Superheavy element
A superheavy element is a chemical element with an atomic number of 104 or higher, also referred to as a transactinide element, which are all synthetic and not found in nature.[1][2] These elements are produced in particle accelerators through the fusion of lighter atomic nuclei, such as bombarding heavy targets like californium or berkelium with beams of calcium ions, resulting in extremely short-lived isotopes that decay rapidly via alpha emission or spontaneous fission.[1][2][3] The first superheavy element, rutherfordium (atomic number 104), was synthesized in 1969 at the Lawrence Berkeley National Laboratory by fusing californium-249 with carbon-12 ions, marking the beginning of systematic efforts to extend the periodic table beyond the actinides.[1] Subsequent discoveries, including dubnium (105), seaborgium (106), and up to oganesson (118)—the heaviest element officially recognized as of 2016—have been achieved through international collaborations at facilities like the Joint Institute for Nuclear Research in Dubna, Russia, and GSI Helmholtz Centre in Darmstadt, Germany.[2][4][3] Due to their high atomic numbers, superheavy elements exhibit extreme instability, with half-lives typically ranging from microseconds to seconds; for instance, tennessine (117) has isotopes with half-lives of 14 to 80 milliseconds.[1] Their chemical properties are profoundly influenced by relativistic effects, where electrons near the nucleus move at speeds approaching the speed of light, altering electron orbitals and leading to unexpected behaviors, such as flerovium (114) potentially acting more like a metal than a noble gas.[3][4] Research on superheavy elements focuses on probing the "island of stability," a theoretical region around atomic numbers 114 to 126 and neutron numbers near 184, where certain isotopes might have significantly longer half-lives—potentially days or years—allowing for more detailed study of their chemistry and nuclear structure.[1][3] Ongoing experiments aim to synthesize elements beyond 118, such as element 119, using advanced accelerators to test these predictions and expand our understanding of nuclear physics at the limits of the periodic table.[3][5]Definition and Classification
Definition
Superheavy elements, also referred to as transactinide elements, are defined as chemical elements with atomic numbers (Z) greater than or equal to 104.[6] This classification distinguishes them from transuranic elements, which encompass all elements with Z greater than 92 (uranium), as superheavy elements represent the heaviest subset synthesized in laboratories and are not found in nature.[7] The term "superheavy" emphasizes their extreme nuclear instability due to the large number of protons, leading to very short half-lives, ranging from microseconds to several hours for known isotopes.[8] These elements occupy positions in the extended periodic table following the actinide series (Z = 89–103), specifically in the 6d transition metal series for Z = 104–112 and the initial 7p series for Z = 113–118.[6] The 6d elements (104–112) align with groups 4 through 12, exhibiting properties analogous to lighter transition metals in those groups, while elements 113–118 transition into the p-block (groups 13–18).[7] Their placement reflects predicted electronic configurations influenced by relativistic effects, which become significant at high Z.[9] Prior to official naming, superheavy elements are designated using a systematic IUPAC nomenclature based on their atomic numbers, where digits are represented by Latin or Greek roots (e.g., un- for 1, bi- for 2, nil- for 0, pent- for 5), combined in order and suffixed with "-ium" to form the name, such as ununpentium for Z = 115.[10] The corresponding symbols consist of three letters starting with "U" followed by the first letters of the roots for the remaining digits (e.g., Uup for ununpentium).[11] Official names, approved by IUPAC after discovery verification, often honor scientists, institutions, or locations involved in their synthesis. The following table lists the confirmed superheavy elements from Z = 104 to 118, including their official names and symbols as recognized by IUPAC as of 2025:| Atomic Number (Z) | Name | Symbol |
|---|---|---|
