Tennessine

Discovery and History

The discovery of tennessine represents a remarkable collaboration between Russian and American scientists, marking a significant milestone in the field of nuclear physics. This synthetic element, was first synthesized in 2010 by a team of researchers from the Joint Institute for Nuclear Research (JINR) in Dubna, Russia, and the Oak Ridge National Laboratory (ORNL) in Tennessee, USA. The element owes its name to the latter institution, reflecting the collaborative efforts that led to its creation.

The synthesis of tennessine involved a complex and delicate process, utilizing particle accelerators and advanced technology. Researchers bombarded a target containing berkelium-249 with a beam of calcium-48 ions, leading to the fusion of the two elements and the formation of tennessine nuclei. This groundbreaking experiment required precise control and meticulous analysis to identify the fleeting presence of tennessine amidst the radioactive decay of the reaction products.

Tennessine’s discovery expanded the seventh row of the periodic table, providing valuable insights into the behavior of superheavy elements. These elements, located at the far end of the periodic table, possess unique properties due to their high atomic numbers and unstable nuclei. Tennessine, in particular, is highly unstable, with a very short half-life, making it challenging to study. However, its classification as a halogen suggests that it shares chemical properties with its lighter counterparts, such as iodine and astatine.

The synthesis of tennessine represents a testament to human ingenuity and scientific collaboration. It underscores the remarkable capabilities of modern physics and the ongoing quest to explore the fundamental building blocks of the universe. As researchers continue to push the boundaries of nuclear science, discoveries like tennessine pave the way for new insights into the nature of matter and the forces that govern the cosmos.

Atomic Structure and Isotopes

Atomic Structure of Tennessine

Tennessine, with its atomic number 117 and symbol Ts, presents an intriguing atomic structure characterized by its large nucleus containing a substantial number of protons and neutrons. Being one of the heaviest elements, the atomic structure of tennessine is governed primarily by the interactions between its protons and neutrons, as well as the binding forces within the nucleus. Theoretical models and computational simulations suggest that tennessine nuclei are likely highly deformed, featuring irregular shapes and energy landscapes contributing to their instability.

Isotopes of Tennessine

• Tennessine-293 (Ts-293): Tennessine-293 has 117 protons (since it’s an atom of tennessine) and 176 neutrons. It is one of the more stable isotopes of tennessine synthesized thus far. Despite being relatively stable compared to other isotopes of tennessine, it still has a very short half-life, typically measured in microseconds. Tennessine-293 is produced through nuclear reactions, such as the fusion of lighter elements in particle accelerators. For example, it can be created by bombarding a target containing berkelium-249 with calcium-48 ions.
• Tennessine-294 (Ts-294): Tennessine-294 consists of 117 protons and 177 neutrons. Like Ts-293, it is one of the more stable isotopes of tennessine. Its half-life is also very short, typically measured in microseconds. Tennessine-294 is produced using similar methods to Ts-293, involving nuclear reactions in particle accelerators.

Physical and Chemical Properties

Physical Properties of Tennessine

• Appearance and State: Tennessine is projected to be a dense, metallic-looking solid at room temperature, characterized by a silver-white appearance.
• Melting and Boiling Points: Its melting and boiling points are anticipated to be relatively low compared to most metals due to its position in the halogen group of the periodic table.
• Density: Tennessine is expected to have a notably high density, likely surpassing that of lead and similar to other dense elements in its vicinity on the periodic table.
• Atomic Radius and Volume: Its atomic radius and atomic volume are projected to be relatively small, consistent with the trend observed for halogens, which tend to have compact atomic structures.

Chemical Properties of Tennessine

• Reactivity: Tennessine’s chemical properties are predicted to resemble those of its lighter halogen counterparts, such as iodine, astatine, chlorine, and fluorine.
• Electron Affinity: Like other halogens, tennessine is expected to exhibit a strong tendency to gain an electron, forming a negative ion (an anion) to achieve a stable electron configuration.
• Oxidation State: Tennessine typically exhibits an oxidation state of -1 in compounds, predominantly forming binary compounds.
• Compound Formation: Despite its extreme instability and short half-life, theoretical calculations suggest that tennessine may form compounds with other elements, particularly metals, creating salts analogous to those formed by other halogens.

Occurrence and Production

Occurrence of Tennessine

Tennessine is a synthetic element and does not occur naturally on Earth. It is a product of human ingenuity and scientific exploration rather than a naturally-occurring substance. Due to its highly unstable nature and extremely short half-life, tennessine cannot be found in nature and must be synthesized in laboratories using specialized equipment and techniques.

Production of Tennessine

The production of tennessine involves complex and carefully controlled processes conducted in particle accelerators. The most common method for synthesizing tennessine is through nuclear fusion reactions, which typically involve bombarding a heavy target nucleus with a beam of lighter nuclei.

One of the most successful methods for synthesizing tennessine involves the fusion of calcium-48 ions with a target containing berkelium-249. This process results in the formation of tennessine nuclei, which are highly unstable and rapidly decay into lighter elements through various radioactive decay modes.

The synthesis of tennessine requires advanced equipment and expertise in nuclear physics, as well as highly specialized facilities such as particle accelerators and target preparation laboratories. The production of tennessine isotopes is a challenging endeavor, requiring precise control over experimental conditions and careful analysis of reaction products to confirm the presence of tennessine atoms.

Applications

Tennessine, being a synthetic and highly unstable element with a very short half-life, does not have any practical applications at present. However, research into its properties and potential applications remains an active area of study in the field of nuclear physics. While the direct applications of tennessine are currently limited, its discovery has important implications for scientific research and technological advancements in various fields.

• Impact on Fundamental Science: The discovery of tennessine has expanded our understanding of the periodic table and the behavior of superheavy elements. By synthesizing and studying tennessine isotopes, researchers gain insights into nuclear structure, decay modes, and the limits of stability in the realm of heavy nuclei. This knowledge contributes to fundamental research in nuclear physics and informs theoretical models of nuclear structure and dynamics.
• Exploration of Nuclear Stability: Tennessine’s position as one of the heaviest elements on the periodic table makes it a valuable subject for studying the limits of nuclear stability. Investigating the properties of tennessine isotopes sheds light on the mechanisms that govern nuclear stability and the factors that influence the synthesis and decay of superheavy elements. This research has implications for understanding the formation of heavy elements in astrophysical environments and the stability of nuclei under extreme conditions.
• Technological Advances: While tennessine itself may not have direct technological applications, research into superheavy elements can lead to technological advancements in areas such as nuclear energy, materials science, and particle physics. Insights gained from studying tennessine isotopes contribute to the development of new techniques for synthesizing and manipulating heavy nuclei, which may have applications in fields such as nuclear medicine, energy production, and materials engineering.
• Inspiration for Future Discoveries: The discovery of tennessine serves as a reminder of the boundless possibilities for scientific exploration and discovery. As researchers continue to push the frontiers of knowledge, new elements and phenomena may be revealed, opening doors to unexpected applications and discoveries. The quest to understand the properties and behavior of tennessine and other superheavy elements drives innovation and inspires future generations of scientists and engineers.