Everything Everywhere Daily: History, Science, Geography & More - Titanium
Episode Date: July 15, 2023Titanium is the ninth most abundant element in the Earth’s crust. However, titanium is not even remotely close to the ninth most common element in industrial or commercial use. In fact, despite ...being so abundant, we didn’t even know titanium existed until the late 18th century, and we couldn’t figure out how to actually practically use it until the 1960s. It is a remarkable metal with amazing properties that is still incredibly hard to work with. Learn more about titanium, the amazing yet difficult metal, on this episode of Everything Everywhere Daily. Sponsors Expedition Unknown Find out the truth behind popular, bizarre legends. Expedition Unknown, a podcast from Discovery, chronicles the adventures of Josh Gates as he investigates unsolved iconic stories across the globe. With direct audio from the hit TV show, you’ll hear Gates explore stories like the disappearance of Amelia Earhart in the South Pacific and the location of Captain Morgan's treasure in Panama. These authentic, roughshod journeys help Gates separate fact from fiction and learn the truth behind these compelling stories. InsideTracker provides a personal health analysis and data-driven wellness guide to help you add years to your life—and life to your years. Choose a plan that best fits your needs to get your comprehensive biomarker analysis, customized Action Plan, and customer-exclusive healthspan resources. For a limited time, Everything Everywhere Daily listeners can get 20% off InsideTracker’s new Ultimate Plan. Visit InsideTracker.com/eed. Subscribe to the podcast! https://link.chtbl.com/EverythingEverywhere?sid=ShowNotes -------------------------------- Executive Producer: Charles Daniel Associate Producers: Peter Bennett & Thor Thomsen Become a supporter on Patreon: https://www.patreon.com/everythingeverywhere Listen on Podurama: https://podurama.com Update your podcast app at newpodcastapps.com Discord Server: https://discord.gg/UkRUJFh Instagram: https://www.instagram.com/everythingeverywhere/ Facebook Group: https://www.facebook.com/groups/everythingeverywheredaily Twitter: https://twitter.com/everywheretrip Website: https://everything-everywhere.com/ Learn more about your ad choices. Visit megaphone.fm/adchoices
Transcript
Discussion (0)
Titanium is the ninth most abundant element in the earth's crust.
However, titanium is not even remotely close to being the ninth most common element in industrial
commercial use.
In fact, despite being so abundant, we didn't even know titanium existed until the late 18th century
and we couldn't figure out how to actually practically use it until the 1960s.
It's a remarkable metal with amazing properties that still is incredibly hard to use.
Learn more about titanium, the amazing yet difficult metal on this episode of Everything
everywhere daily.
What if your perceptions about the past were wrong?
ThruLine is a podcast that takes you back in time to uncover the parts of the story
that may have gone unnoticed.
It effectively turned day into night.
And how it shaped the world now.
Time travel with us every week on the ThruLine podcast from NPR.
Titanium is the 22nd element on the periodic table.
It's a silvery metal that looks very similar to steel in its pure elemental state.
It has a very good strength to weight ratio, and it's highly resistant to corrosion.
It's a relatively poor electrical conductor compared to other metals, and it doesn't expand
or contract much when temperature changes.
It is also non-toxic and is considered to be biocompatible, which, as we'll see in a bit,
has many useful properties.
It is the ninth most abundant element in the earth's crust and the fourth most abundant metal.
The short story about titanium is that it's a metal with,
really attractive properties, and it's very abundant. You would think that such an attractive
metal would have been used throughout history. However, you'd be wrong. No one had a clue that titanium
even existed for most of human history. The reason why titanium remained hidden had to do with
its chemical proclivity to bond with pretty much anything. This is almost the opposite of how gold reacts,
which is why gold is almost always found in its natural metallic state. If you remember back to my
episode on aluminum, it's the opposite of gold, and it's very similar to titanium,
and that pure metallic aluminum almost never exists in nature. The difference between aluminum and
titanium is that whereas there were very few examples of pure aluminum, there are no known
examples of pure titanium. Humans in history were aware of and did use compounds that contained
titanium, but at the time they had no clue what elements were or that such compounds were made
up of more elementary things. The person who's credited with the discovery of titanium is British
clergyman and mineralogist William Greger. In 1791, he was studying samples of sand from Cornwall,
England, when he identified two oxide metals in the sand. One was iron oxide, and the other
was a white metallic oxide that he couldn't identify. He eventually concluded that this oxide must
contain a new element. He published his findings and named the new substance Monoconite.
