The success of engineers who
have managed to bring energy storage technologies to an acceptable level of
cost has provoked explosive growth in proposals for wearable electronics. With
all the variety of models, features, prices, and brands, they have something in
common - a burning passion for batteries.
The need for batteries was so acute that we willingly turned a blind eye to many of their shortcomings. Suffice it to recall the nickel-cadmium and nickel-metal hydride versions with the notorious "memory effect". Although in fairness it should be noted that they still firmly hold their positions in the segment of devices that require high operating currents and stability in harsh operating conditions. Handheld power tools such as drills and screwdrivers, flashlights, electric cars, on-board power supplies for ships and aircraft - all of this remains a vast and conservative habitat for nickel-cadmium batteries.
But there are many more mobile phones and other gadgets! And yet, if we take into account that the battery of a simple smartphone has about 3 grams of "energetic" metal, and in a laptop - 3 times more, then the total mass of lithium in a hundred million devices is not that big.
In any case, the 15 thousand
tons mined at the beginning of the new millennium was also enough for the
production of glass and ceramics (a third of world consumption), lubricants
(for example, lithol, well-known to motorists) and polymers. Power engineers
took their share for the needs of nuclear reactors, in which lithium acts as a
coolant.
But by 2010, lithium
consumption exceeded 500 thousand tons. The most "voracious" buyers
of metal were the manufacturers of batteries, invented by Sony in 1991. Even
then, at the dawn of the "lithium rush", the newest batteries achieved
a record specific energy density, exceeding previous achievements by 3-4 times.
Surprisingly, it’s true: the current lithium batteries have maintained record
levels of thirty years ago, having changed constructively only from a safety
point of view.
Lithium technologies, which at
one time marked a breakthrough and revolution, found themselves in a
fundamental impasse. Of course, they are being improved, and quite intensively,
acquiring flexibility, resistance to thermal overload, and the like. But in the
main - the specific density of stored energy - the increase does not exceed a
few percent. However, neither today nor in the near future, battery revolutions
threaten us. Sodium, graphene, radioisotope, organic, and other promising power
sources have not yet left the stage of experiments and for another five years,
they will not be able to compete with lithium cells in at least one parameter -
cost. This means that lithium is doomed to ensure our mobility and readiness to
be “always in touch” for a long time.
The plans of the Australian
(and not only) authorities include the construction of such storage facilities
in all parts of the continent, which is poor in traditional energy resources.
However, good intentions run into one small problem: the implementation of this
program requires at least 500 thousand tons of lithium, which is simply nowhere
to be found.
There are enough reasons for
alarm. Most of them are associated with the properties of lithium itself, the
lightest metal in nature. In theory, it should be very, very much, because in
the periodic table it follows immediately after hydrogen and helium, the most common
chemical elements in the Universe. However, it is this "lightness"
that contributes to the outstanding chemical activity of lithium, because of
which it is not found in its pure form on Earth. Strong oxidizability forces it
to be stored in petroleum jelly or paraffin, which protects the metal from
contact with atmospheric oxygen.
According to scientists, lithium salts dissolved in the ocean (0.17 mg / l) pull a total of half a trillion tons, about the same amount (21 g / t) is contained in the earth's crust. But all this wealth is ephemeral: extracting lithium, for example, from seawater is too expensive both in terms of energy and cost. The only economically viable method of industrial production of lithium today is associated with the peculiarities of its deposits.
The extraction of lithium is
a process that changes the landscape beyond recognition and, most importantly,
poisons the scarce supplies of local freshwater with salt and chlorine
(chlorine is used to neutralize toxic compounds of lithium and magnesium). The
basis of the process is brine, a supersaturated saline solution. To obtain it,
mines up to 40 meters deep or trenches are punched into which freshwater is
pumped. Then the brine, similar to slushy snow, rises to the surface.
There, in dozens of man-made pools the size of a hockey rink, the brine is brought to a standard in the sun during the year, when the concentration of lithium increases to 5-6%. Then it is pumped into cisterns and taken to a refinery. From it, battery manufacturers get a snow-white powder, similar to flour - refined, dried, and granular carbonate or lithium chloride at a price that breaks all records in terms of growth dynamics (more than 40% per year). For his sake, the poor desert landscape is literally "burned out" to cosmic sterility.
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