The Experts below are selected from a list of 306 Experts worldwide ranked by ideXlab platform
Hideyuki Kihara - One of the best experts on this subject based on the ideXlab platform.
-
Static Electricity‐Responsive Supramolecular Assembly
Chemistry: A European Journal, 2017Co-Authors: Hirokuni Jintoku, Yoko Matsuzawa, Hirotaka Ihara, Hideyuki KiharaAbstract:Stimuli-responsive materials can convert between molecular scale and macroscopic scale phenomena. Two macroscopic Static Electricity-responsive phenomena based on nanoscale supramolecular assemblies of a zinc porphyrin derivative are presented. One example involves the movement of supramolecular assemblies in response to Static Electricity. The assembly of a pyridine (Py) complex of the above-mentioned derivative in cyclohexane is drawn to a positively charged material, whereas the assembly of a 3,5-dimethylpyridine complex is drawn to a negatively charged material. The second phenomenon involves the movement of a non-polar solvent in response to Static electrical stimulation. A cyclohexane solution containing a small quantity of the Py-complexed assembly exhibited a strong movement response towards negatively charged materials. Based on spectroscopic measurements and electron microscope observations, it was revealed that the assembled formation generates the observed response to Static Electricity.
-
Static Electricity-Responsive Supramolecular Assembly.
Chemistry: A European Journal, 2017Co-Authors: Hirokuni Jintoku, Yoko Matsuzawa, Hirotaka Ihara, Hideyuki KiharaAbstract:: Stimuli-responsive materials can convert between molecular scale and macroscopic scale phenomena. Two macroscopic Static Electricity-responsive phenomena based on nanoscale supramolecular assemblies of a zinc porphyrin derivative are presented. One example involves the movement of supramolecular assemblies in response to Static Electricity. The assembly of a pyridine (Py) complex of the above-mentioned derivative in cyclohexane is drawn to a positively charged material, whereas the assembly of a 3,5-dimethylpyridine complex is drawn to a negatively charged material. The second phenomenon involves the movement of a non-polar solvent in response to Static electrical stimulation. A cyclohexane solution containing a small quantity of the Py-complexed assembly exhibited a strong movement response towards negatively charged materials. Based on spectroscopic measurements and electron microscope observations, it was revealed that the assembled formation generates the observed response to Static Electricity.
Hirokuni Jintoku - One of the best experts on this subject based on the ideXlab platform.
-
Static Electricity‐Responsive Supramolecular Assembly
Chemistry: A European Journal, 2017Co-Authors: Hirokuni Jintoku, Yoko Matsuzawa, Hirotaka Ihara, Hideyuki KiharaAbstract:Stimuli-responsive materials can convert between molecular scale and macroscopic scale phenomena. Two macroscopic Static Electricity-responsive phenomena based on nanoscale supramolecular assemblies of a zinc porphyrin derivative are presented. One example involves the movement of supramolecular assemblies in response to Static Electricity. The assembly of a pyridine (Py) complex of the above-mentioned derivative in cyclohexane is drawn to a positively charged material, whereas the assembly of a 3,5-dimethylpyridine complex is drawn to a negatively charged material. The second phenomenon involves the movement of a non-polar solvent in response to Static electrical stimulation. A cyclohexane solution containing a small quantity of the Py-complexed assembly exhibited a strong movement response towards negatively charged materials. Based on spectroscopic measurements and electron microscope observations, it was revealed that the assembled formation generates the observed response to Static Electricity.
-
Static Electricity-Responsive Supramolecular Assembly.
Chemistry: A European Journal, 2017Co-Authors: Hirokuni Jintoku, Yoko Matsuzawa, Hirotaka Ihara, Hideyuki KiharaAbstract:: Stimuli-responsive materials can convert between molecular scale and macroscopic scale phenomena. Two macroscopic Static Electricity-responsive phenomena based on nanoscale supramolecular assemblies of a zinc porphyrin derivative are presented. One example involves the movement of supramolecular assemblies in response to Static Electricity. The assembly of a pyridine (Py) complex of the above-mentioned derivative in cyclohexane is drawn to a positively charged material, whereas the assembly of a 3,5-dimethylpyridine complex is drawn to a negatively charged material. The second phenomenon involves the movement of a non-polar solvent in response to Static electrical stimulation. A cyclohexane solution containing a small quantity of the Py-complexed assembly exhibited a strong movement response towards negatively charged materials. Based on spectroscopic measurements and electron microscope observations, it was revealed that the assembled formation generates the observed response to Static Electricity.
Hirotaka Ihara - One of the best experts on this subject based on the ideXlab platform.
-
Static Electricity‐Responsive Supramolecular Assembly
Chemistry: A European Journal, 2017Co-Authors: Hirokuni Jintoku, Yoko Matsuzawa, Hirotaka Ihara, Hideyuki KiharaAbstract:Stimuli-responsive materials can convert between molecular scale and macroscopic scale phenomena. Two macroscopic Static Electricity-responsive phenomena based on nanoscale supramolecular assemblies of a zinc porphyrin derivative are presented. One example involves the movement of supramolecular assemblies in response to Static Electricity. The assembly of a pyridine (Py) complex of the above-mentioned derivative in cyclohexane is drawn to a positively charged material, whereas the assembly of a 3,5-dimethylpyridine complex is drawn to a negatively charged material. The second phenomenon involves the movement of a non-polar solvent in response to Static electrical stimulation. A cyclohexane solution containing a small quantity of the Py-complexed assembly exhibited a strong movement response towards negatively charged materials. Based on spectroscopic measurements and electron microscope observations, it was revealed that the assembled formation generates the observed response to Static Electricity.