| 104 | Rutherfordium | Rf |
| 105 | Dubnium | Db |
| 106 | Seaborgium | Sg |
| 107 | Bohrium | Bh |
| 108 | Hassium | Hs |
| 109 | Meitnerium | Mt |
| 110 | Darmstadtium | Ds |
| 111 | Roentgenium | Rg |
| 112 | Copernicium | Cn |
| 113 | Nihonium | Nh |
| 114 | Flerovium | Fl |
| 115 | Moscovium | Mc |
| 116 | Livermorium | Lv |
| 117 | Tennessine | Ts |
| 118 | Oganesson | Og |
Island of stability
The concept of the island of stability refers to a theoretical region in the chart of nuclides where certain isotopes of superheavy elements exhibit significantly enhanced nuclear stability due to closed shells, contrasting sharply with the rapid decay observed in currently synthesized superheavy isotopes. This idea was introduced by Glenn T. Seaborg in 1969, who predicted that shell closures around atomic numbers Z ≈ 114–126 and neutron numbers N ≈ 184 would lead to longer-lived superheavy nuclei, potentially extending the periodic table beyond previously expected limits.[13] In nuclear physics, magic numbers represent specific counts of protons or neutrons that fill complete nuclear shells, resulting in particularly stable configurations analogous to noble gas electron shells in atomic physics. For superheavy elements, theoretical models based on the nuclear shell model predict a major shell closure at N = 184 for neutrons, with possible proton closures near Z = 114 or Z = 120–126, creating a localized "island" of relative stability amid the broader trend of increasing instability as atomic mass rises due to heightened Coulomb repulsion and fission tendencies.[14] These shell effects provide binding energy that raises fission barriers and reduces alpha decay probabilities, countering the general decrease in half-lives for elements beyond uranium.[15] Theoretical calculations suggest that isotopes within this island could have half-lives ranging from seconds to minutes for those near the edges, potentially extending to years or even longer for doubly magic configurations like ^{298}114 (Z=114, N=184), far exceeding the microseconds typical of known superheavy isotopes such as ^{294}118.[16] Relativistic effects in superheavy atoms, arising from high nuclear charge accelerating inner electrons to speeds approaching the speed of light, contract and stabilize s and p_{1/2} orbitals while destabilizing d and f orbitals, which may indirectly influence overall atomic stability by altering chemical bonding and volatility in potential island isotopes.[17]Historical Development
Early predictions
The concept of superheavy elements beyond uranium emerged in the early 20th century, primarily through extensions of the periodic table based on atomic shell models. In 1922, Niels Bohr proposed that the periodic system could extend to atomic number Z=118, envisioning it as a noble gas with an electron configuration analogous to radon (86 electrons in completed shells plus 32 more), though he expressed doubts about the stability of such heavy atoms due to relativistic effects on electron orbits.[18] This prediction relied on Bohr's atomic model, which emphasized shell closures for chemical periodicity, but lacked insight into nuclear stability limits. Earlier speculations, such as those by Victor Meyer in 1889, had suggested a finite number of elements around Z=100 based on periodic trends, while Edmund St. John Mills in 1884 estimated an atomic weight limit near 240 using empirical formulas, reflecting pre-nuclear physics views on table extension.[18] The development of the nuclear shell model in the late 1940s by Maria Goeppert Mayer and J. Hans D. Jensen provided a quantum framework for nuclear stability, predicting magic numbers of protons and neutrons (e.g., 82 and 126) that enhance binding energies. By the 1950s, extrapolations to heavier regions suggested potential closed shells at higher magic numbers, such as Z=114 and N=184, implying greater stability for superheavy nuclei than liquid-drop models forecasted. These ideas built on earlier atomic shell extensions but shifted focus to nuclear structure, setting the stage for 1960s predictions. In the mid-1960s, V. M. Strutinsky introduced the shell-correction method to account for quantum shell effects in nuclear masses and deformation energies, revealing how deformed shapes in heavy nuclei could stabilize against fission through enhanced shell closures. Strutinsky's 1967 calculations demonstrated that shell effects dominate over macroscopic liquid-drop instabilities in the superheavy region, predicting minima in potential energy surfaces near doubly magic configurations like ^{298}114, where fission barriers could exceed 10 MeV, potentially yielding half-lives of seconds to years.