the right to suggest a name,^[23] so that elements named after Hahn and Lise Meitner (meitnerium) would be next to each other, honoring their joint discovery of nuclear fission.^[22] This was because they felt that Hesse did not merit an element being named after it.^[16] After protests from the German discoverers and the American Chemical Society, IUPAC relented and the name hassium (Hs) was adopted internationally in 1997.^[16][24]

Natural occurrence

Molybdenite

Hassium is not known to occur naturally on Earth; the half-lives of all its known isotopes are short enough that no primordial hassium would have survived to the present day. However, this does not rule out the possibility of as yet unknown longer-lived isotopes or nuclear isomers existing, some of which could, if long-lived enough, still exist in trace quantities today. In the early 1960s, it was predicted that long-lived deformed isomers of hassium might occur naturally on Earth in trace quantities. This was theorized in order to explain the extreme radiation damage in some minerals that could not have been caused by any known natural radioisotopes, but could have been caused by superheavy elements.^[16]

In 1963, Soviet scientist Victor Cherdyntsev, who had previously claimed the existence of primordial curium-247,^[25] claimed to have discovered element 108 (specifically, the ²⁶⁷Hs isotope, which supposedly had a half life of 400 to 500 million years) in natural molybdenite and suggested the name sergenium (symbol Sg; at the time, this symbol had not yet been taken by seaborgium) for it, after the ancient city of Serik along the Silk Road in Kazakhstan where his molybdenite samples came from.^[16] His rationale for claiming that sergenium was the heavier homologue to osmium was that minerals supposedly containing sergenium formed volatile oxides when boiled in nitric acid, similarly to osmium. His findings were however criticized by V. M. Kulakov on the grounds that some of the properties Cherdyntsev claimed sergenium had were inconsistent with the then-current nuclear physics.^[26]

The chief questions raised by Kulakov were that the claimed alpha decay energy of sergenium was many orders of magnitude lower than expected and the half-life given was eight orders of magnitude shorter than what would be predicted for a nuclide alpha decaying with the claimed decay energy, but at the same time a corrected half-life in the region of 10¹⁶ years would be impossible as it would imply that the samples contained about 100 milligrams of sergenium. However, more recently, it has been suggested that the observed alpha decay with energy 4.5 MeV could be due to a low-energy and strongly enhanced transition between different hyperdeformed states of a hassium isotope around ²⁷¹Hs, thus suggesting that the existence of superheavy elements in nature was at least possible, although unlikely.^[27]

In 2004, the Joint Institute for Nuclear Research conducted a search for natural hassium. This was done underground to avoid interference and false positives from cosmic rays, but no results have been released, strongly implying that no natural hassium was found. The possible extent of primordial hassium on Earth is uncertain; it might now only exist in traces, or could even have completely decayed by now after having caused the radiation damage long ago.^[16]

In 2006, it was hypothesized that an isomer of ²⁷¹Hs might have a half-life of around (2.5±0.5)×10⁸ y, which would explain the observation of alpha particles with energies of around 4.4 MeV in some samples of molybdenite and osmiride.^[28] This isomer of ²⁷¹Hs could be produced from the beta decay of ²⁷¹Bh and ²⁷¹Sg, which, being homologous to rhenium and molybdenum respectively, should occur in molybdenite along with rhenium and molybdenum if they occurred in nature. Since hassium is homologous to osmium, it should also occur along with osmium in osmiride if it occurred in nature. However, the decay chains of these isotopes are very hypothetical and the predicted half-life of this hypothetical hassium isomer is not long enough for any sufficient quantity to remain on Earth.^[28] It is possible that more ²⁷¹Hs may be deposited on the Earth as the Solar System travels through the spiral arms of the Milky Way, which would also explain excesses of plutonium-239 found on the floors of the Pacific Ocean and the Gulf of Finland, but minerals enriched with ²⁷¹Hs are predicted to also have to have excesses of uranium-235 and lead-207, and would have different proportions of elements that are formed during spontaneous fission, such as krypton, zirconium, and xenon. Thus, the occurrence of hassium in nature in minerals such as molybdenite and osmiride is theoretically possible, but highly unlikely.^[28]

