As a general rule, the most successful man in life is the man who has the best information
Sometime between 1500 and 1565 a large graphite deposit was discovered in Cumbria, England. Because the graphite was extremely pure and solid it could easily be sawed into sticks. The graphite was actually thought to be a form of lead and called plumbago – Latin for lead ore.
The Borrowable Mine was soon ordered to be put under armed guard by Queen Elizabeth because the “lead” could be used to line the moulds for making her armies cannonballs. But black marketers managed to smuggle out the graphite for continued use in pencils. Artists from all over the known world quickly learned to appreciate the qualities of Cumbria’s graphite but it wasn’t until 1795 that Nicholas Conte learned to mix graphite powder with clay and fire it in a furnace to actually make something with the equivalent quality of Borrowables plumbago.
Today graphite (named for the Greek word meaning "to write") is attracting the attention of investors, and for just as good a reason as it once attracted artists 500 years ago.
By mass carbon is the fourth most abundant element in the universe (after hydrogen, helium, and oxygen) and it’s the 15th most abundant element in the Earth's crust. Carbon is present in all known life forms and is the second (oxygen is first) most abundant element by mass - about 18.5% - in the human body.
Carbon is the stuff of life, it is the foundation, the chemical basis, of every living thing on Earth, yet because of its pervasive familiarity we all take it for granted. As investors we might want to rethink that.
Allotropes are structural modifications of an element - the allotropes of carbon include:
- Diamond - The carbon atoms are bonded together in a tetrahedral lattice arrangement
- Fullerenes - The carbon atoms are bonded together in spherical, tubular, or ellipsoidal formations
- Graphite - The carbon atoms are bonded together in sheets of a hexagonal lattice
- Graphene - A flat two-dimensional sheet of carbon atoms
Graphite has long been used in the aviation, automotive, sports, steel and plastic industries, as well as in the manufacture of bearings and lubricants. Graphite is an excellent conductor of heat and electricity, is corrosion and heat resistant, and is also strong and light.
Currently, the automotive and steel industries are the largest consumers of graphite and demand across both industries is rising at five percent per annum.
The steel industry uses graphite as liners for ladles and crucibles, they use it in the bricks that line blast furnaces and to increase the carbon content of steel. Graphite has already replaced asbestos in automotive brake linings and pads and is used for gaskets and clutch materials. Sparks plugs are also made incorporating graphite.
But demand for graphite has been rising for other applications as well: in the form of flexible graphite sheets, and in such applications as lithium-ion and vanadium batteries, fuel cells, semi conductors, and components used in the nuclear, wind and solar power sectors.
Graphoil (flexible graphite sheets) is one of the fastest growing graphite markets. Flexible graphite is desirable for compression packing and gaskets, offering the ability to seal by means of filling gaps in order to retain fluid.
Flexible graphite products have valuable properties:
- Free from creep under constant load
- Stable in cryogenic temperatures far below zero to temperatures well above the melting point of most ferrous and non-ferrous metals
- Resists a wide range of corrosive materials
- Nuclear-radiation-resistant even when exposed to massive doses of radiation
- Fire-safe in the presence of highly volatile fluids and extremely high temperatures
Graphite plays a key role in many current, and future, nuclear reactor designs. The next generation nuclear reactor (the INL-led Next Generation Nuclear Plant [NGNP] and other proposed high-temperature, gas-cooled reactors) will generate temperatures that are expected to reach as high as 1,000 °C in their cores. Graphite, having a higher melting point then steel, doesn't burn until temperatures reach 3,000 degrees Celsius. Because graphite has a huge heat-absorbing capacity, it’s also used to keep nuclear fuel at safe temperatures during unexpected events. As an aside, graphite is also used as a heat sink in computers.
China’s Pebble bed reactors (PBR) are a graphite moderated, gas cooled nuclear reactor. The base of the PBR's design is the spherical (billiard ball-sized) fuel elements called pebbles. In the PBR, thousands of pebbles are amassed to create a reactor core. The pebbles are made of pyrolytic graphite (a protective graphite coating that moderates the pace of nuclear reactions) and they contain thousands of micro fuel particles called TRISO particles, which consist of a fissile material such as 235U. These reactors are cooled by non-explosive helium gas instead of depending on a steady source of water.
Substantial amounts of graphite are required to charge the reactor at startup – about 3,000 tons – and a percentage of the balls must be replaced each year as the fuel is spent, necessitating a further 600 to 1,000 tons of graphite each year of operation. China has one operating prototype, is now building two commercial units, and plans to have 30 Pebble Bed nuclear reactors in operation by 2020.
The two major types of fuel cells – the phosphoric acid fuel cell (PAFC) and the proton electrolyte membrane fuel cell (PEMFC) – currently under development rely heavily on graphitized carbon. PAFCs are for stationary power generation (primary or backup power for remote locations such as cell phone towers), whereas PEMFC's have attracted widespread interest for use in transportation applications.