[19] Glenn T. Seaborg formalized the "island of stability" hypothesis in 1969, proposing that superheavy elements around Z=114–126 with N≈184 would form a relatively stable region, extending the actinide series into a new "superactinide" sequence (Z=121–153) with 5g and 6f electron fillings, thereby broadening the periodic table.[20] This built on nuclear shell predictions, suggesting these elements could exhibit enhanced lifetimes amid a "sea" of unstable isotopes, influencing subsequent synthesis efforts. Early estimates of atomic and chemical properties for superheavy elements in groups 4–12 anticipated relativistic influences on electron configurations, leading to contracted s-orbitals and expanded d/f-orbitals. For instance, in group 4 (eka-hafnium, Z=104), predictions indicated a preference for +4 oxidation states with properties akin to zirconium but with increased volatility due to weaker metal-ligand bonds from relativistic stabilization of 6s electrons.[21] Similar trends were forecasted for groups 5–12: group 6 (Z=106) expected to mirror molybdenum with stable +6 states but reduced acidity; group 8 (Z=108) predicted as hassium with osmium-like volatility and high melting points; and group 12 (Z=112) as a volatile, zinc-like metal with minimal +2 stability due to inert-pair effects amplified by relativity. These Dirac-Fock calculations by Fricke and Waber in 1970 highlighted deviations from lighter homologs, such as lower ionization potentials and altered covalency, establishing conceptual trends without exhaustive numerical data.[21]Key discoveries
The discovery of superheavy elements began in the late 1960s with competing efforts by international teams. Element 104, rutherfordium, was first synthesized in 1969 at Lawrence Berkeley National Laboratory (LBNL) by bombarding californium-249 with carbon-12 and carbon-13 ions, producing isotopes with atomic masses around 257 and 258.[1][22] The Joint Institute for Nuclear Research (JINR) in Dubna, Russia, had reported a similar synthesis in 1964 using neon-22 on plutonium-242, but credit was officially awarded to the LBNL team following IUPAC review in 1997.[23] Element 105, dubnium, followed in 1970 at LBNL through the reaction of californium-249 with nitrogen-15.[1] In the 1970s and 1980s, further breakthroughs extended the periodic table. Element 106, seaborgium, was produced in 1974 at LBNL by fusing californium-249 with oxygen-18.[24] The discovery of element 107, bohrium, occurred in 1981 at the Gesellschaft für Schwerionenforschung (GSI) in Darmstadt, Germany, via the bombardment of bismuth-209 with chromium-54.[25] Element 108, hassium, was synthesized in 1984 at GSI using lead-208 and iron-58, marking a significant advancement in cold fusion techniques.[25] These syntheses relied on heavy-ion accelerators and were verified through alpha decay observations. The 2000s saw discoveries of elements 113 through 116, primarily at JINR and collaborating institutions. Element 113, nihonium, was first observed in 2004 at RIKEN in Japan by reacting bismuth-209 with zinc-70, with IUPAC confirmation in 2015.[26] Element 114, flerovium, was synthesized in 1998 at JINR using calcium-48 beams on plutonium-244, yielding isotopes like 289Fl.[27] Element 115, moscovium, emerged in 2003 from JINR-LLNL collaborations bombarding americium-243 with calcium-48.[28] Element 116, livermorium, was produced in 2000 at JINR via calcium-48 on curium-248.[27] Elements 117 and 118 completed the seventh row of the periodic table. Element 117, tennessine, was synthesized in 2010 by a JINR-LLNL-Oak Ridge National Laboratory (ORNL) team using berkelium-249 and calcium-48 at JINR's U-400 cyclotron. Element 118, oganesson, was first created in 2006 at JINR by fusing californium-249 with calcium-48, with independent confirmation in 2012.[29] These achievements were recognized by IUPAC in 2016.