Isotopes

Main article: Isotopes of hassium

List of hassium isotopes

Isotope	Half-life [29]	Decay mode[29]	Discovery year	Reaction
263Hs	0.74 ms	α, SF	2008	208Pb(56Fe,n)[30]
264Hs	~0.8 ms	α, SF	1986	207Pb(58Fe,n)[31]
265Hs	1.9 ms	α, SF	1984	208Pb(58Fe,n)[17]
265mHs	0.3 ms	α	1984	208Pb(58Fe,n)[17]
266Hs	2.3 ms	α, SF	2000	270Ds(—,α)[32]
267Hs	52 ms	α, SF	1995	238U(34S,5n)[33]
267mHs	0.8 s	α	1995	238U(34S,5n)[33]
268Hs	0.4 s	α	2009	238U(34S,4n)
269Hs	3.6 s	α	1996	277Cn(—,2α)[34]
269mHs	9.7 s	α	2004	248Cm(26Mg,5n)[35]
270Hs	3.6 s	α	2004	248Cm(26Mg,4n)[35]
271Hs	~4 s	α	2004	248Cm(26Mg,3n)[36]
272Hs	2.1? s[37]	α, SF ?	unknown	—
273Hs	0.24 s	α	2004	285Fl(—,3α)[38]
274Hs	1? min	α, SF ?	unknown	—
275Hs	0.15 s	α	2003	287Fl(—,3α)[39]
276Hs	1? h	α, SF ?	unknown	—
277Hs	2 s	α	2009	289Fl(—,3α)[40]
277mHs ?	~11 min ?	α	1999	289Fl(—,3α)[41]

Hassium has no stable or naturally-occurring isotopes. Several radioactive isotopes have been synthesized in the laboratory, either by fusing two atoms or by observing the decay of heavier elements. Twelve different isotopes have been reported with atomic masses from 263 to 277 (with the exceptions of 272, 274, and 276), four of which, hassium-265, hassium-267, hassium-269, and hassium-277, have known metastable states (although that of hassium-277 is unconfirmed). Most of these decay predominantly through alpha decay, but some also undergo spontaneous fission.^[29][38]

The lighter isotopes usually have shorter half-lives; half-lives of under 1 ms for ²⁶³Hs, ²⁶⁴Hs, and ^265mHs were observed. ²⁶⁵Hs and ²⁶⁶Hs are more stable at around 2 ms, ²⁶⁷Hs has a half-life of about 50 ms, ^267mHs, ²⁶⁸Hs, ²⁷³Hs, and ²⁷⁵Hs live between 0.1 and 1 second, and ²⁶⁹Hs, ^269mHs, ²⁷⁰Hs, ²⁷¹Hs, and ²⁷⁷Hs are more stable, at between 1 and 30 seconds. The unconfirmed ^277mHs may have a half-life of about 11 minutes. The unknown isotopes ²⁷⁴Hs and ²⁷⁶Hs are predicted to have longer half-lives of around 1 minute and 1 hour respectively. Before its discovery, ²⁷¹Hs was also predicted to have a long half-life of 40 seconds, but it was found to have a shorter half-life of only about 4 seconds.^[29]

The lightest isotopes were synthesized by direct fusion between two lighter nuclei and as decay products. The heaviest isotope produced by direct fusion is ²⁷¹Hs; heavier isotopes have only been observed as decay products of elements with larger atomic numbers. In 1999, American scientists at the University of California, Berkeley, announced that they had succeeded in synthesizing three atoms of ²⁹³118.^[42] These parent nuclei were reported to have successively emitted three alpha particles to form hassium-273 nuclei, which were claimed to have undergone an alpha decay, emitting alpha particles with decay energies of 9.78 and 9.47 MeV and half-life 1.2 s, but their claim was retracted in 2001.^[43] The isotope, however, was produced in 2010 by the same team. The new data matched the previous (fabricated)^[44] data.^[38]

²⁷⁰Hs: prospects for a deformed doubly magic nucleus

According to calculations, 108 is a proton magic number for deformed nuclei (nuclei that are far from spherical), and 162 is a neutron magic number for deformed nuclei. This means that such nuclei are permanently deformed in their ground state but have high, narrow fission barriers to further deformation and hence relatively long life-times to spontaneous fission.^[45][46] The spontaneous fission half-lives in this region are typically reduced by a factor of 10⁹ in comparison with those in the vicinity of the spherical doubly magic nucleus ²⁹⁸Fl, caused by the narrower fission barrier for such deformed nuclei.^[47] Hence, the nucleus ²⁷⁰Hs has promise as a deformed doubly magic nucleus. Experimental data from the decay of the darmstadtium (Z=110) isotopes ²⁷¹Ds and ²⁷³Ds provides strong evidence for the magic nature of the N=162 sub-shell. The recent synthesis of ²⁶⁹Hs, ²⁷⁰Hs, and ²⁷¹Hs also fully support the assignment of N=162 as a magic number. In particular, the low decay energy for ²⁷⁰Hs is in complete agreement with calculations.^[45][46][47]

