Stimuli-responsive materials alter their own properties in response to external stimuli, such as photo-irradiation, heat, pressure and electricity. This feature can be controlled for a wide range of uses, such as in optical discs, computer memories and displays, as well as artificial muscles and drug delivery systems.
Researchers have been working to develop new stimuli-responsive materials in a predictable fashion. However, it has been extremely difficult to design and control the complex molecular arrangements of the materials.
Now, a simple and reliable method to synthesize stimuli-responsive materials has been developed by a team led by Nagoya University’s JST-ERATO Itami Molecular Nanocarbon Project and the Institute of Transformative Bio-Molecules (ITbM). The results of this study were recently reported in the journal Angewandte Chemie International Edition.
The ‘responsive porous host’ method takes a molecule with a porous framework and binds to it a ‘guest’ molecule that is likely to react to external stimuli. In this case, the team found that cycloparaphenylene (CPP), a hydrocarbon molecule composed of 10 para-connected benzene rings, made an ideal host when combined with iodine (I). Iodine situated itself inside the porous carbon rings, and reacted to electric stimulation. Not only did it conduct electricity, it also emitted a white light, which is unusual. Typically, many other components are required to obtain the white color. This shows the potential of the new material, CPP-I, for next generation illumination systems.
“This ‘responsive porous host’ approach is expected to be applicable to different stimuli, such as photo-irradiation, heat application and pH change, and open the path for devising a generic strategy for the development of stimuli-responsive materials in a controllable and predictable fashion,” said Dr. Hirotoshi Sakamoto, a group leader of the JST-ERATO project.
Synthesizing the material is surprisingly simple — the researchers mixed carbon nanorings (CPP) and iodine together, and let it dry. X-ray crystallography confirmed that the iodine molecules line up inside the hollow core of the aligned nanorings.
The team tried several variations of the mixture, changing the number of carbon nanorings, and found that 10 rings led to the most dynamic iodine atom movement and the most sensitive response to external environmental changes.
When a direct current was applied to CPP-I, the bulk resistivity of the sample became approximately 380 times lower, indicating that it conducted electricity rather than resisting electrical transmission. The bulk resistivity in mixtures with 9 or 12 nanorings did not decrease nearly as much. These results show that pore size in the nanoring assembly controls the response to electrical stimulation.
“One of the most difficult parts of this research was to investigate how the electric conductivity of CPP-I is turned on by electric stimuli,” said Dr. Noriaki Ozaki, a postdoctoral researcher of the JST-ERATO project. “Although it only took us about three months to synthesize the molecule and discover its electric-stimuli-responsive properties, it took another year to discover the origin of its properties.”
The team finally figured out how the electric conductivity of CPP-I is turned on by electric stimuli, using X-ray absorption near-edge spectroscopy (XANES), Raman spectroscopy, and fluorescence spectroscopy. These analyses showed that the iodine atoms in the carbon nanorings form extended polyiodide chains when stimulated by electricity, which gave the material electrical conductivity.
The researchers also discovered that electric stimuli can switch the photoluminescence color of CPP-I from a green-blue color to a white color. White luminescence means that the fluorescence spectrum of CPP-I covers the whole visible light range. Spectral broadening is attributed to the irregular distribution of the electronic structures of CPPs, which is caused by the formation of polyiodide chains. The white luminescence of CPP-I is a rare example of white illumination material from a single molecular assembly; white light emission is usually achieved by mixing several components of different colors.
“We were really excited to develop this simple yet powerful method to achieve the synthesis of external-stimuli-response materials,” said Professor Kenichiro Itami, director of the JST-ERATO project and center director of ITbM.