In today’s world of digital information, an enormous amount of data is exchanged and stored on a daily basis.
In the 1980s, IBM unveiled the first hard drive—which was the size of a refrigerator—that could store 1 GB of data, but now we have memory devices that have a thousand-fold greater data-storage capacity and can easily fit in the palm of our hand. If the current pace of increase in digital information is any indication, we require yet newer data recording systems that are lighter, have low environmental impact, and, most importantly, have higher data storage density.
Recently, a new class of materials called axially polar-ferroelectric columnar liquid crystals (AP-FCLCs) has emerged as a candidate for future high-density memory storage materials. An AP-FCLC is a liquid crystal with a structure of parallel columns generated by molecular self-assembly, which have polarization along the column axis.
The columns switch their polar directions upon the application of an external electric field. If AP-FCLCs can maintain their polarization even after the electric field is removed, this property, along with their flexibility, metal-free composition, power-saving ability, and low environmental impact, makes AP-FCLCs ideal for ultra-high-density memory devices. Unfortunately, due to the fluid nature of liquid crystals, the polarity induced by an external electric field can get easily undone by external stimuli.
A solution to this problem has now been proposed by a team of researchers from Chiba University, led by Professor Keiki Kishikawa of the Graduate School of Engineering and including Doctoral Course student Hikaru Takahashi of the Graduate School of Science and Engineering and Associate Professor Michinari Kohri of the Graduate School of Engineering.
In their recent breakthrough study, published in ACS Applied Nano Materials, the team presented a polarization fixation mechanism for a urea-based AP-FCLC system, where the materials can undergo a smooth transition from AP-FCLC phase to a crystal (Cr) phase without affecting the induced polar structure.
“The goal was to realize a compound with three states: a writable and rewritable state, an erasure state, and a save state. Emphasis was placed on minimizing the change in molecular packing structures during the FCLC−Cr phase transition process,” explains Prof. Kishikawa.
To create a polarization-fixable AP-FCLC system, the team synthesized 1,3-bis(3′,4′-di(2-butyloctyloxy)[1,1′-biphenyl]-4-yl)urea—an organic molecule consisting of urea at its molecular center for generating a hydrogen bonding network that can facilitate the formation of columnar aggregate in a liquid crystal (LC) state, two biphenyl groups as substituents for generating strong intermolecular interactions in the column structure, and four bulky alkyl groups as terminal chains to prevent tight molecular packing and enable lower-temperature FCLC−Cr phase transition.
The prepared FCLC system exhibited preservation of polarization in the Cr phase, with thermally stable polarization information storage and resistance to the external electrical field at room temperature. Furthermore, the researchers found that the molecules self-sorted into nanosized helical columns, which then formed small domains and became ferroelectric in nature.
This study provides a new strategy for the development of AP-FCLC systems that can maintain their polarization information for a long time. The proposed framework can be used to develop stable memory materials with high tolerance towards external stimuli and low environmental impact.
“AP-FCLCs have the potential to achieve more than 10,000 times larger recording density than Blu-ray Disks, but they have not been put into practical use due to the instability issue. This work will help improve their reliability, paving the way for light-weight flexible electronic devices and incinerable confidential information-recording devices,” concludes Prof. Kishikawa.
More information:
Hikaru Takahashi et al, Axially Polar-Ferroelectric Columnar Liquid Crystalline System That Maintains Polarization upon Switching to the Crystalline Phase: Implications for Maintaining Long-Term Polarization Information, ACS Applied Nano Materials (2023). DOI: 10.1021/acsanm.3c01508
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Chiba University