Evidence for the magicity of the Z=108 proton shell can be obtained from two sources: the variation in the partial spontaneous fission half-lives for isotones and the large gap in the alpha Q value for isotonic nuclei of hassium and darmstadtium.^[47] For spontaneous fission, it is necessary to measure the half-lives for the isotonic nuclei ²⁶⁸Sg, ²⁷⁰Hs and ²⁷²Ds.^[47] Since the isotopes ²⁶⁸Sg and ²⁷²Ds are not currently known,^[29] and fission of ²⁷⁰Hs has not been measured,^[29][46] this method cannot be used to date to confirm the stabilizing nature of the Z=108 shell. However, good evidence for the magicity of the Z=108 shell can be deemed from the large differences in the alpha decay energies measured for ²⁷⁰Hs, ²⁷¹Ds and ²⁷³Ds.^[45][46][47] More conclusive evidence would come from the determination of the decay energy for the unknown nucleus ²⁷²Ds.^[47]

Predicted properties

Various calculations show that hassium should be the heaviest known group 8 element, consistent with the periodic law. Its properties should generally match those expected for a heavier homologue of osmium, with a few deviations arising from relativistic effects.

Physical and atomic

The previous members of group 8 have relatively high melting points (Fe, 1538 °C; Ru, 2334 °C; Os, 3033 °C). Much like them, hassium is predicted to be a solid at room temperature,^[48] although the melting point of hassium has not been precisely calculated. Hassium should crystallize in the hexagonal close-packed structure (^c/_a = 1.59), similarly to its lighter congener osmium.^[48] Pure metallic hassium is calculated to have a bulk modulus (resistance to uniform compression) comparable to that of diamond^[48][49] (442 GPa).^[50] Hassium is expected to have a bulk density of 40.7 g/cm³, the highest of any of the 118 known elements and nearly twice the density of osmium,^[21] the most dense measured element,^[51] at 22.61 g/cm³.^[52] This results from hassium's high atomic weight, the lanthanide and actinide contractions, and relativistic effects, although production of enough hassium to measure this quantity would be impractical, and the sample would quickly decay.^[21] Osmium is the densest element of the first 6 periods, and its heavier congener hassium is expected to be the densest element of the first 7 periods.^[21][51]

The atomic radius of hassium is expected to be around 126 pm.^[21] Due to the relativistic stabilization of the 7s orbital and destabilization of the 6d orbital, the Hs⁺ ion is predicted to have an electron configuration of [Rn] 5f¹⁴ 6d⁵ 7s², giving up a 6d electron instead of a 7s electron, which is the opposite of the behavior of its lighter homologues. On the other hand, the Hs²⁺ ion is expected to have an electron configuration of [Rn] 5f¹⁴ 6d⁵ 7s¹, analogous to that calculated for the Os²⁺ ion.^[21]

Chemical

Stable oxidation states of the group 8 elements^[53]

Element	Stable oxidation states
iron			+6			+3	+2
ruthenium	+8		+6	+5	+4	+3	+2
osmium	+8			+5	+4	+3	+2

Hassium is the sixth member of the 6d series of transition metals and is expected to be much like the platinum group metals.^[54] Calculations on its ionization potentials, atomic radius, as well as radii, orbital energies, and ground levels of its ionized states are similar to that of osmium, implying that hassium's properties would resemble those of the other group 8 elements, iron, ruthenium, and osmium.^[21][55] Some of these properties were confirmed by gas-phase chemistry experiments.^[37][56][57] The group 8 elements portray a wide variety of oxidation states, but ruthenium and osmium readily portray their group oxidation state of +8 (the highest known oxidation state for any element, which is very rare for other elements) and this state becomes more stable as the group is descended.^[53][58][59] Thus hassium is expected to form a stable +8 state.^[56] Analogously to its lighter congeners, hassium is expected to also show other stable lower oxidation states, such as +6, +5, +4, +3, and +2.^[16][21][10]

The group 8 elements show a very distinctive oxide chemistry which allows extrapolations to be made easily for hassium. All the lighter members have known or hypothetical tetroxides, MO₄.^[60] Their oxidising power decreases as one descends the group. FeO₄ is not known due to its extraordinarily large electron affinity (the amount of energy released when an electron is added to a neutral atom or molecule to form a negative ion)^[61] which results in the formation of the well-known oxoanion ferrate(VI), FeO²⁻
₄.^[62] Ruthenium tetroxide, RuO₄, formed by oxidation of ruthenium(VI) in acid, readily undergoes reduction to ruthenate(VI), RuO²⁻
₄.^[63][64] Oxidation of ruthenium metal in air forms the dioxide, RuO₂.^[65] In contrast, osmium burns to form the stable tetroxide, OsO₄,^[66][67] which complexes with the hydroxide ion to form an osmium(VIII) -ate complex, [OsO₄(OH)₂]²⁻.^[68] Therefore, eka-osmium properties for hassium should be demonstrated by the formation of a stable, very volatile tetroxide HsO₄,^{[16][21][37][57][58]} which undergoes complexation with hydroxide to form a hassate(VIII), [HsO₄(OH)₂]²⁻.^[69] Ruthenium tetroxide and osmium tetroxide are both volatile, due to their symmetrical tetrahedral molecular geometry and their being charge-neutral; hassium tetroxide should similarly be a very volatile solid. The trend of the volatilities of the group 8 tetroxides is expected to be RuO₄ < OsO₄ ≤ HsO₄, based on the calculated enthalpies of adsorption (the energy required for the adhesion of atoms, molecules, or ions from a gas, liquid, or dissolved solid to a surface) for the three compounds;^[21][70] this trend remains the same whether or not relativistic effects are taken into account.^[70]

