Question

Calcium minerals are the raw materials for a variety of large-scale industrial processes. Which of the following is not an industrial process? (a) Converting limestone, \(\mathrm{CaCO}_{3}\), to lime (b) Converting fluorite, \(\mathrm{CaF}_{2},\) to HF (c) Converting slaked lime, \(\mathrm{Ca}(\mathrm{OH})_{2}\), to lime (d) Converting apatite minerals to phosphate fertilizers

Short answer

Option (c) is not an industrial process.

Step-by-step solution

Identify Each Industrial Process

We need to evaluate each of the given options to determine if they are recognized industrial processes. Industrial processes involve specific chemical transformations often used in manufacturing or production on a large scale.

Evaluate Option (a)

Converting limestone, \( \text{CaCO}_3 \), to lime involves thermal decomposition to produce lime (CaO) and carbon dioxide. This is known as the calcination process and is commonly used in the cement and lime industries. Hence, it is an industrial process.

Evaluate Option (b)

Converting fluorite, \( \text{CaF}_2 \), to HF (hydrofluoric acid) is an industrial process where fluorite reacts with sulfuric acid to produce hydrogen fluoride gas and calcium sulfate. This process is essential in producing HF for various industrial applications. Hence, it is categorized as an industrial process.

Evaluate Option (c)

Converting slaked lime, \( \text{Ca(OH)}_2 \), to lime (CaO) is not a common industrial process. Slaked lime is usually the product, not the precursor, in industrial processes. Typically, lime (CaO) is made from limestone, not from slaked lime, in industrial settings. Thus, this does not fit the typical definition of an industrial process.

Evaluate Option (d)

Converting apatite minerals to phosphate fertilizers is a significant industrial process. Apatite is mined and processed into different forms of phosphate fertilizers commonly used in agriculture. Hence, it is indeed a known industrial process.

Determine the Incorrect Industrial Process

From the analysis, options (a), (b), and (d) are recognized industrial processes. Option (c) does not follow the typical pattern of industrial processes and does not fit within standard industrial manufacturing. Therefore, it is not an industrial process in the context provided.

Key concepts

Calcium Minerals

Calcium minerals are foundational in numerous industrial activities. Calcium carbonate, for example, is a widespread calcium mineral known as limestone. It's an essential material used in a variety of industrial processes. Calcium minerals provide the necessary chemical building blocks for products like cement and agricultural lime.
Another important calcium mineral is fluorite, or calcium fluoride (\( \mathrm{CaF}_2 \)), often used in chemical manufacturing. Apatite, rich in calcium phosphate, is important in the production of phosphate fertilizers.

• Limestone transforms into lime under heat.
• Fluorite is used to create hydrofluoric acid.
• Apatite is crucial in fertilizer manufacturing.

These minerals have immense value because of their chemical properties and availability, making them indispensable in various industrial applications.

Chemical Transformation

Chemical transformation is a cornerstone of industrial processes. It involves a change in the chemical makeup of a substance. One remarkable chemical transformation is the thermal decomposition of calcium carbonate (limestone) to form calcium oxide (lime) and carbon dioxide. This is known as a calcination process.
Another transformation occurs when fluorite reacts with sulfuric acid to form hydrofluoric acid. Such processes alter the initial raw material into a different compound, often with beneficial industrial uses.

• Calcination involves heating to cause transformation.
• Chemical transformations are vital in production.
• They convert raw materials into useful products.

Each transformation is driven by specific conditions such as temperature and pressure, enabling the efficient production of materials needed for various industrial applications.

Lime Production

Lime production is an essential industrial process that primarily involves the calcination of limestone (\( \mathrm{CaCO}_3 \)). When subjected to high temperatures, limestone decomposes into lime (calcium oxide, \( \mathrm{CaO} \)) and releases carbon dioxide. This lime is crucial in construction, agriculture, and even in chemical manufacturing processes.
Traditional lime production often involves large kilns where limestone is processed. Lime is usually further transformed into slaked lime (calcium hydroxide, \( \mathrm{Ca(OH)}_2 \)) when mixed with water.

• Calcination of limestone is the key to lime production.
• Lime is vital for construction and soil treatment.
• Slaked lime results from adding water to lime.

Lime and its derivatives play a significant role in neutralizing acidic soils and treating wastewater. It's indeed a fundamental part of many industrial sectors.

Phosphate Fertilizers

Phosphate fertilizers are the result of processing apatite minerals. Apatite, rich in phosphorous, is a vital resource for agriculture. It is processed to produce phosphoric acid, which in turn is used to make various phosphate-based fertilizers. These fertilizers are crucial for plant growth, providing essential nutrients that improve agricultural yields.
The production of these fertilizers involves mining the phosphate rock and subjecting it to chemical processes that extract phosphorous in a plant-usable form.

• Phosphate fertilizers enrich the soil with phosphorus.
• They are derived from processed apatite minerals.
• They are key to high-yield agricultural practices.

With improved fertilizers, farmers can cultivate more robust crops, supporting larger populations and helping ensure food security across the globe.