Chiral
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KAIST research team develops a forgery prevention technique using salmon DNA
The authenticity scandal that plagued the artwork “Beautiful Woman” by Kyung-ja Chun for 30 years shows how concerns about replicas can become a burden to artists, as most of them are not experts in the field of anti-counterfeiting. To solve this problem, artist-friendly physical unclonable functions (PUFs) based on optical techniques instead of electronic ones, which can be applied immediately onto artwork through brushstrokes are needed.
On May 23, a KAIST research team led by Professor Dong Ki Yoon in the Department of Chemistry revealed the development of a proprietary technology for security and certification using random patterns that occur during the self-assembly of soft materials.
With the development of the Internet of Things in recent years, various electronic devices and services can now be connected to the internet and carry out new innovative functions. However, counterfeiting technologies that infringe on individuals’ privacy have also entered the marketplace.
The technique developed by the research team involves random and spontaneous patterns that naturally occur during the self-assembly of two different types of soft materials, which can be used in the same way as human fingerprints for non-replicable security. This is very significant in that even non-experts in the field of security can construct anti-counterfeiting systems through simple actions like drawing a picture.
The team developed two unique methods. The first method uses liquid crystals. When liquid crystals become trapped in patterned substrates, they induce the symmetrical destruction of the structure and create a maze-like topology (Figure 1). The research team defined the pathways open to the right as 0 (blue), and those open to the left as 1 (red), and confirmed that the structure could be converted into a digital code composed of 0’s and 1’s that can serve as a type of fingerprint through object recognition using machine learning. This groundbreaking technique can be utilized by non-experts, as it does not require complex semiconductor patterns that are required by existing technology, and can be observed through the level of resolution of a smartphone camera. In particular, this technique can reconstruct information more easily than conventional methods that use semiconductor chips.
< Figure 1. Security technology using the maze made up of magnetically-assembled structures formed on a substrate patterned with liquid crystal materials. >
The second method uses DNA extracted from salmon. The DNA can be dissolved in water and applied with a brush to induce bulking instability, which forms random patterns similar to a zebra’s stripes. Here, the patterns create ridge endings and bifurcation, which are characteristics in fingerprints, and these can also be digitalized into 0’s and 1’s through machine learning. The research team applied conventional fingerprint recognition technology to this patterning technique and demonstrated its use as an artificial fingerprint. This method can be easily carried out using a brush, and the solution can be mixed into various colors and used as a new security ink.
< Figure 2. Technology to produce security ink using DNA polymers extracted from salmon >
This new security technology developed by the research team uses only simple organic materials and requires basic manufacturing processes, making it possible to enhance security at a low cost. In addition, users can produce patterns in the shapes and sizes they want, and even if the patterns are made in the same way, their randomness makes each individual pattern different. This provides high levels of security and gives the technique enhanced marketability.
Professor Dong Ki Yoon said, “These studies have taken the randomness that naturally occurs during self-assembly to create non-replicable patterns that can act like human fingerprints.” He added, “These ideas will be the cornerstone of technology that applies the many randomities that exist in nature to security systems.”
The two studies were published in the journal Advanced Materials under the titles “1Planar Spin Glass with Topologically-Protected Mazes in the Liquid Crystal Targeting for Reconfigurable Micro Security Media” and “2Paintable Physical Unclonable Function Using DNA” on May 6 and 5, respectively.
Author Information: 1Geonhyeong Park, Yun-Seok Choi, S. Joon Kwon*, and Dong Ki Yoon*/ 2Soon Mo Park†, Geonhyeong Park†, Dong Ki Yoon*: †co-first authors, *corresponding author
This research was funded by the Center for Multiscale Chiral Architectures and supported by the Ministry of Science and ICT-Korea Research Foundation, BRIDGE Convergent Research and Development Program, the Running Together Project, and the Samsung Future Technology Development Program.
< Figure 1-1. A scene from the schematic animation of the process of Blues (0) and Reds (1) forming the PUF by exploring the maze. From "Planar Spin Glass with Topologically-Protected Mazes in the Liquid Crystal Targeting for Reconfigurable Micro Security Media" by Geonhyeong Park, Yun-Seok Choi, S. Joon Kwon, Dong Ki Yoon. https://doi.org/10.1002/adma.202303077 >
< Figure 2-1. A schematic diagram of the formation of digital fingerprints formed using the DNA ink. From "Paintable Physical Unclonable Function Using DNA" by Soon Mo Park, Geonhyeong Park, Dong Ki Yoon. https://doi.org/10.1002/adma.202302135 >
2023.06.08 View 7746 -
Success in Real-Time Observation of the Formation Process of Topological Solitons, a Core Technology for Next-Generation Information Transfer
< From left) Geonhyeong Park (Ph.D. Candidate), Yun-Seok Choi (Ph.D.), Professor Dong Ki Yoon, and Changjae Lee (Ph.D. Candidate) of the Department of Chemistry >
Professor Dong Ki Yoon's research team in the Department of Chemistry at KAIST announced on the 11th that they have succeeded in controlling the formation of topological solitons in a regular, large-area manner through the self-assembly of chiral liquid crystal materials and observing their formation process in real-time.