Experimental atomic gas phase chemistry

Despite the fact that the selection of a volatile hassium compound (hassium tetroxide) for gas-phase chemical studies was clear from the beginning,^[21][58] the chemical characterization of hassium was considered a difficult task for a long time.^[58] Although hassium isotopes were first synthesized in 1984, it was not until 1996 that a hassium isotope long-lived enough to allow chemical studies to be performed was synthesized. Unfortunately, this hassium isotope, ²⁶⁹Hs, was then synthesized indirectly from the decay of ²⁷⁷Cn;^[58] not only are indirect synthesis methods not favourable for chemical studies,^[21] but also the reaction that produced the isotope ²⁷⁷Cn had a low yield (its cross-section was only 1 pb),^[58] and thus did not provide enough hassium atoms for a chemical investigation.^[54] The direct synthesis of ²⁶⁹Hs and ²⁷⁰Hs in the reaction ²⁴⁸Cm(²⁶Mg,xn)^274−xHs (x = 4 or 5) appeared more promising, as the cross-section for this reaction was somewhat larger, at 7 pm.^[21][58] However, this yield was still around ten times lower than that for the reaction used for the chemical characterization of bohrium.^[58] New techniques for irradiation, separation, and detection had to be introduced before hassium could be successfully characterized chemically as a typical member of group 8 in early 2001.^[21][58]

Ruthenium and osmium have very similar chemistry due to the lanthanide contraction, but iron shows some differences from them: for example, although ruthenium and osmium form stable tetroxides in which the metal is in the +8 oxidation state, iron does not.^[58][60] Consequently, in preparation for the chemical characterization of hassium, researches focused on ruthenium and osmium rather than iron,^[58] as hassium was expected to also be similar to ruthenium and osmium due to the actinide contraction.^[21] However, in the planned experiment to study hassocene (Hs(C₅H₅)₂), ferrocene may also be used for comparison along with ruthenocene and osmocene.^[10]

File:Hassium chemistry experiment setup.png

Schematic diagram of the IVO-COLD system, which was used to study the gas-phase properties of hassium tetroxide (HsO₄) and its lighter homologues ruthenium tetroxide (RuO₄) and osmium tetroxide (OsO₄).^[21][71]

In ferrocene, the cyclopentadienyl rings are in a staggered conformation.

In ruthenocene and osmocene, the cyclopentadienyl rings are in an eclipsed conformation. Hassocene is predicted to also have this structure.

The first chemistry experiments were performed using gas thermochromatography in 2001, using ¹⁷²Os and ¹⁷³Os as a reference. During the experiment, 5 hassium atoms were synthesized using the reaction ²⁴⁸Cm(²⁶Mg,5n)²⁶⁹Hs. They were then thermalized and oxidized in a mixture of helium and oxygen gas to form the tetroxide.

²⁶⁹Hs + 2 O₂ → ²⁶⁹HsO₄

The measured deposition temperature indicated that hassium(VIII) oxide is less volatile than osmium tetroxide, OsO₄, and places hassium firmly in group 8.^[21][37][57] However, the enthalpy of adsorption for HsO₄ measured, (−46 ± 2) kJ/mol, was significantly lower than what was predicted, (−36.7 ± 1.5) kJ/mol, indicating that OsO₄ was more volatile than HsO₄, contradicting earlier calculations, which implied that they should have very similar volatilities. For comparison, the value for OsO₄ is (−39 ± 1) kJ/mol.^[21] It is possible that hassium tetroxide interacts differently with the different chemicals (silicon nitride and silicon dioxide) used for the detector; further research is required, including more accurate measurements of the nuclear properties of ²⁶⁹Hs and comparisons with RuO₄ in addition to OsO₄.^[21]

In order to further probe the chemistry of hassium, scientists decided to assess the reaction between hassium tetroxide and sodium hydroxide to form sodium hassate(VIII), a reaction well-known with osmium. In 2004, scientists announced that they had succeeded in carrying out the first acid-base reaction with a hassium compound, forming sodium hassate(VIII):^[69]

HsO
₄ + 2 NaOH → Na
₂[HsO
₄(OH)
₂]

