The principle of magnetic storage used by most hard drives is
an important pillar in the evolution of modern digital world. Before the advent
of flash memory, it dominated the way we saved our data. Simply speaking, binary
information (0 or 1) is presented by small magnets pointing forward (0) or backward
(1); let’s say the north is the head. Writing the data is by changing the
pointing directions of these magnets, usually fulfilled by an electric coiled
wrapped head (by applying the current into the head, you create a strong external
magnetic field that realign the directions of the small magnets in the hard
drive, one at a time). In addition, packing in as many magnets as possible in a
limited volume will define the capacity of a hard drive, and this is improving
ever since the first device available. Imaging the first computer I had came
with a hard drive of 400 MB, and now a decent one has a few TB storage
capacities. By comparing the number, you can realize how much effort and
advances in the business of data storage. For a very nice introduction, you can
find at hard
drive 101: magnetic storage.
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| Figure 1. A generic ferrimagnet, composed of Fe and Gd, shows the alignment of magnetic moment. Courtesy of I.Radu et al., Nature 472 205 (2011). |
A nice paper where ultrafast laser pulses (sub 100 fs) instead of
external magnetic field are used to write data intrigued my curiosity. I know immediately
that it is the heating effect that causes the change of the magnetization of
the small magnets in the hard drive. But for me, the heat has no
directionality, how it can tell the magnet to point forward or backward. It
should just erase the information since an ultrafast laser pulse can easily
create a hot environment above Curie temperature where the magnetization is
destroyed. So in my mind, an ultrafast laser is a hard drive terminator, not a
hard drive writer. Driven by this curiosity, I dug in to find out, and this is
how:
Strong magnets are either ferromagnetic of ferrimagnetic (that is
right, only one letter difference). Iron is ferromagnetic, since when it gains
magnetization, all the molecules have the magnetic moments (or the moment generator
– the atoms’ spins) aligned in one direction. On the other hand, ferrimagnetic
materials contain different atoms or same atoms in different chemical forms.
For example, the alloy of GdFeCo or magnetite is ferrimagnetic. When these materials gain magnetic power, the
magnetic moments of different atoms (or same atoms with different chemical
forms) are pointing in the opposite direction. However the magnitudes are
different. As a result, the cancellation is not complete, and some magnetic
power retains. This lengthy discussion has a purpose, since in order to use
ultrafast laser to write on the device, we need ferrimagnetic materials as our
small magnets. Figure 1 is an example of a ferrimagnetic material made of the
alloy of GdFeCo. The small arrows are the direction of the spins or magnetic
moments if you prefer.
The working principle is like this: When an ultrafast laser pulse hits the ferrimagnetic material (in this paper, a alloy where the active components are Gadolinium (Gd) and Iron (Fe)), the temperature shoots up and all spins are free to flip (or randomize) due to the energy shot. As a result, magnetic moments are decreasing toward zero. In other words, they start to demagnetize (I got this part right). Here is the catch: Fe demagnetize faster than Gd. Like figure 2 shows, when the overall magnet moment of Fe reaches 0 before 0.4 ps, Gd is still decreasing toward zero. At this instant, another principle plays a pivotal role – exchange interaction between Gd and Fe. This exchange interaction says that the flips of the spins of the Gd and Fe can undergo collaboratively, with the spin of a Gd atom flips from up to down, that of a Fe atom goes from down to up. Mother Nature likes the exchange interaction, since it is more energy efficient. Now incorporate this to our discussion. Right after the 0.4 ps, the overall magnetic moment of Gd is still decreasing; it means the spins are flipping down. This gives the spins of Fe atoms a direction, which favors to flip up against Gd’s to please Mother Nature. So the magnetic moment of Fe starts to build up, instead of staying randomized. After the overall magnetic moment of Gd hits zero, the overall magnetic moment of Fe has built up quite a bit. This built-up will guide the entire alloy to relax into an overall ferrimagnetic form. If you are still with me, you know the secret of this technology. With this principle at hands, you can use an ultrafast laser to write the data in an unprecedented speed -- for a few hundreds of picoseconds you can write a bit. And maybe scientists can push this limit even further.
The working principle is like this: When an ultrafast laser pulse hits the ferrimagnetic material (in this paper, a alloy where the active components are Gadolinium (Gd) and Iron (Fe)), the temperature shoots up and all spins are free to flip (or randomize) due to the energy shot. As a result, magnetic moments are decreasing toward zero. In other words, they start to demagnetize (I got this part right). Here is the catch: Fe demagnetize faster than Gd. Like figure 2 shows, when the overall magnet moment of Fe reaches 0 before 0.4 ps, Gd is still decreasing toward zero. At this instant, another principle plays a pivotal role – exchange interaction between Gd and Fe. This exchange interaction says that the flips of the spins of the Gd and Fe can undergo collaboratively, with the spin of a Gd atom flips from up to down, that of a Fe atom goes from down to up. Mother Nature likes the exchange interaction, since it is more energy efficient. Now incorporate this to our discussion. Right after the 0.4 ps, the overall magnetic moment of Gd is still decreasing; it means the spins are flipping down. This gives the spins of Fe atoms a direction, which favors to flip up against Gd’s to please Mother Nature. So the magnetic moment of Fe starts to build up, instead of staying randomized. After the overall magnetic moment of Gd hits zero, the overall magnetic moment of Fe has built up quite a bit. This built-up will guide the entire alloy to relax into an overall ferrimagnetic form. If you are still with me, you know the secret of this technology. With this principle at hands, you can use an ultrafast laser to write the data in an unprecedented speed -- for a few hundreds of picoseconds you can write a bit. And maybe scientists can push this limit even further.
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Researchers have demonstrated this phenomenon theoretically
and experimentally (this article).
As can be seen from figure 3, the magnetic moment flips back and forth after
the ultrafast pulses hit the sample.
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Amazingly, ultrafast lasers are finding their applications
at the frontiers in so many fields. They shine and rise in the fundamental
chemical physics, advanced spectroscopy, astronomy, machining (Jim has a
nice article about it), and now, computer science. Who knows what their next
stop will be?
DISCLAIMER
The opinions expressed herein are those of the author and do not represent the Optical Society of America (OSA) or any OSA affiliate.
