Today, we're going to talk a little bit about boron. First, we'll talk about its chemical properties. Then we'll look at where it's found and the mining process to extract boron from the ground.

After that, we'll look at some applications where boron plays a significant role. And then we'll finish up by looking at the market size and demand for boron.

Boron 101.

Today, we're going to talk a little bit about boron.

First we'll talk about its chemical properties.

Then we'll look at where it's found and the mining process to

extract boron from the ground.

After that we'll look at some applications where boron plays a significant role.

And then we'll finish up by looking at the market size and demand for boron.

Boron 101.

Boron is a non-metal element found in nature, bound to oxygen.

It's a brittle, dark, lustrous metalloid in its crystalline form with

two stable isotopes forming iconic bonds with air stable compounds,

such as boric acid and borax.

There are several forms of boron, including borates,

boric acid, and boron oxide.

The most common form is amorphous boron, which is a dark powder.

Boron has an atomic number of 5 with five protons and 5 electrons and its nucleus.

The nucleus contains 6 neutrons.

It has a melting point of 2,300 degrees centigrade or 2,573.15

Kelvins, 4,172 degrees Fahrenheit.

Its boiling point is 2,550 degrees centigrade or 2,823.15 Kelvins.

Where is boron found?

Boron is primarily found in borax, kernite, and in tincalconite,

which is hydrated sodium borates.

And it's mainly obtained from boron mines located in Turkey and the USA.

Argentina Chile, Russia, China and Peru.

In its natural state.

Boron has a low solubility, meaning it forms salts relatively easily.

Boron can be mined from minerals, such as colemanite colemanite,

ulexite, tincal, and kernite.

The borate ore is extracted through a combination of

drilling, blasting and shoveling.

The ore is then taken to crushing machines and then transported to refinery centers,

where it is processed into products such as borax, borax pentahydrate,

borax decahydrate, and boric acid..

A further process for extracting boron from brines of natural or industrial salt

mines has been developed, including the steps of reacting borates contained in the

brine with a hydrochloric acid solution.

This forms precipitates, which are separated from the brine by

filtration or centrifugation.

The brine is then subjected to one or more extraction stages via solvents to

extract any remaining boron content.

Boron is used in various traditional applications, including fertilizers, glass

production, detergents and pharmaceuticals with exciting new uses found in

decarbonization and advanced energy.

Boron is an essential micronutrient for plant growth and health, playing a role

in cell walls and reproductive structures.

It can be added to fertilizers either by blending with dry, granular

fertilizers or mixing with liquid fertilizers but over application

of boron can lead to crop damage.

Boron is also an important component in glass production.

It significantly lowers the melting temperature required for glass production.

Borates are used in manufacturing to provide strength, resilience,

and resistance to thermal shock, chemicals and scratches.

Boron oxide is also used in insulation and textile glass production.

Borosilicate glass is a type of glass with silica and boron trioxide as

the main glass forming constituents.

Boron is used also in detergents to lower water-based solutions,

surface tension and to produce household or industrial cleaners,

laundry detergents, and hand soaps.

It's also added to liquid laundry detergents up to 2% concentration

to stabilize the protease and other enzymes in the formulation.

Sodium perborate requires hot water of 60 degrees centigrade

to undergo hydrolysis unless an activator such as boron is present.

Boron-containing compounds are used in medicinal chemistry to improve

the pharmacokinetic properties of anti estrogens based on their

glycogen binding capability.

It's also used as a protecting group that's released from the active drug

and as the active drug component.

It has been approved for human use in clinical trials such

as paraboronophenylalanine for boron nutrient capture therapy.

Boron and boric acid are also found in many pharmaceutical applications

including eyedrops, bone development, osteoarthritis treatment, and more.

Boron notably plays a vital role in decarbonization by reducing greenhouse gas

emissions and providing multiple benefits that support carbon footprint reduction.

It can also help replace more carbon intensive materials and processes

in industries, such as through the adsorption of large amounts of carbon.

Boron's also being used in energy transition to mitigate climate change,

using renewable energy, electrical, energy efficiency, and electric mobility.

Boron is being used as an advanced energy material due to its unique properties.

It's a good conductor of electricity, extremely strong and lightweight and can

provide portable energy sources serving as catalysts in chemical reactions,

and potentially be used as electrode materials in lithium-ion batteries.

Boron based furan polymers are a new class of renewable energy materials based

on boron that are highly biodegradable.

Additionally boron compounds have been studied for their potential

applications in small molecule activation, hydrogen storage, electrolytes.

OLEDs and metal-ion batteries.

Boron is being further researched in a number of fuel cell ideas

that use boron alloys as catalysts.

Hydrogen boron fusion energy is a promising energy source for transportation

and vehicles and sodium borohydride solution and potassium borohydride can

be used to power small fuel cells.

Direct borohydride fuel cells (DBFCs) are a subcategory of alkaline fuel cells,

which are directly fed by sodium sodium borohydride or potassium borohydride.

Boron has a very high energy density, much better than that of petroleum, which makes

it an attractive alternative motor fuel.

The global boron market size was valued at $1.98 billion in 2021 and is projected

to reach $2.78 billion by 2029 growing at a compound annual growth rate of

4.3% during the forecast period 2023.

to 2032.

The United States holds nearly one fifth of the world's boron

resources and is a net exporter.

Major producers include Eti Maden of Turkey, Rio Tinto, Australia, US Borax,

United States, Searles Valley Minerals, United States, Minera Santa Rita, Mexico.

Borax Argentina, Argentina, Quiborax, Chile, and 5e Advanced Materials

, formerly American Pacific Borates, which is currently the latest and

only permitted source of boron in the last 20 years, based in the

United States in Southern California.

And that concludes our short introduction to boron.

For more information on all other aspects of boron and more depth articles

and news and podcasts and videos, please go to borates.today today.