The team from the University of Mainz are planning to study the electrodeposition of hassium atoms using the new TASCA facility at the GSI. The current aim is to use the reaction ²²⁶Ra(⁴⁸Ca,4n)²⁷⁰Hs.^[72] In addition, scientists at the GSI are hoping to utilize TASCA to study the synthesis and properties of the hassium(II) compound hassocene, Hs(C₅H₅)₂, using the reaction ²²⁶Ra(⁴⁸Ca,xn). This compound is analogous to the lighter ferrocene, ruthenocene, and osmocene, and is expected to have the two cyclopentadienyl rings in an eclipsed conformation like ruthenocene and osmocene and not in a staggered conformation like ferrocene.^[10] Hassocene was chosen because it has hassium in the low formal oxidation state of +2 (although the bonding between the metal and the rings is mostly covalent in metallocenes) rather than the high +8 state which has been investigated, and relativistic effects were expected to be stronger in the lower oxidation state.^[10] Many metals in the periodic table form metallocenes, so that trends could be more easily determined, and the highly symmetric structure of hassocene and its low number of atoms also make relativistic calculations easier. Hassocene should be a stable and highly volatile compound.^[10]

References

1. Hassium. The Periodic Table of Videos. University of Nottingham. January 28, 2011. Retrieved October 19, 2012.
2. "Radioactive Elements". Commission on Isotopic Abundances and Atomic Weights. 2018. Retrieved 2020-09-20.
3. Audi et al. 2017, p. 030001-136.
4. Hoffman, Lee & Pershina 2006, p. 1672.
5. Östlin, A. (2013). "Transition metals". Electronic Structure Studies and Method Development for Complex Materials (PDF) (Licentiate). pp. 15–16. Retrieved 24 October 2019.
6. Gyanchandani, Jyoti; Sikka, S. K. (10 May 2011). "Physical properties of the 6 d -series elements from density functional theory: Close similarity to lighter transition metals". Physical Review B. 83 (17): 172101. doi:10.1103/PhysRevB.83.172101.
7. Kratz; Lieser (2013). Nuclear and Radiochemistry: Fundamentals and Applications (3rd ed.). p. 631.
8. Hoffman, Darleane C.; Lee, Diana M.; Pershina, Valeria (2006). "Transactinides and the future elements". In Morss; Edelstein, Norman M.; Fuger, Jean (eds.). The Chemistry of the Actinide and Transactinide Elements (3rd ed.). Dordrecht, The Netherlands: Springer Science+Business Media. p. 1691. ISBN 978-1-4020-3555-5.
9. Fricke, Burkhard (1975). "Superheavy elements: a prediction of their chemical and physical properties". Recent Impact of Physics on Inorganic Chemistry. Structure and Bonding. 21: 89–144. doi:10.1007/BFb0116498. ISBN 978-3-540-07109-9. Retrieved 4 October 2013.
10. Düllmann, C. E. (2008). Investigation of group 8 metallocenes @ TASCA (PDF). 7th Workshop on Recoil Separator for Superheavy Element Chemistry TASCA 08. Archived from the original (PDF) on 30 April 2014. Retrieved 28 August 2020.
11. Hoffman, Lee & Pershina 2006, p. 1673.
12. Hoffman, Lee & Pershina 2006, p. 1691.
13. Robertson, M. (2011). "Chemical Data: Hassium". Visual Elements Periodic Table. Royal Society of Chemistry. Retrieved 28 November 2012.
14. Emsley, J. (2011). Nature's Building Blocks: An A–Z Guide to the Elements (New ed.). Oxford University Press. pp. 215–217. ISBN 978-0-19-960563-7.
15. Kondev, 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.
16. Cite error: The named reference emsley was invoked but never defined (see the help page).
17. Münzenberg, G.; Armbruster, P.; Folger, H.; Heßberger, F. P.; Hofmann, S.; Keller, J.; Poppensieker, K.; Reisdorf, W.; Schmidt, K.-H.; et al. (1984). "The identification of element 108" (PDF). Zeitschrift für Physik A. 317 (2): 235–236. Bibcode:1984ZPhyA.317..235M. doi:10.1007/BF01421260. Retrieved 20 October 2012.
18. Attention: This template ({{cite doi}}) is deprecated. To cite the publication identified by doi:10.1351/pac199365081757, please use {{cite journal}} (if it was published in a bona fide academic journal, otherwise {{cite report}} with |doi=10.1351/pac199365081757 instead. (Note: for Part I see Pure Appl. Chem., Vol. 63, No. 6, pp. 879–886, 1991)