[26] Key experiments for elements 114–118 utilized calcium-48 beams at JINR's Dubna Gas-Filled Recoil Separator (DGFRS), which separated fusion products from beam particles for detection.[30] This approach, developed in the late 1990s, enabled the production of neutron-rich isotopes approaching the predicted island of stability.[28] IUPAC and IUPAP joint working groups confirmed these discoveries through rigorous review of experimental data, requiring independent replication and cross-verification of decay properties.[31] Naming controversies arose during the "transfermium wars" for elements 104–109 in the 1970s–1990s, involving disputes between American (LBNL) and Soviet/Russian (JINR) teams over credit and nomenclature. For element 108, GSI proposed hassium (after Hesse, Germany) in 1994, rejecting the American suggestion of hahnium; IUPAC resolved it in favor of hassium in 1997.[32] Element 114's name, flerovium, adopted in 2012, honored JINR's Flerov Laboratory without major dispute, though it echoed a rejected proposal for element 102.[33] Later namings for 113–118 proceeded smoothly under updated IUPAC guidelines.[26] Verification of these discoveries relied on observing alpha decay chains that terminated in known isotopes of lighter elements, providing genetic links for identification. For instance, oganesson-294 decayed through a chain ending in known polonium and lead isotopes, confirming its atomic number.[34] Similar chains, often 3–5 steps long, were essential for elements 114–118, with cross-checks at facilities like GSI ensuring reproducibility.[35]Recent advances
In 2025, researchers at the GSI Helmholtz Centre for Heavy Ion Research (GSI/FAIR) in Darmstadt, Germany, announced the discovery of seaborgium-257 (Sg-257), a new isotope of element 106 with 151 neutrons.[36] This isotope was produced by bombarding a tungsten-186 target with chromium-52 ions in the UNILAC linear accelerator, yielding 22 observed nuclei that decayed primarily via spontaneous fission with a half-life of 12.6 milliseconds. The discovery extends the known isotopic chain of seaborgium to 14 members, providing valuable data on neutron-rich nuclei near the predicted island of stability and enhancing understanding of shell effects in superheavy systems.[37] Advancements in synthesis techniques also marked 2024, particularly in the production of livermorium (element 116). At Lawrence Berkeley National Laboratory's 88-Inch Cyclotron, scientists successfully generated livermorium-288 by fusing titanium-50 beams with plutonium-242 targets, observing two decay chains over 22 days of irradiation.[5] This novel reaction, with a measured cross-section of approximately 0.3 picobarns, demonstrates the feasibility of using neutron-deficient projectiles like titanium-50 for superheavy fusion, potentially enabling attempts to synthesize elements 119 and 120 by targeting curium-248 or californium-249. The approach addresses limitations of traditional calcium-48 beams and highlights progress toward accessing more stable superheavy isotopes.[38] On the chemical front, a breakthrough in 2025 involved the first direct observation of molecules formed with nobelium (element 102), the heaviest element to date with identified compounds. Using the 88-Inch Cyclotron at Berkeley Lab, researchers produced nobelium ions via bombardment of a lead target with calcium-48 ions, then exposed them to trace gases of nitrogen and water vapor in a gas-filled separator.[39] Mass spectrometry detected cationic nobelium complexes with dinitrogen and water ligands, confirming chemical bonding on an atom-by-atom basis despite relativistic effects altering nobelium's reactivity to resemble lighter actinides more than expected. This technique, applicable to other superheavies like lawrencium and rutherfordium, promises to probe periodic trends in extreme atomic numbers and validate theoretical predictions for superheavy chemistry.[40] Efforts to discover elements 119 and 120 continued at major facilities, though without success as of late 2025. At RIKEN in Japan, upgraded superconducting linear accelerators increased beam intensities for titanium-50 reactions with berkelium-249, but extensive irradiation campaigns yielded no confirmed events, consistent with cross-sections below 0.1 picobarns.