-
Static Electricity-Responsive Supramolecular Assembly.
Chemistry: A European Journal, 2017Co-Authors: Hirokuni Jintoku, Yoko Matsuzawa, Hirotaka Ihara, Hideyuki KiharaAbstract:: Stimuli-responsive materials can convert between molecular scale and macroscopic scale phenomena. Two macroscopic Static Electricity-responsive phenomena based on nanoscale supramolecular assemblies of a zinc porphyrin derivative are presented. One example involves the movement of supramolecular assemblies in response to Static Electricity. The assembly of a pyridine (Py) complex of the above-mentioned derivative in cyclohexane is drawn to a positively charged material, whereas the assembly of a 3,5-dimethylpyridine complex is drawn to a negatively charged material. The second phenomenon involves the movement of a non-polar solvent in response to Static electrical stimulation. A cyclohexane solution containing a small quantity of the Py-complexed assembly exhibited a strong movement response towards negatively charged materials. Based on spectroscopic measurements and electron microscope observations, it was revealed that the assembled formation generates the observed response to Static Electricity.
Yoko Matsuzawa - One of the best experts on this subject based on the ideXlab platform.
-
Static Electricity‐Responsive Supramolecular Assembly
Chemistry: A European Journal, 2017Co-Authors: Hirokuni Jintoku, Yoko Matsuzawa, Hirotaka Ihara, Hideyuki KiharaAbstract:Stimuli-responsive materials can convert between molecular scale and macroscopic scale phenomena. Two macroscopic Static Electricity-responsive phenomena based on nanoscale supramolecular assemblies of a zinc porphyrin derivative are presented. One example involves the movement of supramolecular assemblies in response to Static Electricity. The assembly of a pyridine (Py) complex of the above-mentioned derivative in cyclohexane is drawn to a positively charged material, whereas the assembly of a 3,5-dimethylpyridine complex is drawn to a negatively charged material. The second phenomenon involves the movement of a non-polar solvent in response to Static electrical stimulation. A cyclohexane solution containing a small quantity of the Py-complexed assembly exhibited a strong movement response towards negatively charged materials. Based on spectroscopic measurements and electron microscope observations, it was revealed that the assembled formation generates the observed response to Static Electricity.
-
Static Electricity-Responsive Supramolecular Assembly.
Chemistry: A European Journal, 2017Co-Authors: Hirokuni Jintoku, Yoko Matsuzawa, Hirotaka Ihara, Hideyuki KiharaAbstract:: Stimuli-responsive materials can convert between molecular scale and macroscopic scale phenomena. Two macroscopic Static Electricity-responsive phenomena based on nanoscale supramolecular assemblies of a zinc porphyrin derivative are presented. One example involves the movement of supramolecular assemblies in response to Static Electricity. The assembly of a pyridine (Py) complex of the above-mentioned derivative in cyclohexane is drawn to a positively charged material, whereas the assembly of a 3,5-dimethylpyridine complex is drawn to a negatively charged material. The second phenomenon involves the movement of a non-polar solvent in response to Static electrical stimulation. A cyclohexane solution containing a small quantity of the Py-complexed assembly exhibited a strong movement response towards negatively charged materials. Based on spectroscopic measurements and electron microscope observations, it was revealed that the assembled formation generates the observed response to Static Electricity.
Alla Merkulova - One of the best experts on this subject based on the ideXlab platform.
-
Development of Automation Algorithm for Step of Designing Technology of Static Electricity Protection Clothing
2018 International Russian Automation Conference (RusAutoCon), 2018Co-Authors: Irina Cherunova, Salikh Tashpulatov, Alla MerkulovaAbstract:The article presents the research results, which aim at providing an automation algorithm for the step of the designing technology of Static Electricity protection clothing. Designing the protective clothing is intended to the creation of such a structure, the properties of which ensure human protection against hazards, save health, resist own wear, form the necessary area and volume of the shell, distribute loads for human movement and comfort. Such hazard is Static Electricity. To solve these problems, it is reasonable to create a special CAD-module and then introduce it into the general cycle of clothing automated designing. Its purpose is to develop a package of materials, integrate them in the solution of tasks on human thermal protection by clothing and predict its antielectroStatic properties. As a result, a mathematical model of clothing surface electrification was developed taking into account operation conditions and material properties. [16]. Based on this model an algorithm of design flow was developed for the special warm Static Electricity protection clothing. Based on the created algorithm a special software environment is developed, which may be integrated in a number of modern CAD-systems for clothing. The research was made in Don State Technical University within the framework of State Assignment of the Ministry of education and science of Russia under the project 11.9194.2017.
