Bauxite vs Aluminum
Although we are familiar with aluminum, we do not know much about where it comes from. Thus, bauxite term is quite unfamiliar to us. Following is a description about aluminum and bauxite, their relationship and the differences.
Aluminum or Al is an element in the group 3 and period 3, which has the atomic number of 13. The electron configuration of Al is 1s2 2s2 2p6 3s2 3p1. Al is a silvery white solid, and it is the most abundant metal in the earth crust. Al is not soluble in water at room temperature. Atomic weight of Al is about 27 g mol-1, and it is a light weighted, low density (but denser than water) and durable metal. It is a good electric conductor. Al does not easily ignite. Al is showing both metallic and non-metallic characteristics; hence, it is amphoteric. As a metal, it reacts with acids releasing hydrogen gas a form the +3 charged metal ion. As a non-metal, it reacts with hot alkali solutions and form aluminate ions. Since Al is too reactive to stay in its free form, naturally it occurs in minerals. Main Al containing mineral is bauxite. Large bauxite ores are located in Australia, Brazil, Jamaica and Guinea. It is also in the minerals such as cryolite, beryl, garnet etc. Al is largely used in automobiles and other vehicles manufacturing, construction, paints, for household items, packaging etc, due to its low density and resistance to corrosion. Pure aluminum is soft and lack in strength to use it, but it is mixed with other elements like iron or silicon (in small amounts) to increase the strength and hardness.
Aluminum is highly reactive, thus it is naturally occurring in oxides or hydroxide form, most of the time. Bauxite is a sedimentary rock type, which is the mineral ore of aluminum. It mostly contains aluminum hydroxide, Al(OH)3 and aluminum oxide (it is a mixture of gibbsite, boehmite and diaspore). In addition, there are iron oxides, hydroxides and other trace material mixed in it too. It has white, grey, red and yellowish color mixture. The mineral is translucent. Mainly, the bauxite deposits are in the tropical and subtropical areas and in Europe. Most of the bauxite is mined from surface mines, which have large blanket type deposits. Some are produced from underground excavations. Unlike some metal ores, bauxite is normally in good conditions, therefore, need less processing to purify it. This bauxite is then converted to alumina by chemical processes. Aluminum can be separated from alumina by an electrolysis process (Hall process). Bauxite is used as an abrasive, for cement, chemicals, makeup and other products.
What is the difference between Aluminum and Bauxite?
• Aluminum is an element; bauxite is a mixture of aluminum compounds and few other compounds.
• Bauxite is the main mineral ore of aluminum. It is remarkably easy and effective to harness aluminum from bauxite than from any other aluminum-containing mineral.
• Bauxite occurs naturally, but pure Al rarely occurs naturally.
• Aluminum is silvery white color whereas bauxite is yellowish, reddish brown color.
The key difference between endopeptidase and exopeptidase is that the endopeptidase breaks peptide bonds within the protein molecules while the exopeptidase cleaves peptide bonds at the terminals of the protein molecules. Proteins are important macromolecules, which are essential for most of the biochemical reactions occurring in all organisms. Different amino acids join together and form these proteins. Furthermore, enzymes catalyze the hydrolysis of proteins back into amino acids. They are specific enzymes called proteases or peptidases. Therefore, they have the capability to break down peptide chains of proteins into amino acids. Moreover, peptidases can be endopeptidases or exopeptidases. CONTENTS 1. Overview and Key Difference 2. What is Endopeptidase 3. What is Exopeptidase 4. Similarities Between Endopeptidase and Exopeptidase 5. Side by Side Comparison – Endopeptidase vs Exopeptidase in Tabular Form 6. Summary What is Endopeptidase? Endopeptidase is a type of protein-cleaving enzyme that breaks peptide bonds within the protein molecule........READ