[41] Similarly, at the Joint Institute for Nuclear Research (JINR) in Russia, attempts using vanadium-51 on plutonium-244 and other combinations faced setbacks from low production rates and detection challenges, prompting further beam current enhancements.[42] These failed searches underscore the technical hurdles in reaching the next superheavy elements but have refined fusion models and target preparation methods for future trials. The International Union of Pure and Applied Chemistry (IUPAC) maintained its oversight of superheavy element nomenclature in 2025, with no new elements confirmed for naming but ongoing consultations on provisional systematic names like ununennium for element 119. This builds on the 2018 revision of discovery criteria, which streamlined verification for superheavies beyond element 118, ensuring rapid recognition once syntheses are replicated across laboratories.[43] Potential names for future elements will adhere to IUPAC guidelines honoring scientists or geographic origins, as seen with prior additions like oganesson.[26]Synthesis Methods
Nuclear fusion techniques
The synthesis of superheavy elements (SHE) primarily relies on nuclear fusion reactions, where a lighter projectile nucleus is accelerated to fuse with a heavy target nucleus, forming a compound nucleus that subsequently evaporates neutrons to reach a more stable configuration.[44] Two main approaches dominate: cold fusion and hot fusion, distinguished by the choice of reaction partners and the resulting excitation energy of the compound nucleus. Cold fusion reactions, developed at GSI in Darmstadt, involve doubly magic lead or bismuth targets (Z ≈ 82) bombarded by medium-mass projectiles such as zinc or calcium isotopes (Z = 30–20), leading to low excitation energies (10–15 MeV) and typically the evaporation of 1–2 neutrons. This method was instrumental in synthesizing elements from Z=106 (seaborgium) to Z=112 (copernicium), with representative reactions like ^{70}\mathrm{Zn} + ^{208}\mathrm{Pb} \to ^{277}\mathrm{Cn} + n, where cross-sections peak at around 1 picobarn (pb).[44] In contrast, hot fusion reactions, pioneered at the Joint Institute for Nuclear Research (JINR) in Dubna, employ neutron-rich actinide targets (Z = 90–98) such as plutonium or americium, paired with the neutron-rich projectile ^{48}\mathrm{Ca} (Z=20), resulting in higher excitation energies (30–40 MeV) and the evaporation of 3–5 neutrons to form more neutron-rich isotopes closer to the predicted island of stability. A key example is the production of flerovium (Z=114) via ^{48}\mathrm{Ca} + ^{244}\mathrm{Pu} \to ^{292}114^* \to ^{288}114 + 4n, which yielded the first confirmed decay chain in 1998 with a cross-section of approximately 1 pb at the optimal energy. Similarly, moscovium (Z=115) was synthesized in ^{48}\mathrm{Ca} + ^{243}\mathrm{Am} \to ^{291}115^* \to ^{288}115 + 3n, with measured cross-sections on the order of 0.1–1 pb, highlighting the role of neutron evaporation in stabilizing the residue against fission. These reactions exploit beam-target geometries where the projectile beam is directed onto a thin, rotating target foil to maximize interaction rates while minimizing degradation.[45] The probability of fusion is quantified through excitation functions, which map the evaporation residue cross-section as a function of the center-of-mass beam energy, revealing a narrow peak where the fusion barrier is surmounted with minimal quasifission.[46] For SHE production, these functions typically show maximum yields at energies 5–10% above the Coulomb barrier (around 200–250 MeV for actinide targets), with fusion probabilities dropping sharply due to competition from quasifission, where the dinuclear system breaks apart before full equilibration.[46] Deformation of the colliding nuclei plays a crucial role in enhancing cross-sections; prolate deformations in actinide targets can lower the effective barrier for tip-on orientations, increasing fusion hindrance for side-on collisions but overall favoring neutron-rich paths when aligned properly.[47] Theoretical models incorporating these deformations predict up to a factor of 2–5 improvement in cross-sections for optimally oriented deformed nuclei in hot fusion scenarios.[47]Accelerators and facilities