A soliton refers to a phenomenon where a specific wave persists without dissipating through interaction with its surroundings. In particular, even when a wave is transmitted over long distances, it retains its unique information until it reaches the desired destination. Therefore, in today's digital society, which is susceptible to hacking, solitons are highly anticipated to be the core of future communication due to their inherent high stability. Furthermore, topological solitons created using organic liquid crystal molecules are expected to be utilized as next-generation anti-counterfeiting devices and memory elements due to their unique spin directionality.
Professor Yoon's team specifically revealed the formation process of topological solitons in this study, which had not been observable in real-time under mild conditions such as room temperature until now. This was made possible by using self-assembling chiral liquid crystal materials in a confined space created by air pillars.
This research, in which Geonhyeong Park (Ph.D. Candidate, Department of Chemistry) and Dr. Ahram Suh participated as co-first authors, and Dr. Yun-Seok Choi and Changjae Lee (Ph.D. Candidate) from the same group also participated, was published online in the international journal 'Advanced Materials' on June 5th and is scheduled to be featured as the back cover of the July issue. (Paper title: "Fabrication of Arrays of Topological Solitons in Patterned Chiral Liquid Crystals for Real-Time Observation of Morphogenesis")
< Figure 1. Schematic diagram of the research>
< Figure 2. Real-time observation of topological soliton formation using liquid crystals>
In this study, Professor Yoon's team implemented topological soliton structures at approximately 30 degrees Celsius, similar to room temperature, using chiral (asymmetric) liquid crystal materials instead of the conventional liquid crystal molecules widely used as core materials in liquid crystal displays (LCDs). Generally, complex equipment is required to control the formation of topological solitons, and their formation time is very short, which has hindered research into their formation process until now.
To achieve regular formation and control of topological solitons formed by chiral liquid crystal molecules, Professor Yoon's team precisely controlled a combination of vertical alignment layers, which can orient molecules vertically, and air pillars. Specifically, they prepared concave patterns based on circular silicon material, several micrometers (one-millionth of a meter) in size, coated with a vertical alignment layer, and a glass substrate. By adjusting the gap to several micrometers and injecting chiral liquid crystal material, air pillars were spontaneously formed on the concave patterns. Subsequently, the liquid crystal molecules were vertically aligned on all substrates, inevitably causing regular distortions between the substrates, and between the substrate and the air pillars, thus developing a system where chiral molecular structures, i.e., topological solitons, could be formed.
The key to the formation and control of topological solitons lies in controlling the thermal phase transition to occur regularly as desired when cooling from the isotropic phase temperature (approximately 40 degrees Celsius) to the liquid crystal phase temperature (approximately 30 degrees Celsius), where the liquid crystal material near the air pillars is cooler than the liquid crystal material between the glass substrate and the silicon patterned parts. This is consistent with the everyday wisdom of eating steamed eggs from a 'Ttukbaegi' (earthen pot) by starting from the relatively cooler part exposed to the air (near the air pillars) rather than the hot pot part (silicon or glass substrate part).
Through real-time analysis, the research team elucidated that topological defects are formed by the naturally formed air pillars through controlled thermal phase transition, and topological solitons are formed only at the locations of these defects. This analysis technique has the potential for application in various fields, including the interpretation of topological soliton formation found in other physical phenomena such as skyrmion particles in electromagnetism.
< Figure 3. Snapshots during the formation process of regularly arranged topological solitons>
Professor Dong Ki Yoon stated, "General topological solitons are known to be highly stable, capable only of generation or annihilation. Through the results of this research, we can understand the formation process of solitons in more detail, and they can be used as spintronics application technology, considered a next-generation semiconductor device for storing and recording information."
This research was conducted in collaboration with Professor Ivan Smalyukh's laboratory at the University of Colorado, Department of Physics, and was supported by the Multiscale Chiral Structures Research Center and strategic projects of the National Research Foundation of Korea under the Ministry of Science and ICT.
2022.07.11 View 47 -
New Chiral Nanostructures to Extend the Material Platform
Researchers observed a wide window of chiroptical activity from nanomaterials
A research team transferred chirality from the molecular scale to a microscale to extend material platforms and applications. The optical activity from this novel chiral material encompasses to short-wave infrared region.
This platform could serve as a powerful strategy for hierarchical chirality transfer through self-assembly, generating broad optical activity and providing immense applications including bio, telecommunication, and imaging technique. This is the first observation of such a wide window of chiroptical activity from nanomaterials.