19. Attention: This template ({{cite doi}}) is deprecated. To cite the publication identified by doi:10.1351/pac199365081815, please use {{cite journal}} (if it was published in a bona fide academic journal, otherwise {{cite report}} with |doi=10.1351/pac199365081815 instead.
20. Chatt, J. (1979). "Recommendations for the naming of elements of atomic numbers greater than 100". Pure and Applied Chemistry. 51 (2): 381–384. doi:10.1351/pac197951020381.
21. Cite error: The named reference Haire was invoked but never defined (see the help page).
22. "Names and symbols of transfermium elements (IUPAC Recommendations 1994)". Pure and Applied Chemistry. 66 (12): 2419. 1994. doi:10.1351/pac199466122419.
23. "IUPAC verabschiedet Namen für schwere Elemente: GSI-Vorschläge für die Elemente 107 bis 109 akzeptiert" (PDF). GSI-Nachrichten (in German). Gesellschaft für Schwerionenforschung. March 1997. Retrieved 27 March 2013. {{cite web}}: Unknown parameter |trans_title= ignored (|trans-title= suggested) (help)
24. <Please add first missing authors to populate metadata.> (1997). "Names and symbols of transfermium elements (IUPAC Recommendations 1997)". Pure and Applied Chemistry. 69 (12): 2471. doi:10.1351/pac199769122471.
25. Cherdyntsev, V. V.; Mikhailov, V. F. (1963). "The Primordial Transuranium Isotope in Nature". Geokhimiya (U.S.S.R.). 1: 3–14. Retrieved 10 August 2013.
26. Kulakov, V. M. (1970). "Has element 108 been discovered?". Soviet Atomic Energy. 29 (5): 1166–8. doi:10.1007/BF01666716.
27. Marinov, A.; Gelberg, S.; Kolb, D.; Brandt, R.; Pape, A. (2003). "New outlook on the possible existence of superheavy elements in nature". Physics of Atomic Nuclei. 66 (6): 1137–45. arXiv:nucl-ex/0210039. Bibcode:2003PAN....66.1137M. doi:10.1134/1.1586428.
28. Ivanov, A. V. (2006). "The possible existence of Hs in nature from a geochemical point of view". Physics of Particles and Nuclei Letters. 3 (3): 165. arXiv:nucl-th/0604052. Bibcode:2006PPNL....3..165I. doi:10.1134/S1547477106030046.
29. Sonzogni, Alejandro. "Interactive Chart of Nuclides". National Nuclear Data Center: Brookhaven National Laboratory. Retrieved 2008-06-06. Cite error: The named reference "nuclidetable" was defined multiple times with different content (see the help page).
30. Dragojević, I.; Gregorich, K.; Düllmann, Ch.; Dvorak, J.; Ellison, P.; Gates, J.; Nelson, S.; Stavsetra, L.; Nitsche, H. (2009). "New Isotope ²⁶³108". Physical Review C. 79: 011602. Bibcode:2009PhRvC..79a1602D. doi:10.1103/PhysRevC.79.011602. {{cite journal}}: Invalid |display-authors=9 (help)
31. Münzenberg, G.; Armbruster, P.; Berthes, G.; Folger, H.; Heßberger, F. P.; Hofmann, S.; Poppensieker, K.; Reisdorf, W.; Quint, B.; et al. (1986). "Evidence for264108, the heaviest known even-even isotope". Zeitschrift für Physik A. 324 (4): 489. Bibcode:1986ZPhyA.324..489M. doi:10.1007/BF01290935.
32. Hofmann; Heßberger, F.P.; Ackermann, D.; Antalic, S.; Cagarda, P.; Ćwiok, S.; Kindler, B.; Kojouharova, J.; Lommel, B.; et al. (2001). "The new isotope ²⁷⁰110 and its decay products ²⁶⁶Hs and ²⁶²Sg" (PDF). Eur. Phys. J. A. 10: 5–10. Bibcode:2001EPJA...10....5H. doi:10.1007/s100500170137. {{cite journal}}: Cite uses deprecated parameter |authors= (help)
33. Lazarev, Yu. A.; Lobanov, YV; Oganessian, YT; Tsyganov, YS; Utyonkov, VK; Abdullin, FS; Iliev, S; Polyakov, AN; Rigol, J; et al. (1995). "New Nuclide ²⁶⁷108 Produced by the ²³⁸U + ³⁴S Reaction". Physical Review Letters. 75 (10): 1903–1906. Bibcode:1995PhRvL..75.1903L. doi:10.1103/PhysRevLett.75.1903. PMID 10059158.
34. Hofmann, S.; et al. (1996). "The new element 112". Zeitschrift für Physik A. 354 (1): 229–230. doi:10.1007/BF02769517. {{cite journal}}: Explicit use of et al. in: |author2= (help)
35. "Decay properties of ²⁶⁹Hs and evidence for the new nuclide ²⁷⁰Hs", Turler et al., GSI Annual Report 2001. Retrieved 2008-03-01.