The synthesis of superheavy elements requires accelerators capable of producing intense beams of heavy ions, such as calcium-48 or titanium-50, with energies typically in the range of 5-8 MeV per nucleon to overcome the Coulomb barrier in fusion reactions with actinide targets.[45] Two primary types of accelerators are employed: cyclotrons, which provide high beam intensities through continuous acceleration in a magnetic field, and linear accelerators (linacs), which offer precise control over beam energy and are suited for injecting heavy ions into synchrotrons for further acceleration.[48] Cyclotrons, like those at major facilities, excel in delivering stable, high-current beams essential for the low cross-sections of superheavy element production, often on the order of picobarns.[49] The Joint Institute for Nuclear Research (JINR) in Dubna, Russia, hosts the Superheavy Element Factory (SHE Factory), a dedicated cyclotron complex centered on the DC-280 cyclotron, which accelerates 48Ca beams to intensities up to 6 × 10^{13} ions per second at energies of 5-8 A·MeV, enabling the production of elements up to oganesson (Z=118). This facility, operational since 2019, includes the upgraded U-400 cyclotron for initial acceleration and supports experiments with beam powers reaching approximately 10 pμA, a significant enhancement over prior setups that has increased synthesis rates by orders of magnitude. It has enabled the discovery of new isotopes, such as livermorium-288, livermorium-289, and copernicium-280, as of July 2025.[50][51][52] At GSI Helmholtz Centre in Darmstadt, Germany, the UNILAC linear accelerator provides high-intensity heavy-ion beams, such as titanium-50 at energies optimized for fusion, and serves as the injector for the Facility for Antiproton and Ion Research (FAIR), which is expected to deliver even higher luminosities for superheavy element studies starting in 2027.[53][54] Lawrence Berkeley National Laboratory's 88-Inch Cyclotron in the United States accelerates a range of heavy ions, including titanium-50 for recent element 116 production, with beam energies up to several MeV per nucleon and intensities suitable for atom-at-a-time experiments.[5] Japan's RIKEN Nishina Center employs the RIKEN Gas-filled Recoil Ion Separator (RIKEN GAS or GARIS) coupled to its Radioactive Isotope Beam Factory (RIBF) cyclotrons, which generate intense heavy-ion beams for synthesizing and separating superheavy residues, including efforts toward elements beyond 118.[55] Ongoing attempts to synthesize element 119 (ununennium) as of November 2025 include reactions such as ^{50}\mathrm{Ti} + ^{249}\mathrm{Bk} at facilities like LBNL, GSI, and JINR, as well as heavier projectile approaches at RIKEN, though no confirmed atoms have been produced yet. Similar efforts target element 120 using projectiles like ^{54}\mathrm{Cr} + ^{249}\mathrm{Cf}. These build on the 2024 success with titanium-50 for livermorium (element 116), aiming to access more neutron-rich isotopes.[56][5][57] Target preparation for these experiments involves fabricating thin actinide foils, typically 0.5-1 mg/cm² thick, from isotopes like plutonium-244, americium-243, or curium-248, deposited on titanium backings via molecular plating to withstand intense beam bombardment without significant degradation.[58] These foils are irradiated in rotating wheel assemblies to distribute heat and ensure uniform exposure.[59] Fusion products, which recoil from the target with velocities around 5-10% of the speed of light, are then transported via gas-jet systems—where helium or argon gas carries the ions through capillaries to detectors—achieving separation efficiencies over 90% while minimizing contamination from scattered beam particles.[60] International collaborations are crucial for superheavy element research, pooling expertise in beam production, target fabrication, and detection; for instance, the confirmed synthesis of element 118 (oganesson) resulted from joint efforts between JINR's SHE Factory and U.S. laboratories, including Lawrence Livermore National Laboratory and Oak Ridge National Laboratory, which supplied enriched actinide targets like californium-249.[27] Similar partnerships, such as those between GSI/FAIR and international teams for mass measurements, and RIKEN's collaborations with global institutions for separator upgrades, have accelerated progress by sharing rare isotopes and advanced instrumentation.[61]Properties
