Molybdenum: Difference between revisions
(Created page with "==History== Molybdenum, a trace element with significant roles in biological processes, has a history intertwined with metallurgy and industry. First isolated in the late 18th century by Swedish chemist Carl Wilhelm Scheele and later recognized as a distinct element by Peter Jacob Hjelm, molybdenum found applications in steel production and catalysis during the 19th and 20th centuries. ==Chemical Structure== Molybdenum, with the symbol Mo and atomic number 42, is a tran...") |
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==Legal Status== | ==Legal Status== | ||
Molybdenum itself is not subject to legal restrictions. However, regulations may apply to molybdenum-containing products, particularly in industrial and occupational settings. Awareness of molybdenum's legal status ensures responsible use and compliance with relevant regulations. | Molybdenum itself is not subject to legal restrictions. However, regulations may apply to molybdenum-containing products, particularly in industrial and occupational settings. Awareness of molybdenum's legal status ensures responsible use and compliance with relevant regulations. | ||
[[Category:Minerals]] |
Latest revision as of 16:40, 26 February 2024
History
Molybdenum, a trace element with significant roles in biological processes, has a history intertwined with metallurgy and industry. First isolated in the late 18th century by Swedish chemist Carl Wilhelm Scheele and later recognized as a distinct element by Peter Jacob Hjelm, molybdenum found applications in steel production and catalysis during the 19th and 20th centuries.
Chemical Structure
Molybdenum, with the symbol Mo and atomic number 42, is a transition metal known for its versatility in various oxidation states. It acts as a cofactor for enzymes involved in nitrogen metabolism and plays a vital role in biological nitrogen fixation. Molybdenum exists in different oxidation states, with molybdenum(VI) being the most common in biological systems.
Variants
Molybdenum variants include molybdenum disulfide and various molybdenum compounds used in industrial applications. These variants have applications in lubricants, catalysts, and electronic devices.
Toxicity
Molybdenum toxicity is rare but can occur with excessive intake, leading to molybdenum-induced gout and other adverse effects. Maintaining a balance in molybdenum consumption, primarily through dietary sources, is crucial for preventing toxicity.
Synergistic Compounds
Molybdenum interacts with other minerals such as copper and iron, and it plays a crucial role in the function of enzymes like xanthine oxidase. Understanding these interactions is essential for maintaining optimal health and preventing imbalances.
Effects
Health Benefits
Molybdenum is essential for the proper functioning of enzymes involved in breaking down certain amino acids and purines. Adequate molybdenum intake supports normal growth, development, and overall metabolic processes.
Risks
While molybdenum is generally safe at recommended levels, excessive intake can lead to adverse health effects. Individuals with certain genetic conditions may be more susceptible to molybdenum-related issues.
Subjective Effects
Subjective effects of molybdenum intake are not commonly reported, as its influence is primarily on internal physiological processes. However, individuals with specific health conditions may experience effects related to molybdenum metabolism.
Attainability
Molybdenum is attainable through a balanced diet that includes legumes, nuts, grains, and leafy green vegetables. Molybdenum supplements are available but should be used cautiously to avoid exceeding recommended daily limits.
Legal Status
Molybdenum itself is not subject to legal restrictions. However, regulations may apply to molybdenum-containing products, particularly in industrial and occupational settings. Awareness of molybdenum's legal status ensures responsible use and compliance with relevant regulations.