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Ruthenium electron configuration , atomic mass , atomic number basics information in points

By   June 27, 2023

know all Ruthenium electron configuration , atomic mass , atomic number basics information in points ?

question : what is atomic mass and atomic number of Ruthenium element ?

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answer : as we know Ruthenium element is denoted by ‘Ru’ symbol and Ruthenium has ‘101.07’ atomic mass and ’44’ atomic number.

question : write the electron configuration of Ruthenium element ?

answer : Ruthenium electronic configuration is ”[Kr] 4d7 5s1”.

question : write some information about Ruthenium ?

answer : Ruthenium has melting point = 2,250

Ruthenium boiling point = 3,900

Ruthenium has density ‘12.37’ and it is found ”% on earth. Ruthenium belongs to group ‘8’.

some interesting facts of Ruthenium are given below –

Ruthenium is the forty-fourth element on the periodic table with the chemical symbol Ru. It is a transition metal that belongs to the platinum group of metals. Ruthenium has several important applications in various fields.

One of the primary uses of ruthenium is in catalysis. Ruthenium-based catalysts are employed in various chemical reactions, including hydrogenation, oxidation, and metathesis reactions. These catalysts exhibit high activity, selectivity, and stability, making them valuable in the production of chemicals, pharmaceuticals, and fine chemicals. Ruthenium catalysts are particularly important in the synthesis of organic compounds and the production of renewable fuels.

Ruthenium also finds applications in the field of electronics. Ruthenium oxide is used as a material for resistors and capacitors in electronic devices. It is highly stable and has a high dielectric constant, making it suitable for applications in microelectronics, such as memory devices and integrated circuits.

Another significant use of ruthenium is in the field of electrochemistry. Ruthenium-based compounds, such as ruthenium dioxide (RuO2), are used as electrode materials in supercapacitors and batteries. Ruthenium-based electrodes exhibit high conductivity and excellent electrochemical stability, enabling efficient energy storage and discharge.

Ruthenium has applications in the production of specialty materials. Ruthenium alloys, such as ruthenium-titanium, are used to create hard-wearing electrical contacts in devices like smartphones and computers. Ruthenium is also used as a coating material to enhance the corrosion resistance and durability of components in various industries, including automotive and chemical processing.

Moreover, ruthenium has applications in the field of solar energy. Ruthenium complexes are used as dyes in dye-sensitized solar cells (DSSCs). These dyes capture light and facilitate the conversion of solar energy into electricity. Ruthenium-based dyes have high absorption efficiency and excellent stability, making them suitable for renewable energy applications.

It’s worth noting that ruthenium’s scarcity and high cost limit its widespread use in industrial applications. However, its unique properties and versatility make it valuable in specialized fields such as catalysis, electronics, energy storage, and solar energy conversion.

In summary, ruthenium’s applications in catalysis, electronics, electrochemistry, specialty materials, and solar energy highlight its significance in various fields. Its catalytic properties, stability, and conductivity make it valuable in industries such as chemical synthesis, electronics, energy storage, and renewable energy. The unique properties of ruthenium contribute to advancements in technology, sustainability, and energy conversion.