Jo Aug 15, 2024
Most rare earth minerals contain uranium, thorium and their decay products, so the technology for removing radioactivity plays a key role in the production of rare earths, especially in reduction of production cost, environmental protection and application of rare earth products. Furthermore, complete removal of trace radioactive substances existing in rare earth products is highly significant for wide application of rare earths and in medicine for health protection and cure.
Up to now, many methods for separating and removing radioactive substances have been reported: ion exchange method, solvent extraction method, co-precipitation method, etc. among which co-precipitation method is very effective for infinitesimal amount of radioactive materials such as radium and actinium. In an extremely dilute system, trace radioactive substances are usually separated by co-precipitation with carriers. Porous materials such as diatomaceous earth, activated carbon, fire brick, silica gel and alumina, barium sulfate, strontium sulfate , iron hydroxide(Ⅲ) and aluminum hydroxide are used as carriers.
In an attempt to remove trace radioactive substances existing in industrially produced rare earth carbonate, Kim Chol Ju, a researcher at the Faculty of Chemical Engineering, has conducted an experimental study of the radioactivity removal characteristics of [Ba-Fe] co-precipitation method, the combination of BaSO4 and Fe(OH)3 co-precipitation methods.
In the [Ba-Fe] co-precipitation process, the total removing rate is over 92% and loss rate of rare earths is less than 0.1% in the case of industrially produced rare earth carbonate.
As this method enables prompt and effective removal of radioactive elements such as uranium, thorium, radium, radiolead, etc., remaining in extremely small quantities in rare earth compounds, it could be applied in the field of hydrometallurgy in which rare earth compounds are produced from several kinds of rare earth minerals and in other fields of production and application of rare earth materials from rare earth compounds.
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Jo Aug 12, 2024
It is very important to correctly model and identify damping in all vibration systems of physical devices that involve damping.
A variety of methods and techniques of damping identification have been developed, most of which can be classified into frequency domain (circle-fitting method, half-power bandwidth method, wavelet transform method, etc.) and time domain (logarithmic decrement method, least squares complex exponential (LSCE) method, Smith least squares method, Hilbert transform method, etc.). Some of the damping identification methods in frequency domain have high accuracy, but the algorithm is very complicated, which restricts its wide application in practice.
Matrix method and modal method are also used for damping identification. In the modal method, modal identification is a must as the damping characteristics are decided by means of modal damping ratio. Modal identification is complicated and it is difficult to ensure the correctness of modal parameters. In the matrix method, which directly identifies the damping matrix by experimentally measured FRF, the imaginary part of experimentally measured FRF is decided for damping identification. This method is highly accurate and it is possible to decide the damping ratio of mechanical structures of lower DOF. However, it is very difficult for all numbers of DOF as mechanical structures are of high DOF in practice.
Kim Won Ju, a researcher at the Faculty of Mechanical Science and Technology, has proposed a method for correctly and simply deciding the damping characteristics of the whole system using the experimentally measured FRF and the FE model. Using the experimentally measured frequency response function matrix, he built an experimental model and combined it with the FE model to enlarge the experimental identity data to the whole system.
Comparing his method with preceding ones through simulations and error analysis, he verified its precision and effectiveness.
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Jo Aug 8, 2024
Unijunction transistor (UJT) is a semiconductor with two ohmic base contacts and an emitter p-n junction, so it is called double-base diode. Its static(S-shaped) I-V characteristic has a region with negative differential resistances. Therefore, UJTs are used in pulse generators, sawtooth generators and converters. UJT-based circuits are well known to be simpler and more reliable than those based on diodes and bipolar transistors.
Recently, transducers where the output signal frequency depends on physical quantities such as temperature, light, magnetic field, stress, concentration of gas and radiation level, have been designed with UJTs. Thus, improvement of the switching characteristic of UJT leads to that of the characteristics of these transducers.
To improve the switching characteristic of UJT, a number of researchers have investigated the radiation effect on it. To the best of our knowledge, there are no reports in the literature regarding how the neutron irradiation of UJT affects its peak point voltage.
Pae Kyong Il, a researcher at the Semiconductor Institute, has proposed a new analytical expression for the peak point voltage of UJT considering the effect of neutron irradiation, and proved its validity by comparing the calculated values and those measured from the neutron irradiation on an Si planar UJT.
His study has shown that the calculated values of the peak point voltage of UJT are in good agreement with the measured ones, that the peak point voltage of UJT decreases after neutron irradiation, and that the peak point voltage of UJT decreases gradually with the growing intensity of neutron fluence.
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Jo Aug 4, 2024
The silicon steel plate is widely used as core materials of various devices such as a transformer and an electromotor. However, in order to solve the energy problem, it is very important to develop soft magnetic materials with less iron loss.