36. Dvorak, Jan (2006-09-25). "On the production and chemical separation of Hs (element 108)" (PDF). Technical University of Munich. Archived from the original (PDF) on 2009-02-25. Retrieved 2012-12-23.
37. Dullman, C.E. Superheavy Element Research Superheavy Element - News from GSI and Mainz. University Mainz Cite error: The named reference "Duellmann" was defined multiple times with different content (see the help page).
38. "Six New Isotopes of the Superheavy Elements Discovered " Berkeley Lab News Center". Newscenter.lbl.gov. Retrieved 2011-02-27. Cite error: The named reference "273Hs" was defined multiple times with different content (see the help page).
39. Yeremin, A. V.; Oganessian, Yu. Ts.; Popeko, A. G.; Bogomolov, S. L.; Buklanov, G. V.; Chelnokov, M. L.; Chepigin, V. I.; Gikal, B. N.; Gorshkov, V. A.; et al. (1999). "Synthesis of nuclei of the superheavy element 114 in reactions induced by ⁴⁸Ca". Nature. 400 (6741): 242. Bibcode:1999Natur.400..242O. doi:10.1038/22281.
40. Element 114 – Heaviest Element at GSI Observed at TASCA
41. Attention: This template ({{cite doi}}) is deprecated. To cite the publication identified by doi:10.1103/PhysRevLett.83.3154, please use {{cite journal}} (if it was published in a bona fide academic journal, otherwise {{cite report}} with |doi=10.1103/PhysRevLett.83.3154 instead.
42. Ninov, V.; Loveland, W.; Ghiorso, A.; Hoffman, D. C.; Lee, D. M.; Nitsche, H.; Swiatecki, W. J.; Kirbach, U. W.; Laue, C. A.; Adams, J. L.; Patin, J. B.; Shaughnessy, D. A.; Strellis, D. A.; Wilk, P. A.; et al. (1999). "Observation of Superheavy Nuclei Produced in the Reaction of The element Link does not exist. with The element Link does not exist.". Physical Review Letters. 83 (6): 1104–1107. Bibcode:1999PhRvL..83.1104N. doi:10.1103/PhysRevLett.83.1104. {{cite journal}}: Explicit use of et al. in: |author2= (help)
43. Public Affairs Department (21 July 2001). "Results of element 118 experiment retracted". Berkeley Lab. Retrieved 2008-01-18.
44. At Lawrence Berkeley, Physicists Say a Colleague Took Them for a Ride George Johnson, The New York Times, 15 October 2002
45. Mason Inman (2006-12-14). "A Nuclear Magic Trick". Physical Review Focus. Retrieved 2006-12-25.
46. Dvorak, J.; Brüchle, W.; Chelnokov, M.; Dressler, R.; Düllmann, Ch. E.; Eberhardt, K.; Gorshkov, V.; Jäger, E.; et al. (2006). "Doubly Magic Nucleus ₁₀₈²⁷⁰Hs₁₆₂". Physical Review Letters. 97 (24): 242501. Bibcode:2006PhRvL..97x2501D. doi:10.1103/PhysRevLett.97.242501. PMID 17280272.
47. Robert Smolańczuk (1997). "Properties of the hypothetical spherical superheavy nuclei". Physical Review C. 56 (2): 812–824. Bibcode:1997PhRvC..56..812S. doi:10.1103/PhysRevC.56.812.
48. Cite error: The named reference hcp was invoked but never defined (see the help page).
49. Grossman, Jeffery C.; Mizel, Ari; Côté, Michel; Cohen, Marvin L.; Louie, Steven G. (1999). "Transition metals and their carbides and nitrides: Trends in electronic and structural properties". Phys. Rev. B. 60 (9). American Physical Society: 6343–7. Bibcode:1999PhRvB..60.6343G. doi:10.1103/PhysRevB.60.6343. Retrieved 2013-08-06.
50. Cohen, Marvin (1985). "Calculation of bulk moduli of diamond and zinc-blende solids". Phys. Rev. B. 32 (12): 7988–7991. Bibcode:1985PhRvB..32.7988C. doi:10.1103/PhysRevB.32.7988.
51. Arblaster, J. W. (1989). "Densities of osmium and iridium: recalculations based upon a review of the latest crystallographic data" (PDF). Platinum Metals Review. 33 (1): 14–16.
52. J.A. Dean (ed), Lange's Handbook of Chemistry (15th Edition), McGraw-Hill, 1999; Section 3; Table 3.2 Physical Constants of Inorganic Compounds
53. Greenwood, Norman N.; Earnshaw, Alan (1997). Chemistry of the Elements (2nd ed.). Butterworth-Heinemann. ISBN 978-0-08-037941-8., pp. 27–28.
54. Griffith, W. P. (2008). "The Periodic Table and the Platinum Group Metals". Platinum Metals Review. 52 (2): 114. doi:10.1595/147106708X297486.