“We synthesized chiral copper sulfides using cysteine, as the stabilizer, and transferring the chirality from molecular to the microscale through self-assembly,” explained Professor Jihyeon Yeom from the Department of Materials Science and Engineering, who led the research. The result was reported in ACS Nano on September 14.
Chiral nanomaterials provide a rich platform for versatile applications. Tuning the wavelength of polarization rotation maxima in the broad range is a promising candidate for infrared neural stimulation, imaging, and nanothermometry. However, the majority of previously developed chiral nanomaterials revealed the optical activity in a relatively shorter wavelength range, not in short-wave infrared.
To achieve chiroptical activity in the short-wave infrared region, materials should be in sub-micrometer dimensions, which are compatible with the wavelength of short-wave infrared region light for strong light-matter interaction. They also should have the optical property of short-wave infrared region absorption while forming a structure with chirality.
Professor Yeom’s team induced self-assembly of the chiral nanoparticles by controlling the attraction and repulsion forces between the building block nanoparticles. During this process, molecular chirality of cysteine was transferred to the nanoscale chirality of nanoparticles, and then transferred to the micrometer scale chirality of nanoflowers with 1.5-2 2 μm dimensions formed by the self-assembly.
“We will work to expand the wavelength range of chiroptical activity to the short-wave infrared region, thus reshaping our daily lives in the form of a bio-barcode that can store vast amount of information under the skin,” said Professor Yeom.
This study was funded by the Ministry of Science and ICT, the Ministry of Health and Welfare, the Ministry of Food and Drug Safety, the National Research Foundation of Korea,the KAIST URP Program, the KAIST Creative Challenging Research Program, Samsung and POSCO Science Fellowship.
-PublicationKi Hyun Park, Junyoung Kwon, Uichang Jeong, Ji-Young Kim, Nicholas A.Kotov, Jihyeon Yeom, “Broad Chrioptical Activity from Ultraviolet to Short-Wave Infrared by Chirality Transfer from Molecular to Micrometer Scale," September 14, 2021 ACS Nano (https://doi.org/10.1021/acsnano.1c05888)
-ProfileProfessor Jihyeon YeomNovel Nanomaterials for New Platforms LaboratoryDepartment of Materials Science and EngineeringKAIST
2021.10.22 View 10817 -
Gallium-Based Solvating Agent Efficiently Analyzes Optically Active Alcohols
A KAIST research team has developed a gallium-based metal complex enabling the rapid chiral analysis of alcohols. A team working under Professor Hyunwoo Kim reported the efficient new alcohol analysis method using nuclear magnetic resonance (NMR) spectroscopy in iScience.
Enantiopure chiral alcohols are ubiquitous in nature and widely utilized as pharmaceuticals. This importance of chirality in synthetic and medicinal chemistry has advanced the search for rapid and facile methods to determine the enantiomeric purities of compounds. To date, chiral analysis has been performed using high-performance liquid chromatography (HPLC) with chiral columns.
Along with the HPLC technique, chiral analysis using NMR spectroscopy has gained tremendous attention as an alternative to traditionally employed chromatographic methods due to its simplicity and rapid detection for real-time measurement. However, this method carries drawbacks such as line-broadening, narrow substrate scope, and poor resolution. Thus, compared with popular methods of chromatographic analysis, NMR spectroscopy is infrequently used for chiral analysis.
In principle, a chiral solvating agent is additionally required for the NMR measurement of chiral alcohols to obtain two distinct signals. However, NMR analysis of chiral alcohols has been challenging due to weak binding interactions with chiral solvating agents. To overcome the intrinsic difficulty of relatively weak molecular interactions that are common for alcohols, many researchers have used multifunctional alcohols to enhance interactions with solvating agents.
Instead, the KAIST team successfully varied the physical properties of metal complexes to induce stronger interactions with alcohols rather than the strategy of using multifunctional analytes, in the hopes of developing a universal chiral solvating agent for alcohols. Compared to the current method of chiral analysis used in the pharmaceutical industry, alcohols that do not possess chromophores can also be directly analyzed with the gallium complexes.
Professor Kim said that this method could be a complementary chiral analysis technique at the industry level in the near future. He added that since the developed gallium complex can determine enantiomeric excess within minutes, it can be further utilized to monitor asymmetric synthesis. This feature will benefit a large number of researchers in the organic chemistry community, as well as the pharmaceutical industry.
(Figure: Schematic view of the in-situ direct 1H NMR chiral analysis.)
-Profile:
Professor Hyunwoo Kim
Department of Chemistry
KAIST
http://mdos.kaist.ac.kr
hwk34@kaist.ac.kr
For more on this article,
please go to https://doi.org/10.1016/j.isci2019.07051
2019.11.14 View 11846