A fuel cell is not a battery. A battery is an energy storage device. It will stop producing electrical energy when the chemical reactants are consumed or it needs to be recharged. The fuel cell is an energy conversion device and will produce electrical energy as long as the fuel, and the oxidant, are fed to the electrodes.
More and more fuel-cell applications are in development every year and fuel cell technologies rely heavily on graphite. The proton exchange fuel cell (PEMFC) requires 80-100 lbs of graphite per vehicle.
"Large-scale fuel cell applications are being developed that could consume as much graphite as all other uses combined." U.S. Geological Survey
Solar Thermal Collectors
The biggest limitation of Solar or Photovoltaic (PV) panels is that they can use only a fraction of the sunlight that hits them, the rest of the sunlight turns into heat which actually hurts the performance of the panels. An alternative that can make use of all of the sunlight, including light frequencies PVs can't use, is the solar thermal collector – they collect heat that’s used to boil the water to make the steam which drives the turbine which creates the electricity.
To further increase the efficiency of solar collectors, nanoparticles - particles a billionth of a meter in size - are added into the heat transfer oils normally used in solar thermal power plants. In laboratory tests nanoparticles increased heat collection efficiency by up to 10 percent. 100 grams of nanoparticles provides the same heat-collecting surface area as an entire football field.
Graphite nanoparticles are very efficient heat collectors.
Vanadium Redox Batteries
When the sun doesn’t shine and the wind doesn’t blow, neither solar nor wind plants are generating electricity. These two green energies need batteries to store the excess energy they can produce under optimal conditions. The vanadium redox battery (VRB) could be the perfect answer as they:
- Have unlimited capacity simply by increasing the size of their storage tanks
- Can be left completely discharged for long periods of time with no ill effects
- Have low maintenance requirements
- Can be recharged by simply replacing the electrolyte
- Have a nominal environmental footprint
VRB’s also require almost 300 tonnes of flake graphite per 1,000 megawatts of storage capacity.
The most important application for increased graphite demand might come from the lithium-ion batteries found in electric vehicle batteries and used to power our modern consumer electronics.
While lithium is the cathode the anode is graphite and these batteries need 10 to 30 times more graphite than lithium (depending on which expert you listen to). The lithium-ion battery industry is growing at a 30-40% annual rate.
As many as six million electric vehicles might be manufactured in 2020, each of them requiring 40 lbs of graphite for its battery system – the electric motorcycle and scooter markets are growing even faster.
Lithium-ion batteries are also crucial to the consumer electronics industry for applications as varied as power tools, cell telephones, laptops, tablets and media players.
If you took a close look, a very close look, at a graphite pencil lead you will see layer upon layer of carbon atoms, multiple two dimensional planes that are loosely bonded to their neighbors.
The reason graphite works so well as a writing material, and industrial lubricant, is because the layers of atoms slip easily over one another. The layered structure facilitates easy cleavage along the planes.
Each of those single layer of atoms is grapheme. Separating the individual layers of graphite sets the electrons free and allows carbon to behave differently.
Graphene has unique combinations of optical, electrical and mechanical properties:
- Astonishing electrical conductivity - Graphene has the highest current density (a million times that of copper) at room temperature; the highest intrinsic mobility (100 times more than in silicon); and can carry more electricity more efficiently, quickly, and with more precision than any other material.
- Graphene also beats diamond in thermal conductivity; it's better than any other known material.
- It is the thinnest and strongest material known to man; 200 times stronger than steel, is almost invisible and weightless, and stretches like rubber; graphene can stretch up to 20% of its length, and yet is the stiffest known material, even stiffer than diamond.
- Graphene is the most impermeable material ever discovered.
Graphene is transparent in infra-red and visible light, absorbing just 2.3% of light that lands on it. But with your naked eye, you can see a single layer of graphene laid on a blank piece of white paper.
Indium Tin Oxide (ITO), the current touch screen material of choice, absorbs 10% of incident light, but it’s quite brittle, the exact opposite of graphene. Graphene is ideal for use in touch screens.
According to some reports the world has only 5-10 years of ITO reserves remaining and prices already exceed US$700,000 per tonne.
Photovoltaic (PV) Cells
Graphene has no band gap; everything is accepted. What this means is that graphene solar panels have a huge advantage over silicon solar panels. Graphene can absorb light from all over the solar spectrum, whereas silicon is confined to certain frequencies. That makes graphene solar panels much more efficient than any other material. Instead of waiting 10-12 years for payback, it might come as quickly as five years.
It is possible to induce a small band gap in graphene by doping it, which means grapheme can be used a transistor. You need the band gap if you want to be able to turn the transistor off.
Spintronics is a technology for controlling not only individual electronics, but also their spin, this increases the amount of information that can be stored per electron - data is stored in the spin of an electron, not its presence. Since graphene has a long spin diffusion length, the technology promises to increase the efficiency with which devices consume power and increase data storage capability.
Superconductivity At Room Temperature
The mean free path is the distance an electron can travel freely without bumping into something, or having its path disrupted by scattering – both cause resistance which means heat is generated. In graphene, the mean free path is 65 microns, long enough that electronic components could be made that would operate at ambient temperatures with virtually no resistance. We’re talking ambient temperature unimpeded conduction of electrons – superconductivity at room temperature.
