| RESEARCH HIGHLIGHTS |
MMLV contains the enzyme reverse
transcriptase that allows its RNA to be converted to DNA in the host. Song’s research shows that this enzyme binds to a protein (peptidyl release factor 1) in its host that would otherwise be responsible for reading the stop-codons. This thwarts its ability to bind and prevents it from working.
The research also provides insight into the
workings of the world’s most notorious retro- virus, human immunodeficiency virus (HIV). It was previously believed that a reverse
transcriptase interaction would be common across all retroviruses. However, Song and his team found that the HIV reverse transcriptase did not bond to peptidyl release factor 1.
“This means that any anti-gammaretro-
virus interventions would not work on HIV,” Song says.
1. Tang, X., Zhu, Y., Baker, S. L., Bowler, M. W., Chen, B. J. et al. Structural basis of suppression of host translation termination by Moloney Murine Leukemia Virus. Nature Communications 7, 12070 (2016).
Data storage
LASER HEATING HITS THE SPOT
LASER-BASED MEASUREMENTS REVEAL JUST HOW SMALL EACH MAGNETIC ‘BIT’ COULD BE USING NEXT-GENERATION HARD DISK TECHNOLOGY KNOWN AS HEAT-ASSISTED MAGNETIC RECORDING
A method for accurately measuring the thermomagnetic properties of heat-assisted magnetic recording (HAMR) media reveals what the minimum bit size and ultimate data density might be for the next-generation storage technology1. Existing hard disk technology is
approaching fundamental physical limits on the amount of data that can be stored on magnetic disks. One of the most promising technologies capable of breaching these limits is HAMR, which heats small areas to allow for smaller magnetic bits and higher data densities. The minimum possible bit size has been the subject of considerable debate. Yang Hongzhi and Yunjie Chen from the A*STAR Data Storage Institute (DSI) have now developed a method using two lasers to put this debate to rest. “The basic idea of HAMR is to use a tiny laser spot to heat the magnetic material on the
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Heat-assisted magnetic recording could be the basis of the next generation of hard disk drive (pictured) technologies.
disk to its critical ‘Curie’ temperature, which makes it more easily writable,” explains Chen. Writability sets the upper limit on data
density as it determines how small an area can be magnetically ‘switched’ using the weak magnetic field of conventional data writing heads. By heating the magnetic disk to a certain tempera- ture, a material with an intrinsically finer-grained magnetic fabric can be used, resulting in smaller bits. One of the unknowns surrounding the technology is how far each bit would need to be separated in order to maintain reliable switching without affecting neighboring bits. “The switching field distribution at the
heating temperature is directly related to how narrow a magnetic transition can be recorded, which will decide the data density that could be achieved,” says Chen. “Using a lab-built multifunctional HAMR writing and measure- ment system here at the DSI, we developed a method that allows us to accurately measure the
thermomagnetic properties of HAMR media at the Curie temperature.” The team’s approach uses two laser beams,
one to spot-heat the media to exactly the right temperature, and the other to measure the magnetic signal based on an unusual interaction between magnetism and light known as the magneto-optic Kerr effect. Using this approach, the researchers were
able to run a range of tests on experimental HAMR media, providing unprecedented insight into its thermomagnetic response. “We expect this test method to be helpful for characteriza- tion and development of HAMR media as the major candidate for the next generation of hard disk drive technologies.”
1. Yang, H. Z., Chen, Y. J., Leong, S. H., An, C. W., Ye, K. D. & Hu, J. F. Measurement of magnetic property of FePt granular media at near Curie temperature. Journal of Magnetism and Magnetic Materials 423, 27–33 (2017).
A*STAR RESEARCH 27
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