Zinc selenide (ZnSe) nanoparticles were synthesized in aqueous solution using glutathione (GSH) as a ligand. The influence of the ligand content, reaction temperature, and hydroxyl ion concentration (pH) on the fabrication of the ZnSe particles was investigated. The optical properties of the synthesized ZnSe particles were characterized using various analytical techniques. The nanoparticles absorbed UV-vis light in the range of 350-400 nm, which is shorter than the absorption wavelength of bulk ZnSe particles (460 nm). The lowest ligand concentration for achieving good light absorption and emission properties was 0.6 mmol. The reaction temperature had an impact on the emission properties; photoluminescence spectroscopic analysis showed that the photo-discharge characteristics were greatly enhanced at high temperatures. These discharge characteristics were also affected by the hydroxyl ion concentration in solution; at pH 13, sound emission characteristics were observed, even at a low temperature of 25oC. The manufactured nanoparticles showed excellent light absorption and emission properties, suggesting the possibility of fabricating ZnSe QDs in aqueous solutions at low temperatures.
Molybdenum trioxide (MoO3) is used in various applications including sensors, photocatalysts, and batteries owing to its excellent ionic conductivity and thermal properties. It can also be used as a precursor in the hydrogen reduction process to obtain molybdenum metals. Control of the parameters governing the MoO3 synthesis process is extremely important because the size and shape of MoO3 in the reduction process affect the shape, size, and crystallization of Mo metal. In this study, we fabricated MoO3 nanoparticles using a solution combustion synthesis (SCS) method that utilizes an organic additive, thereby controlling their morphology. The nucleation behavior and particle morphology were confirmed using ultraviolet-visible spectroscopy (UV-vis) and field emission scanning electron microscopy (FE-SEM). The concentration of the precursor (ammonium heptamolybdate tetrahydrate) was adjusted to be 0.1, 0.2, and 0.4 M. Depending on this concentration, different nucleation rates were obtained, thereby resulting in different particle morphologies.
알칼라인 수전해 공정에 사용되는 복합 분리막은 고분자와 나노 세라믹 입자로 구성되며 기계적 안정성과 높은 이온 전도성을 가지는 것이 필수적이다. 나노 세라믹 입자는 알칼라인 용액 내 수산화이온(OH-)의 전도성을 높인다고 보고되어 왔으나 세라믹 입자의 비율에 따른 OH-의 관계와 효과의 이해가 미흡한 실정이다. 본 연구에서는 여러 물성 측정(버블포인트, 이온 저항 등)을 통하여 분리막 성능에 입자의 비율이 미치는 영향과 원인을 연구하였다. 입자의 비율이 증가하면 이온 저항은 감소하며, 높은 버블포인트를 유지한다. 이는 분리막 내의 OH-증가로 이온 저항이 낮아지며, 입자의 밀집한 배열이 버블포인트를 유지하는 것으로 판단된다. 따라서 비율의 증가에 따라 OH-상호 작용으로 높은 전도성과 안정성을 가져온다.
Well-dispersed Ag3VO4 nanoparticles @polyacrylonitrile (PAN) nanofibers were synthesized by an easily controlled, template-free method as a photo-catalyst for the degradation of methylene blue. Their structural, optical, and photocatalytic properties have been studied by X-ray diffraction, transmission electron microscopy, field-emission scanning electron microscopy equipped with rapid energy dispersive analysis of X-ray, photoluminescence, and ultraviolet–visible spectroscopy. The characterization procedures revealed that the obtained material is PAN nanofibers decorated by Ag3VO4 nanoparticles. Photocatalytic degradation of methylene blue investigated in an aqueous solution under irradiation showed 99% degradation of the dye within 75 min. Finally, the antibacterial performance of Ag3VO4 nanoparticles @PAN composite nanofibers was experimentally verified by the destruction of Escherichia coli. These results suggest that the developed inexpensive and functional nanomaterials can serve as a non-precious catalyst for environmental applications.