Nuclear properties
Superheavy elements (SHEs), defined as those with atomic numbers Z ≥ 104, exhibit nuclear properties dominated by strong Coulomb repulsion between protons, leading to inherent instability. Their nuclei are characterized by complex shell structures, where magic numbers—such as proton numbers Z = 114 or 120 and neutron numbers N = 184—create shell closures that enhance binding energy and stability through quantum shell effects. These closures raise fission barriers, potentially increasing half-lives by up to 15 orders of magnitude compared to liquid-drop model predictions without shell corrections, as observed in isotopes near N = 152 for elements like rutherfordium (Z = 104).[62][63] The half-lives of known SHE isotopes typically range from microseconds to hours, influenced heavily by proximity to shell closures; for instance, isotopes near Z = 114 and N = 184 show extended α-decay half-lives due to increased shell gaps of approximately 3 MeV. Fission barriers in these nuclei are generally low, around 5–8 MeV for heavier SHEs, but shell effects can elevate them, promoting relative stability against spontaneous fission (SF) in lighter isotopes. In contrast, without strong shell stabilization, barriers drop below 5 MeV, favoring rapid decay.[64][62] Alpha decay is a primary mode for SHEs, proceeding through chains that reveal energy spectra and Q-values indicative of nuclear structure. Q-values for α-decay typically range from 10–12 MeV, with half-lives calculated via models like the Viola-Seaborg formula, showing sensitivity to shell effects; for example, ^{294}Og (Z = 118) undergoes α-decay to ^{290}Lv (Z = 116) with a predicted Q-value around 11.5 MeV and a half-life on the order of 0.7 ms, continuing a chain influenced by deformed shells at N ≈ 172. These chains provide insights into single-particle levels and stability, with longer sequences near magic numbers.[65][63] In heavier SHE isotopes (Z > 116), spontaneous fission dominates over α-decay, with SF half-lives as short as microseconds due to lowered barriers from high proton numbers; branching ratios favor SF when T_{SF}^{1/2} / T_α^{1/2} < 1. Neutron emission accompanies SF in some cases, with average yields of 2–4 neutrons per event, contributing to post-fission fragments and aiding detection, though less common than in lighter actinides.[64][66] Isotope production yields for SHEs are quantified by evaporation residue cross-sections, which represent the probability of forming and surviving the compound nucleus after neutron evaporation. The cross-section is given by\sigma_{ER} = \sigma_{fus} \times P_{survival},
where \sigma_{fus} is the fusion cross-section and P_{survival} is the survival probability against fission during de-excitation. Typical values for known SHEs range from picobarns (pb) for lighter fusions to femtobarns (fb) for Z ≈ 118, decreasing rapidly with Z due to lower survival probabilities near 10^{-5}–10^{-7}.[67]
Chemical properties
Superheavy elements exhibit chemical behaviors significantly influenced by relativistic effects arising from the high velocities of inner electrons near the speed of light, which become prominent for atomic numbers Z > 80. These effects cause a radial contraction and stabilization of s and p_{1/2} orbitals due to increased relativistic mass, while d and f orbitals expand, leading to altered electron configurations and bonding trends compared to lighter homologs.[9][68] For instance, in group 6, relativistic destabilization of the 7s orbital enhances the volatility of seaborgium compounds, such as its hexacarbonyl Sg(CO)_6, making it more gaseous than expected from non-relativistic trends.[69] Experimental investigations of superheavy element chemistry are constrained by production rates of only a few atoms per experiment, necessitating rapid, on-line techniques. For hassium (element 108), gas-phase thermochromatography was used to study the formation and adsorption of volatile HsO_4 molecules, revealing deposition temperatures consistent with group 8 tetroxide behavior, albeit with relativistic modifications reducing stability relative to osmium. Aqueous-phase studies of rutherfordium (element 104) employed solvent extraction with tributylphosphate in HCl media, demonstrating that Rf^{4+} ions hydrolyze similarly to hafnium but extract more readily than zirconium, indicating group 4 homology with relativistic influences on ion size and charge density.