Drawing Data in Nanometer Scale
[A joint team of Korean researchers from POSTECH, Soongsil University, and Seoul National University proposes a method for storing data in nanometer scale by poking a sharp probe.]
[Researchers used metastable materials to increase the data storage capacity by 10 times compared to previous research findings.]
Frank Holzenburg, an artist with tens of thousands of followers across his social networking accounts, has attracted attention for his life-like drawings that are smaller than a fingernail. Recently, a method to draw data in an area smaller than 10 nanometers (nm; 1 nm = 1 billionth of a meter) – like drawing a small picture on paper – has been proposed.
A joint research team led by Professor Daesu Lee (Department of Physics) of POSTECH, Professor Se Young Park (Department of Physics) at Soongsil University, and Dr. Ji Hye Lee (Department of Physics and Astronomy) of Seoul National University has proposed a method for densely storing data by ‘poking’ with a sharp probe. This method utilizes a material in the metastable*1 state, whose properties change easily even with slight stimulation.
A thin film of metastable ferroelectric*2 calcium titanate (CaTiO3) enables the polarization*3 switching of a material even with a slight pressure of a probe: A very weak force of 100 nanonewtons (nN) is more than enough. The joint research team succeeded in making the width of the polarization path smaller than 10 nm by using this force and found the way to dramatically increase the capacity of data storage. This is because the smaller the size of the path, the more data the single material can store.
The data storage capacity increased by up to 1 terabit (Tbit)/cm as a result of drawing the data storage area using a probe on the thin film. This result is 10 times greater than that of a previous study (0.11Tbit/cm²) which suggested a probe-based storage method using another material. Unlike the data storage method that uses electric fields, this probe method only requires a very small force, so the burden on the device is also small.
The results from the study are drawing attention as they have proved that materials achieve higher performance in an unstable metastable state. The findings are anticipated to be applicable in the next-generation electronic devices with improved integration and efficiency in the future.
Recently published in Physical Review Letters, one of the most authoritative journals in the field of physics, this study was supported by the Institute for Basic Science, and by the Research Center Program, the Basic Science Research Institute Fund, and the Key Research Institutes in Universities program of the National Research Foundation of Korea.
A state in which a substance is stable without transitioning at a temperature at which it should change to another form..
A material that has its own polarization even without an external electric field and whose direction of polarization can be changed by an external electric field.
A phenomenon in which the positive and negative charges are charged at both ends of an object when a dielectric is placed in an electric field.