Fe-based amorphous and nano-crystalline alloys are widely used because of its low cost and iron loss about one fifth to one third of silicon steel plates. But, they are restricted to some degree in application because the value of maximum flux density of these materials is about 80% of silicon steel plates. Therefore, researches to develop soft magnetic materials with higher maximum flux density and lower core loss have been performed. As a result, new Fe-based nano-crystal soft magnetic materials have been developed. Among them, Fe-Cu-B system nano-crystalline soft magnetic materials are attracting a great deal of attention.
In most studies, the experimental results of the influence of copper, silicon and boron on the magnetic properties were analyzed, but the thermodynamic changing process was not described in detail.
Jo Chol Min, a researcher at the Faculty of Materials Science and Technology, has conducted a study to thermodynamically solve the influence of Cu addition on the crystallization of the Fe-based nano-crystalline soft magnetic alloy fabricated by the melt spinning method. In addition, he has analyzed the influence of silicon and boron on the magnetic properties of Fe-based nano-crystalline soft magnetic alloys to determine the reasonable composite.
He found that the crystallization activation energy of Fe-based alloys containing copper was lower than copper-free alloys, which indicates that copper is effective to accelerate the crystallization of alloys and increase the magnetic property. He also demonstrated that in crystallization heat treatment, the maximum flux density and coercive force of the Fe-based nano-crystalline soft magnetic alloy containing copper were the best with 2% of Si.
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Jo Jul 30, 2024
People want to live in a cleaner environment and more developed living conditions. Various harmful substances such as toxic materials, gas, dust and dirt come into being from the daily life of people. These substances pollute air, water, soil, etc. and destroy ecological environment, thus doing direct or indirect harm to people.
As an acidic igneous rock containing quartz, feldspars and mica as essential minerals, granite is widely used for decoration of the outer walls of buildings. However, during the processing of granite, granite waste in which 30% is dust is generated. This waste is used as construction filler for building materials, but most of it is left in the open air or landfilled. Consequently, soil, underground water and source of stream are polluted and the concentration of dust in the air is increased. Especially, the particle size of fine granite dust (FGD) is so small that exerts severe harmful influence on the environment.
Recycling of this FGD into eco-friendly material can be very profitable to the economy as well as environment protection.
Ri Chol Ju, a researcher at the Faculty of Earth Science and Technology, has proposed a method of synthesizing zeolite from waste granite powder with low energy (fusing at the temperature of 800℃) and at low cost (using an effective solvent-sodium carbonate).
The results showed that 13X zeolite can be successfully synthesized through pretreatment at the relatively low temperature from what is manufactured by separating chemically stable quartz from FGD.
This method could be applied to all the waste produced from the processing of other rocks containing crystalline quartz.
If you need some more information, please refer to his paper “Hydrothermal synthesis of 13X zeolite by using feldspars separated from waste granite powder” in “International journal of environmental science and technology” (SCI).
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Jo Jul 28, 2024
Development and use of natural energy plays an important role in guaranteeing the sustainable development of economy and satisfying the energy demands. In this field, study on the solar energy is particularly important. Recently, the efficiency of perovskite solar cells (PSCs) which have become the focus of solar energy development almost reached the efficiency of silicon solar cells and therefore a lot of efforts are being made to ensure the stability of solar cells.
The stability of PSCs primarily depends on the stability of perovskite which performs the function of light absorber in devices. For this reason, many researchers are trying to improve the heat and humidity stability of perovskite.
Recently, it has been found that ion liquid, which has been studied in several fields including medicine due to its special properties such as high viscosity, low vapor pressure and incombustibility, can be used as an additive or a solvent for perovskite precursor to improve the performance and stability of PSCs.
Ion liquid, well known as an eco-friendly harmless solvent, has polarity that can solve perovskite precursor, so it can replace the toxic DMF or DMSO that have been conventionally used for fabrication of PSCs.
Kang Jin Hyok, a researcher at the Faculty of Information Science and Technology, investigated the influence of ion liquid methylammonium acetate (MAAc) on the characteristics of perovskite and the performance of hole transport material (HTM)-free PSCs with carbon electrode when it is used as a solvent of precursor for preparing perovskite.
The perovskite was prepared by solid–gas reaction between dimethylammonium lead iodide (DMAPbI3) and methylamine (MA). DMAPbI3 was solved by ion liquid MAAc instead of DMF and it was used as a precursor.
The perovskite film based on ion liquid was more uniform and denser than the one based on DMF, thus improving the crystallinity and crystal size of perovskite. The analysis result showed that the nonradiative recombination of cells decreased and the open circuit voltage could be improved when using MAAc instead of DMF.
For further details, you can refer to his paper “The characteristics of hole-transport material-free perovskite solar cells with carbon electrode made by using ion liquid methylammonium acetate solvent” in “Results in Optics” (SCI).
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