[70] Theoretical predictions suggest that superheavy elements largely follow periodic trends as analogs to lighter homologs, but with deviations due to relativistic orbital shifts. Flerovium (element 114), for example, is anticipated and experimentally confirmed to be more inert and volatile than lead, exhibiting weak metallic bonding and adsorption on gold surfaces only under specific conditions, positioning it as the least reactive group 14 element.[71] The primary challenges in studying these elements stem from their ultrashort half-lives, often milliseconds to seconds, which restrict experiments to single atoms and demand automated, continuous separation and detection systems. On-line techniques, such as gas-filled recoil separators, enabled the first chemical studies of copernicium (element 112) by rapidly isolating reaction products for volatility assessments, confirming its mercury-like behavior with enhanced nobility from relativistic 7s contraction.Decay and Detection
Decay processes
Superheavy elements primarily undergo radioactive decay through alpha emission, which is the dominant mode due to the high Coulomb barrier and nuclear structure favoring the ejection of a helium-4 nucleus. These alpha particles typically carry energies between 9 and 11 MeV, reflecting the Q-values of the transitions in neutron-deficient isotopes.[34] Following initial alpha decays, many chains terminate via spontaneous fission (SF), particularly in even-Z, even-N nuclei where the barrier to fission is lower, allowing symmetric or asymmetric splitting into lighter fragments without external excitation. Electron capture, involving the capture of an inner-shell electron by a proton to form a neutron, occurs rarely in superheavy nuclei owing to the high atomic numbers and relativistic effects that suppress weak interaction rates compared to alpha decay or SF.[72] The choice of decay path is significantly influenced by odd-even nucleon effects, stemming from pairing interactions in the nuclear shell model. Nuclei with an odd number of protons or neutrons experience a hindrance to spontaneous fission because the unpaired nucleon raises the fission barrier by disrupting the even-even configuration's symmetry, leading to longer SF half-lives by factors of 10 to 100 compared to neighboring even-even isotopes.[73] Alpha decay half-lives show less pronounced staggering, as the process is less sensitive to single-particle effects, though odd-A nuclei often exhibit slightly extended lifetimes due to reduced overlap in the alpha-nucleus potential.[74] These effects guide the observed branching in decay chains, with even-even superheavies favoring quicker SF termination while odd-mass ones prolong alpha sequences. An illustrative example is the decay chain of tennessine-294 (Z=117, A=294), the most stable known isotope of tennessine, observed in fusion-evaporation reactions at facilities like the Dubna Gas-Filled Recoil Separator. This chain proceeds through successive alpha decays until spontaneous fission intervenes, reaching established actinide isotopes. The sequence, based on experimental data from multiple events (over 10 atoms observed across experiments as of 2019), is summarized below, including measured alpha energies, half-lives, and notes on branching (using adopted values from recent compilations):| Nuclide | Decay Mode | Alpha Energy (MeV) | Half-Life | Notes/Branching |
|---|---|---|---|---|
| ^{294}Ts | α | 10.84 ± 0.08 | 51^{+38}_{-16} ms | 100% α; no SF observed[75] |
| ^{290}Mc | α | 10.69 ± 0.07 | 0.65 ± 0.10 s | 100% α; consistent across chains[76] |
| ^{286}Nh | α | 10.14 ± 0.04 | 9.5^{+2.4}_{-1.1} s | 100% α; long-lived relative to parents[76] |
| ^{282}Db | α | 9.88 ± 0.10 | 220 ± 60 ms | 100% α; branches to known dubnium isotopes |
| ^{278}Rf | SF | - | ~10 ms (inferred) | Terminates chain; ~20-30% of Rf isotopes SF here, others α to lower Z |