Boron is a chemical element classified among the nonmetals in the periodic table and is utilized in various industrial processes. It does not occur freely in nature but is instead found in the form of compounds, primarily in borate minerals.

^{Image Showing the Position of the Element Boron in the Periodic Table}^{(Tenmak Boren)}

Definition and General Properties

Boron (B) is a nonmetal with the atomic number 5, exhibiting semiconducting properties. Physically, it can be found in either a brittle, crystalline form or in an amorphous structure. Due to its high thermal resistance, chemical stability, and neutron absorption capability, boron is valuable in advanced technological applications.

Occurrence and Reserves

Boron is not found in its elemental form in nature; instead, it occurs primarily as borate minerals. Turkey holds the majority of the world’s boron reserves (approximately 73%), with major production centers located in Kırka, Emet, Bigadiç, and Bandırma.

Production Technologies

Boron ores are refined through various physical and chemical processes. These include flotation, precipitation, filtration, and crystallization methods. Final products include boric acid, borax decahydrate, anhydrous borax, and sodium perborate. These processes are evaluated both in terms of chemical engineering and environmental sustainability.

^{Element Boron}^{(Tenmak Boren)}

Chemical Compounds and Structures

Boron forms a wide range of compounds, among which the most common are:

Boric Acid (H₃BO₃): Used as an antiseptic and a glass additive.
Borax (Na₂B₄O₇·10H₂O): Used in detergents and as a flux in metallurgy.
Boron Carbide (B₄C): A very hard material used in armor and abrasives.
Boron Nitride (BN): Serves as a high-temperature insulator and thermal conductor.

These compounds share common characteristics such as high thermal resistance, varying electrical conductivity, and chemical inertness.

Industrial Applications

Glass and Ceramics: Boron enhances the thermal and chemical resistance of glass and contributes to gloss and durability in ceramic surfaces.
Agriculture: It is an essential micronutrient for plant growth, and its deficiency can negatively affect crop quality.
Detergent Industry: Cleaning products containing sodium perborate function as bleaching agents and water softeners.
Metallurgy: Used as a grain refiner, fluxing agent, and strength enhancer in alloys.
Electronics and Semiconductors: Due to its semiconducting properties, it is utilized in high-tech devices.
Energy Technologies: Research is ongoing into its role in hydrogen storage systems and rocket propellants.

Use in Nuclear Reactor Technology

Boron, especially its isotope boron-10, has a high capacity for neutron absorption. This makes it a critical material in pressurized water reactors, where it functions as a control rod material or coolant additive. It is used in liquid systems in the form of boric acid, and in solid form as boron carbide. Its role is vital for nuclear safety.

Strategic Importance and Economic Value

Due to its industrial versatility and strategic uses such as in nuclear energy, boron is classified as a critical raw material. Institutions like the European Union and the United States have designated it a "strategic resource." Turkey’s leadership in boron reserves presents both economic and technological opportunities.

Toxicological and Ecological Assessments

Although boron is considered to have low toxicity, high doses can be harmful to both humans and the environment. The World Health Organization (WHO) has set the limit for boron in drinking water at 2.4 mg/L. This threshold must be carefully observed in agricultural irrigation and aquatic ecosystems. The effects of boron compounds on human health, particularly in terms of reproductive health and kidney function, are subjects of ongoing research.

Boron Element