Four years later, the German chemist Martin Heinrich Klapproth came across the same oxide that Gregor had discovered.
He too recognized that the material must be a new element, which he named titanium, after the Titans of Greek mythology.
Later Caproth heard of Gregor's discovery and obtained a sample of the sand that Gregor had studied from Cornwall and found that it was also titanium.
Claproth credited Gregor with the discovery of titanium, but it was his name for the element that stuck.
Both Claproth and Gregor had identified that there had to be a new new material.
element in the compounds that they studied, but neither of them was actually able to isolate the
element. Neither of them ever saw pure actual titanium. For over a hundred years, chemists continued
to study titanium, but no one was able to actually create a sample of pure titanium. They could
get it to bind with other elements, but they couldn't isolate it. There were certain things
that they were able to learn about titanium from these studies, but they weren't able to determine
its most important properties without pure titanium. They were however getting close, but
By the 1880s, Swedish chemists were able to make 94% pure titanium.
It wasn't until 1910 that Matthew Hunter, a scientist at General Electric and the Rensselaer Polytendic Institute,
used a variation of the Swedish process to finally produce metallic titanium.
He was searching for new potential light bulb filaments.
His process, known as the Hunter process, involved heating titanium tetrachloride with sodium
at temperatures as high as 800 degrees Celsius or 1,500 degrees Fahrenheit at very high pressures.
This allowed for the creation of titanium with purity levels over 99.9%.
While this was a breakthrough and it finally allowed researchers to study titanium as metal in its
pure form, it really had no practical application.
The process was too difficult and it could only produce very small amounts.
The idea of using titanium for something like a golf club was still a little.
a long way away. The breakthrough and the ability to create titanium for industrial use occurred in
1930, less than 100 years ago. A scientist from Luxembourg named William Kroll was running experiments
with titanium. Over a period of years, he developed a process of reacting titanium tetrachloride
with magnesium in a vacuum chamber. Known as the Kroll process, it creates an end product that is
called a titanium sponge. It's called a titanium sponge because it's very porous and looks like a
sponge, not because it's actually absorbent. A titanium sponge is mostly pure titanium
with some other impurities, mostly magnesium, that needs to be further refined. However, it's a starting
material and the biggest part of making titanium. By 1938, Kroll had been able to make over 50 pounds
of pure titanium metal, and use that to make simple metal objects such as wires and titanium
plates. In the 1940s, the U.S. Bureau of Mines began to investigate ways of producing titanium, and
determined that the Kroll process was the best means of commercial titanium production.
And while it's been improved over the years, the basic Kroll process is still used today.
During the Second World War, the Bureau of Mines was making 100 pounds of titanium per week using
the Kroll process.
100 pounds a week is still not a lot of metal.
You couldn't really build anything out of it.
But it did vastly expand the ability to conduct engineering experiments with the metal.
Samples were sent to laboratories and researchers discovered
many of the things that I mentioned at the start of this episode. It was as strong as stainless steel,
but weighed 40% less. It was resistant to corrosion, and it performed well at high temperatures.
People began envisioning airplanes, ships, and vehicles made out of titanium, and some thought it
could replace both aluminum and steel in industrial production. The press called titanium the wonder metal
and the miracle metal. In the early 1950s, at least two dozen companies in the United States announced
plans to create titanium. It was the tech boom of that era. However, there was a problem.
Titanium production was never able to match expectations. Only 75 tons of titanium was produced in
51, despite a demand for over 30,000 tons. Besides the big problem of simply making titanium,
now that they had some actual metal to work with, they found another very significant problem.
Titanium didn't behave like other metals. Everyone had just assumed that,
that they could repurpose the same machines that were used for stainless steel production.
Metal is metal, right? Well, it turned out that working with pure titanium was nothing like working
with steel. You couldn't forge, stamp, roll, or grind titanium like you could other metals.