55. Element 108, hassium, Hs
56. Düllmann, Ch. E.; Dressler, R.; Eichler, B.; Gäggeler, H. W.; Glaus, F.; Jost, D. T.; Piguet, D.; Soverna, S.; et al. (2003). "First chemical investigation of hassium (Hs, Z=108)". Czechoslovak Journal of Physics. 53 (1 Supplement): A291–A298. Bibcode:2003CzJPS..53A.291D. doi:10.1007/s10582-003-0037-4. Retrieved 17 November 2012. {{cite journal}}: |first31= missing |last31= (help); |first32= missing |last32= (help); |first33= missing |last33= (help); |first34= missing |last34= (help)
57. "Chemistry of Hassium" (PDF). Gesellschaft für Schwerionenforschung mbH. 2002. Retrieved 2007-01-31.
58. Schädel, Matthias (2003). The Chemistry of Superheavy Elements. Springer. p. 269. ISBN 978-1402012501. Retrieved November 17, 2012.
59. Barnard, C. F. J.; Bennett (2004). "Oxidation States of Ruthenium and Osmium". Platinum Metals Review. 48 (4): 157. doi:10.1595/147106704X10801.
60. Yurii D. Perfiliev; Virender K. Sharma (2008). "Higher Oxidation States of Iron in Solid State: Synthesis and Their Mössbauer Characterization – Ferrates – ACS Symposium Series (ACS Publications)". Platinum Metals Review. 48 (4): 157. doi:10.1595/147106704X10801.
61. IUPAC, Compendium of Chemical Terminology, 2nd ed. (the "Gold Book") (1997). Online corrected version: (2006–) "Electron affinity". doi:10.1351/goldbook.E01977
62. Gutsev, Gennady L.; Khanna, S.; Rao, B.; Jena, P. (1999). "FeO₄: A unique example of a closed-shell cluster mimicking a superhalogen". Physical Review A. 59 (5): 3681. Bibcode:1999PhRvA..59.3681G. doi:10.1103/PhysRevA.59.3681.
63. Cotton, S.A. (1997). Chemistry of Precious Metals. London: Chapman and Hall. ISBN 978-0-7514-0413-5.
64. Attention: This template ({{cite doi}}) is deprecated. To cite the publication identified by doi:10.1002/047084289X.rr009.pub2, please use {{cite journal}} (if it was published in a bona fide academic journal, otherwise {{cite report}} with |doi=10.1002/047084289X.rr009.pub2 instead.
65. G.M. Brown & J.H. Butler (1997) New method for the characterization of domain morphology of polymer blends using ruthenium tetroxide staining and low voltage scanning electron microscopy (LVSEM). Polymer 38, (15), 3937–3945.
66. Mager Stellman, J. (1998). "Osmium". Encyclopaedia of Occupational Health and Safety. International Labour Organization. p. 63.34. ISBN 978-92-2-109816-4. OCLC 35279504 45066560. {{cite book}}: Check |oclc= value (help)
67. Housecroft, C. E.; Sharpe, A. G. (2004). Inorganic Chemistry (2nd ed.). Prentice Hall. pp. 671–673, 710. ISBN 978-0-13-039913-7.
68. Thompson, M. "Osmium tetroxide (OsO₄)". Bristol University. Retrieved 2012-04-07.
69. CALLISTO result
70. Pershina, V.; Bastug, T.; Fricke, B. (2005). "Relativistic effects on the electronic structure and volatility of group-8 tetroxides MO₄, where M = Ru, Os, and element 108, Hs". J. Chem. Phys. 122 (12): 124301. Bibcode:2005JChPh.122l4301P. doi:10.1063/1.1862241. PMID 15836372. Retrieved 17 November 2012.
71. Düllmann, Ch. E.; Brüchle, W.; Dressler, R.; Eberhardt, K.; Eichler, B.; Eichler, R.; Gäggeler, H. W.; Ginter, T. N.; et al. (22 August 2002). "Chemical investigation of hassium (element 108)". Nature. 418 (6900): 859–862. Bibcode:2002Natur.418..859D. doi:10.1038/nature00980. PMID 12192405. Retrieved 18 November 2012.
72. Electrodeposition experiments with hassium, J. Even et al., TASCA 08, 7th Workshop on Recoil Separator for Superheavy Element Chemistry October 31, 2008, GSI, Darmstadt, Germany

External links

• Hassium Becomes Heaviest Element To Have Its Chemistry Studied: Paul Preuss, Lawrence Berkeley National Laboratory. 5 June 2001.
• Hassium at The Periodic Table of Videos (University of Nottingham)
• WebElements.com: Hassium

Template:Chemical elements named after places
Cite error: There are <ref group=lower-alpha> tags or {{efn}} templates on this page, but the references will not show without a {{reflist|group=lower-alpha}} template or {{notelist}} template (see the help page).