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Chapter 22: Problem 6

Aluminum is widely distributed throughout the world in the form of aluminosilicates. What property of these minerals prevents them from being a source of aluminum?

Short Answer

Expert verified
The strong and stable bonds in aluminosilicates make aluminum extraction energy-intensive and costly.

Step by step solution

01

Understand the Composition of Aluminosilicates

Aluminosilicates are minerals composed of aluminum, silicon, and oxygen. These minerals form very stable structures due to strong bonds between the elements.
02

Identify the Bond Characteristics

The aluminum in aluminosilicates is bound in a crystal lattice with silicon and oxygen. This bonding is quite strong and energy-intensive to break, making it difficult to extract aluminum.
03

Consider the Extraction Process

The extraction of aluminum from aluminosilicates would require breaking these strong bonds. This process is not only energy-intensive but also costlier compared to extracting aluminum from more easily processed minerals like bauxite.
04

Compare with Other Aluminum Sources

Compare the difficulty of extracting aluminum from aluminosilicates versus from bauxite. Bauxite is preferred for aluminum extraction because its chemical composition allows for a more straightforward and less energy-intensive extraction process.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

aluminosilicates
Aluminosilicates are a group of minerals composed of aluminum, silicon, and oxygen. They are found widely distributed across the Earth's crust. These minerals are known for their incredibly stable structures, resulting from strong bonds between aluminum, silicon, and oxygen atoms. Because of this stability, extracting aluminum from aluminosilicates requires a significant amount of energy. The chemical bonds within aluminosilicates are so strong that breaking them is not practical for aluminum extraction purposes. Understanding the robust nature of these bonds explains why aluminosilicates are not a common source of aluminum.
crystal lattice
A crystal lattice is a repeating three-dimensional structure formed by atoms, ions, or molecules. In the case of aluminosilicates, the aluminum atoms are embedded within a lattice of silicon and oxygen atoms. This lattice framework provides a highly ordered structure, contributing to the mineral’s stability. Due to the tightly bound atoms in a crystal lattice, a substantial amount of energy is required to disrupt this arrangement to extract individual elements like aluminum. The strength and stability of the crystal lattice are key factors making aluminosilicates impractical for aluminum extraction compared to more easily broken down minerals.
bauxite
Bauxite is the principal ore of aluminum and is preferred for aluminum extraction. It primarily contains aluminum hydroxide minerals, which are much easier to process compared to aluminosilicates. The chemical bonds in bauxite are weaker, allowing for a more straightforward and less energy-intensive extraction process. The extraction involves the Bayer process, where bauxite is dissolved in sodium hydroxide, separating aluminum oxide from impurities. The ease and efficiency of extracting aluminum from bauxite make it the most economically viable source, which is why it is extensively used over more complex minerals like aluminosilicates.

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Most popular questions from this chapter

Because of their different molar masses, \(\mathrm{H}_{2}\) and \(\mathrm{D}_{2}\) effuse at different rates (Section 5.5 ). (a) If it takes 16.5 min for \(0.10 \mathrm{~mol}\) of \(\mathrm{H}_{2}\) to effuse, how long does it take for \(0.10 \mathrm{~mol}\) of \(\mathrm{D}_{2}\) to do so in the same apparatus at the same \(T\) and \(P ?\) (b) How many effusion steps does it take to separate an equimolar mixture of \(\mathrm{D}_{2}\) and \(\mathrm{H}_{2}\) to \(99 \mathrm{~mol} \%\) purity?

Which set of elements gives cach of the following alloys: (a) brass; (b) stainless steel; (c) bronze; (d) sterling silver? 1\. Cu, Ag 2\. \(\mathrm{Cu}, \mathrm{Sn}, \mathrm{Zn}\) 3\. Ag. Au 4\. Fe, Cr, Ni 5\. Fe, V 6\. \(\mathrm{Cu}, \mathrm{Zn}\)

The location of elements in the regions of Earth has enormous practical importance, (a) Define differentiation, and explain which physical property of a substance is primarily responsible for this process. (b) What are the four most abundant elements in the crust? (c) Which element is abundant in the crust and mantle but not the core?

Hydrogen is by far the most abundant element cosmically. In interstellar space, it exists mainly as \(\mathrm{H}_{2}\). In contrast, on Earth, it exists very rarely as \(\mathrm{H}_{2}\) and is ninth in abundance in the crust. Why is hydrogen so abundant in the universe? Why is hydrogen so rare as a diatomic gas in Earth's atmosphere?

Phosphorus is one of the impurities present in pig iron that is removed in the basic-oxygen process. Assuming that phosphorus is present as \(\mathrm{P}\) atoms, write equations for its oxidation and subsequent reaction in the basic slag.
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