For example, when drilling titanium, if you drilled it at speeds used on normal metals,
the temperature would rise dramatically, which damaged the drill bit. So you had to drill slower,
which took much more time. This made making anything extremely difficult.
The first attempt at trying to make a panel for an aircraft resulted in a sheet of metal
that could be ripped apart like a piece of paper.
All of the dreams about the miracle metal revolutionizing the world were falling apart.
The failure of pure titanium led to trying to find titanium alloys that would be easier to work with.
The eventual alloy, which was discovered and is still the most popular today, is 90% titanium,
6% aluminum, and 4% vanadium.
Perhaps the biggest event in the history of titanium was the development of the development,
of the high-speed reconnaissance spy plane known as the Lockheed A-12.
The A-12 was the predecessor to the SR-71 Blackbird, which was the subject of a previous episode.
The A-12 was to be the fastest aircraft in the world, something that could outrun any enemy missile.
As such, it would need to be very lightweight and have a skin that could handle the high temperatures
that would be created due to friction.
Titanium seemed to be the perfect metal for the job.
This was the biggest titanium project ever by a wide.
margin. Prior to the A12, titanium was primarily used for small parts and jet engines. The A12
was to be 93% titanium by gross weight. Construction of the A12 required the development of new
techniques for using titanium, and the discovery of even more problems. For example, they
discovered that water with chlorine in it actually caused the welds to weaken. Titanium bolts would
have their heads pop off if they were tightened with cadmium-coated wrenches. Every time one problem,
was solved, it seems they created another. A full 95% of the first 6,000 titanium components
created for the A12 couldn't be used. Eventually, they did solve many problems of working with titanium.
The creation of the A12, in a very literal sense, spawned the creation of the titanium industry.
It was from the production of the A12 that a base of knowledge was created in milling and
working with titanium. Another major discovery regarding titanium was made in
1952. In Sweden, an experiment with rabbits accidentally found that bone would bind with titanium
metal. This process, dubbed Osseo integration, had never been observed before. It had previously been
assumed that the body would reject any foreign substance. Further experiments found that the body
didn't reject titanium and that there were no negative consequences. Today, titanium is used for
screws and plates to mend broken bones, as well as in dental implants. Throughout the Cold War,
titanium was classified as a strategic mineral, so its use was limited. The U.S. Department of Defense
actually created a strategic stockpile of titanium sponges. These were to be used in projects which were deemed to be
spongeworthy. When the Cold War ended, titanium was reclassified, and in 2000, the titanium
sponge reserve was sold off. The end of the Cold War and the reclassification of titanium,
away from being a strategic material, changed the market for titanium. Whereas titanium was only used for
high-value items like aircraft parts, titanium was now available to be used for other purposes,
such as golf clubs, tennis rackets, and bicycle frames. The biggest use of titanium today,
by far, is titanium dioxide. Titanium dioxide is a very white pigment. A full 95% of all titanium
that is mined will end up as titanium dioxide. Titanium dioxide is used in paints,
plastics, paper, cosmetics, and even in toothpaste. It is extremely white, and, and, and, even in toothpaste. It is extremely
white, which means that it can reflect light and heat very well. The exterior of the Saturn
5 rockets used in the Apollo program was painted with titanium dioxide. Titanium is a very
odd element. It's very common in nature and has amazing properties, but it never fulfilled
its promise as the wonder metal. It never became as widespread as a similar metal that gained
popularity in the 20th century, aluminum. One big reason titanium isn't used more is that
it's just really hard to work with. More important than that is the fact that titanium
still remains relatively difficult to make, as we've never developed a process substantially
better than the Kroll process. If someone could develop such a system, it would have the
potential to usher in a true titanium revolution and finally allow this wonder metal to fulfill
its promise. The executive producer of Everything Everywhere Daily is Charles Daniel. The associate
producers are Thor Thompson and Peter Bennett. I just want to thank everyone.
including the show's producers who support the show over on Patreon.
If you'd like to support the show, just head over to patreon.com,
which is currently the only place where you can get show merchandise.
Also, if you want to talk to other listeners about the show,
head over to our Facebook group or Discord server,
both of which have links in the show notes.
