Bohrium: Difference between revisions
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Bohrium is a synthetic chemical element with the symbol Bh and atomic number 107. It is a member of the [[transition metals]] and is part of the [[7th period]] in the [[periodic table]]. Bohrium is named after the Danish physicist [[Niels Bohr]], who made foundational contributions to understanding atomic structure and quantum theory. | |||
Bohrium | |||
== Properties == | ==Properties== | ||
Bohrium is a [[radioactive element]] and is not found naturally on Earth. It is produced artificially in a laboratory setting. Due to its position in the periodic table, it is expected to have properties similar to other group 7 elements, such as [[rhenium]] and [[manganese]]. | |||
=== | ===Physical Properties=== | ||
- '''Atomic Number''': 107 | |||
- '''Atomic Weight''': [270] (most stable isotope) | |||
- '''Density''': Unknown, but predicted to be around 37.1 g/cm³ | |||
- '''Melting Point''': Unknown | |||
- '''Boiling Point''': Unknown | |||
== | ===Chemical Properties=== | ||
Bohrium is expected to exhibit chemical behavior similar to that of rhenium. It is predicted to form a stable +7 oxidation state, and possibly lower oxidation states as well. Due to its short half-life, detailed chemical studies have not been conducted. | |||
== | ==Isotopes== | ||
{{ | |||
Bohrium has several isotopes, all of which are radioactive. The most stable isotope is [[Bohrium-270]], with a half-life of approximately 61 seconds. Other isotopes include Bohrium-267, Bohrium-271, and Bohrium-272, each with varying half-lives and decay modes. | |||
==Production== | |||
Bohrium is produced in particle accelerators through the fusion of lighter elements. The most common method involves bombarding [[Bismuth-209]] with [[Chromium-54]] ions: | |||
\[ | |||
\text{\(^{209}_{83}Bi + \ ^{54}_{24}Cr \rightarrow \ ^{262}_{107}Bh + 1n\)} | |||
\] | |||
This reaction produces Bohrium-262, which decays rapidly into lighter elements. | |||
==Applications== | |||
Due to its short half-life and the difficulty in producing it, bohrium has no practical applications outside of scientific research. It is primarily used in experiments to study the properties of superheavy elements and to test theoretical models of atomic structure. | |||
==History== | |||
Bohrium was first synthesized in 1981 by a team of scientists at the [[Gesellschaft für Schwerionenforschung]] (GSI) in [[Darmstadt]], Germany. The team was led by [[Peter Armbruster]] and [[Gottfried Münzenberg]]. The element was named in honor of Niels Bohr, reflecting his contributions to the understanding of atomic structure. | |||
==See Also== | |||
- [[Periodic Table]] | |||
- [[Transition Metals]] | |||
- [[Radioactive Elements]] | |||
- [[Synthetic Elements]] | |||
==External Links== | |||
- [Wikimedia Commons: Bohrium](https://commons.wikimedia.org/wiki/Category:Bohrium) | |||
{{Periodic table}} | {{Periodic table}} | ||
{{Bohrium}} | |||
[[Category:Chemical elements]] | [[Category:Chemical elements]] | ||
[[Category:Synthetic elements]] | [[Category:Synthetic elements]] | ||
[[Category:Transition metals]] | [[Category:Transition metals]] | ||
[[Category: | [[Category:Radioactive elements]] | ||
Revision as of 12:36, 31 December 2024
Bohrium
Bohrium is a synthetic chemical element with the symbol Bh and atomic number 107. It is a member of the transition metals and is part of the 7th period in the periodic table. Bohrium is named after the Danish physicist Niels Bohr, who made foundational contributions to understanding atomic structure and quantum theory.
Properties
Bohrium is a radioactive element and is not found naturally on Earth. It is produced artificially in a laboratory setting. Due to its position in the periodic table, it is expected to have properties similar to other group 7 elements, such as rhenium and manganese.
Physical Properties
- Atomic Number: 107 - Atomic Weight: [270] (most stable isotope) - Density: Unknown, but predicted to be around 37.1 g/cm³ - Melting Point: Unknown - Boiling Point: Unknown
Chemical Properties
Bohrium is expected to exhibit chemical behavior similar to that of rhenium. It is predicted to form a stable +7 oxidation state, and possibly lower oxidation states as well. Due to its short half-life, detailed chemical studies have not been conducted.
Isotopes
Bohrium has several isotopes, all of which are radioactive. The most stable isotope is Bohrium-270, with a half-life of approximately 61 seconds. Other isotopes include Bohrium-267, Bohrium-271, and Bohrium-272, each with varying half-lives and decay modes.
Production
Bohrium is produced in particle accelerators through the fusion of lighter elements. The most common method involves bombarding Bismuth-209 with Chromium-54 ions:
\[ \text{\(^{209}_{83}Bi + \ ^{54}_{24}Cr \rightarrow \ ^{262}_{107}Bh + 1n\)} \]
This reaction produces Bohrium-262, which decays rapidly into lighter elements.
Applications
Due to its short half-life and the difficulty in producing it, bohrium has no practical applications outside of scientific research. It is primarily used in experiments to study the properties of superheavy elements and to test theoretical models of atomic structure.
History
Bohrium was first synthesized in 1981 by a team of scientists at the Gesellschaft für Schwerionenforschung (GSI) in Darmstadt, Germany. The team was led by Peter Armbruster and Gottfried Münzenberg. The element was named in honor of Niels Bohr, reflecting his contributions to the understanding of atomic structure.
See Also
- Periodic Table - Transition Metals - Radioactive Elements - Synthetic Elements
External Links
- [Wikimedia Commons: Bohrium](https://commons.wikimedia.org/wiki/Category:Bohrium)
