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Tennessine: Element Properties and Uses
Description
Tennessine (Ts) is a synthetic, superheavy, and highly radioactive element with the atomic number 117. One of the newest additions to the periodic table, it occupies a foundational position in modern nuclear research. Tennessine exists for moments in fractions of a second before decaying into lighter elements, but its creation marks a breakthrough in the modern search for superheavy nuclei.
History and Naming
Tennessine was first synthesized in 2010 through a joint effort by Russian and American scientists from the Joint Institute for Nuclear Research (JINR) in Dubna, Russia, and the Oak Ridge National Laboratory (ORNL) in Tennessee, USA. The experiment targeted berkelium-249 (²⁴⁹Bk) with ions of calcium-48 (⁴⁸Ca) to produce Tennessine-294 atoms.
The new atoms broke down almost instantly, but their characteristic alpha-particle emissions were evidence of the existence of element 117.
In 2016, the International Union of Pure and Applied Chemistry (IUPAC) officially recognized the discovery and approved the name "Tennessine", after the United States state of Tennessee, to honor ORNL, Vanderbilt University, and the University of Tennessee's contributions to the research and discovery of superheavy elements.
Atomic and Physical Properties
|
Property |
Value (Predicted or Observed) |
|
Atomic Number |
117 |
|
Symbol |
Ts |
|
Group / Period |
17 / 7 |
|
Element Category |
Halogen (Predicted) |
|
Density (Predicted) |
~7.2 g/cm³ |
|
Melting Point (Estimated) |
~350–500°C |
|
Boiling Point (Estimated) |
~610–780°C |
|
Most Stable Isotope |
Ts-294 |
|
Half-Life |
~20 milliseconds |
Tennessine is expected to behave as a metallic or semi-metallic halogen, unlike lighter analogs such as chlorine or iodine. Theoretical models suggest relativistic effects—due to the high velocity of inner electrons—may bestow weaker nonmetallic character and perhaps metallic bonding tendencies upon it.
Chemical Properties Description
As a result of its extremely short half-life and small output of production, no actual chemical experiment has ever been performed on tennessine. Computational chemistry and periodic trends, however, give insight into its likely behavior:
•Group Similarity: Tennessine is in Group 17 (the halogens) and should be expected to display some reactivity similarity with astatine (At), the largest naturally occurring halogen.
• Oxidation States: Calculated oxidation states are –1, +1, and +3, of which +1 and +3 must be more stable due to relativistic stabilization effects.
• Chemical Reactivity: It would give simple compounds such as Tennessine chloride (TsCl) and Tennessine fluoride (TsF), but none of these have been experimentally established.
Production and Synthesis
Synthesis of tennessine is a marvelous piece of scientific achievement involving particle accelerators, radioactive targets, and sophisticated ion-beam technology.
Synthesis involves the following key steps:
1. Target preparation: Thin layer of berkelium-249, which is prepared at the High Flux Isotope Reactor at ORNL, is deposited on a foil of titanium.
2. Ion bombardment: Calcium-48 beam is accelerated to high energy and bombarded on the berkelium target.
3. Nuclear Fusion: Sometimes the collision of nuclei results in the formation of a superheavy compound nucleus (Tennessine), which releases neutrons and decays almost immediately.
4. Detection: Carefully designed detectors measure the alpha decay chain to confirm the new element's presence.
Because of its low yield—only a few atoms per experiment—and rapid decay, each observation demands high precision and worldwide cooperation.
Applications and Scientific Significance
Tennessine's short half-life and minute production eliminate any industrial or commercial uses, but its scientific impact is enormous:
• Nuclear Structure Studies: The study of tennessine enables physicists to observe how protons and neutrons behave in the superheavy region of the periodic table.
• Theoretical Confirmation: Its discovery confirms nuclear shell model predictions and the quest for the "island of stability", a theoretical region where superheavy elements may have longer half-lives.
• Technological Development: Equipment and methods developed to produce tennessine—such as advanced target preparation, particle beam manipulation, and detector technology—have influenced developments in nuclear medicine, materials science, and accelerator physics. For more information, please check Stanford Advanced Materials (SAM).
Frequently Asked Questions
What is Tennessine?
Tennessine (Ts) is a synthetic, radioactive element with atomic number 117, produced by high-energy nuclear fusion reactions of berkelium and calcium isotopes.
Why is it named Tennessine?
The element is named after the U.S. state of Tennessee in acknowledgment of the key role played by its research institutions in the discovery.
How is Tennessine made?
It is made by bombarding targets of berkelium-249 with calcium-48 ions in a particle accelerator, producing only a few atoms at a time.
What are its chemical properties?
Expected to act like a heavy halogen, perhaps metallic in character, with oxidation states of –1, +1, and +3.
Does Tennessine possess any useful industrial applications?
No useful applications exist as of now due to its instability, but its synthesis drives technology in nuclear science and high-precision instrumentation.
What is the advantage of studying Tennessine?
It increases understanding of superheavy element stability, nuclear forces, and relativistic effects on chemical behavior.
Chin Trento