Graphene is the most impermeable material ever discovered, not even helium atoms can squeeze through. Highly sensitive gas detectors can be manufactured because the smallest quantity of a gas will get caught in its lattice producing an electrical signal that flags the presence of the chemical.
Medical imaging devices that won’t do the harm X-rays cause are possible using graphene, as are strain sensors. When you pull or push the strain can be monitored. This could be useful for buildings in earthquake prone areas or in airplane wings.
If you pass a strand of DNA through a sheet of grapheme with a small gap in it, the electrical properties of graphene change on exposure to each base pair. Because graphene is 2D, it can "read" one base at a time, making it much more accurate than anything used today.
All the chemical derivatives of graphene are useful. You can dissolve graphene, and the solutions (fluorographene, graphene oxide, hydrogenated grapheme) have applications in printable electronics that are already 10 times better than current state of the art technology.
In 2010 a European Commission included graphite among the 14 materials it considered high in both economic importance and supply risk. The British Geological Survey listed graphite as one of the materials to most likely be in short supply globally.
The US government has also declared graphite a critical material. The US Department of Homeland Security, and the State Department, said the country could be hurt if terrorists were to disable graphite mines in China.
The natural graphite market is 1-1.2 million tonnes per year and utilizes several foms of graphite: flake, amorphous and lump. Historical applications primarily use amorphous and lump graphite, while most newly emerging technologies and applications use flake graphite. About 40% of the estimated 1.2 million tonnes of graphite that are processed each year is flake.
China, India and Canada are responsible for most graphite mining and processing, with China producing the lion’s share at 70–80%. China’s production is 70% amorphous and lower-value small flake graphite.
Currently China imports a significant amount of North Korea’s large flake graphite production, raising considerable doubts in regards to China’s abilities to ramp up its graphite supply. Indeed China has already taken steps to retain its graphite resources by restricting its export quota. China imposed a 20% export duty, a 17% VAT and also closed state owned enterprises.
“The days of cheap, abundant graphite from China are over.” Industrial Minerals Magazine May, 2011
It’s thought that the increased use of lithium-ion batteries could gobble up well over 1.6 million tonnes of flake graphite per year by 2020. Only flake, upgraded to 99.9% purity, and synthetic graphite (made from petroleum coke using a relatively expensive process) can be used in lithium-ion batteries.
“Annual flake graphite production will have to increase by a factor of six by 2020 to meet incremental lithium carbonate requirements for batteries.” Canaccord research report
The US Geological Survey says large-scale fuel cell applications are being developed that could consume as much graphite as all other uses combined. This is a bold statement, but even if only half of the USGS demand is realized, graphite use is going to explode just because of fuel cells, let alone other known demand drivers and new applications.
What if the current market almost doubles? New demand between now and 2020 could total as much as 1 million tonnes on top of the existing 1.2 million tonnes of demand.
Today’s graphite producers, other than the ones in China, are going to have to produce more, and junior companies are going to have to get busy and start to develop deposits. There will be a premium placed on mines in stable, safe areas for investment.
A large scale producer puts out 20,000 to 40,000 tonnes per year. That implies a need for a lot of new mines... and a lot of opportunity for investors. A million tonnes divided by 40,000 could be the equivalent of up to 25 new mines needed to meet growing demand.
Consider also that most of the mines expected to come online, and the ones already in production, will not produce the highest grades of graphite. The highest grade is crystalline large flake, which runs between 94% and 97% carbon and starts at 80 or higher mesh size. Most new mines will probably produce medium, small-flake, lump, or amorphous graphite.
The extraction of graphite and its processing is very well known in western countries, which are the leaders in graphite and graphene application research.
China is not going to be much of a factor in the large flake graphite market, except perhaps as a future importer. The West has large flake graphite deposits, knows how to extract and refine the graphite, and leads in technological advancements.
New high-tech applications require more and more graphite production while graphene seems to be a wonder material. A lot of time, effort and money is being spent researching it, with 3,000 research reports written on the subject in 2010 alone.
An investor needs to be doing due diligence on junior resource companies with near surface, high grade large flake deposits close to all necessary infrastructure in politically safe jurisdictions.
Graphite should be on every investors radar screen. Is it on yours?
If not, maybe it should be.
If you're interested in learning more about a specific graphite junior, the junior resource sector, bio-tech and technology sectors please come and visit us at www.aheadoftheherd.com
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Richard Mills has based this document on information obtained from sources he believes to be reliable but which has not been independently verified; Richard Mills makes no guarantee, representation or warranty and accepts no responsibility or liability as to its accuracy or completeness. Expressions of opinion are those of Richard Mills only and are subject to change without notice. Richard Mills assumes no warranty, liability or guarantee for the current relevance, correctness or completeness of any information provided within this Report and will not be held liable for the consequence of reliance upon any opinion or statement contained herein or any omission.
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