이온교환막은 전기투석, 연료전지 외에도 수처리 공정에 있어 관심도가 매우 높다. 본 연구에서는 이온교환막에 사용되는 이온교환수지를 대신할 물질로써 입자를 제조하였다. 나노단위의 입자가 표면적을 증가시켜 기존의 이온교환수지보다 더 높은 이온교환능이 기대된다. 단분산된 나노크기의 입자를 제조하여 양이온은 -NH3+,-NR3+,-PR3+,-SR2+등의 관능기를 그리고 음이온은 –SO3-,-COO-,-PO3-,-C6H4O- 등의 관능기를 도입함으로써 각각 양전하와 음전하로 높게 하전시킬 수 있다. 입자를 제조하고 이에 따른 제타전위를 측정하고 IEC, FT-SEM, TGA 및 FT-IR을 측정하여 특성을 파악하였다.
Copper is an essential micronutrient whose deficiency is often seen to occur in humans. Although many biomedical studies have focused on the use of nanoparticles, the nutritional effects of nano-sized copper oxide particles are not well known. This aim of this study was to investigate the nutritional bioavailability of nano- and micro-sized copper oxide (CuO) particles in copper-deficient (CuD) mice. Copper deficiency was induced in mice by feeding a CuD diet (0.93 mg Cu/kg diet) for 7 weeks. After the induction of copper deficiency, nano- or micro-sized copper oxide particles were administered orally at two different doses (0.8 and 4.0 mg CuO/kg body weight) to mice in the following groups: (1) normal control (NC), (2) CuD, (3) low dose micro-sized CuO, (4) high dose micro-sized CuO, (5) low dose nano-sized CuO, and (6) high dose nano-sized CuO. The hepatic copper concentration in the CuD group was significantly lower than that in the NC group. Compared to the NC group, the CuD group exhibited lower serum ceruloplasmin (CP) activity and CP level. The copper/zinc-superoxide dismutase activity in the CuD group was significantly lower than that in the NC group. Treatment with nano- or micro-sized copper oxide particles for 2 weeks restored the hepatic copper levels and serum CP activities to values similar to those observed in the NC group. The CP levels and copper/zinc-superoxide dismutase activities in all the copper oxide treatment groups also recovered to normal values after 3 weeks of copper oxide treatment. These results show that oral administration of either nano- or micro-sized copper oxide particles for 2–3 weeks restored the normal condition in previously CuD mice.
A precipitation behavior of nano-oxide particle in Fe-5Y2O3 alloy powders is studied. The mechanically alloyed Fe-5Y2O3 powders are pressed at 750oC for 1h, 850oC for 1h and 1150oC for 1h, respectively. The results of Xray diffraction pattern analysis indicate that the Y2O3 diffraction peak disappear after mechanically alloying process, but Y2O3 and YFe2O4 complex oxide precipitates peak are observed in the powders pressed at 1150oC. The differential scanning calorimetry study results reveal that the formation of precipitates occur at around 1054oC. Based on the transmission electron microscopy analysis result, the oxide particles with a composition of Y-Fe-O are found in the Fe-5Y2O3 alloy powders pressed at 1150oC. It is thus conclude that the mechanically alloyed Fe-5Y2O3 powders have no precipitates and the oxide particles in the powders are formed by a high temperature heat-treatment
In this article, to predict the wear amount of nano particles in a worn nano composite, computational analysis pre/post-processor were developed using ABAQUS and visual basic programs. The abrasion, which is one of nano particles release scenarios, was applied in the computational analysis. Moreover, reciprocation, which is the abrasion type, was selected and incarnated in abrasion computational analysis. Also, to predict wear amount of nano composite in computational analysis, archard equation was applied and the predicted wear amount was evaluated compare with experimental value. The predicted wear amount of nano composite was increased in accordance with increasing force and was similar to result of experimental value.
전도성 고분자 PFO(Polyfluorene)에 양전극 ITO와 음전극으로 AI 를 추가한 단순한 양극성 구조의 ITO/PFO/Al 소자를 제작하였다. PFO에 BaTIO₃나노세라믹스 분말을 중량비로 0wt%, 10wt%, 20wt% 와 30wt% 로 달리한 4종류의 시편에 만들고, Keithley 사의 2400 Sourcemeter를 이용하여 0V에서 21V까지 DC전압을 인가하면서 소자에 흐르는 전류량을 관찰하였다. 수 나노 크기의 BaTIO₃분말의 첨가는 PFO/AI 계면에서의 전위장벽을 감소시켜 Fowler-Nordheim Tunneling이 시작되는 전압이 BaTIO₃가 첨가되지 않은 시편의 경우에 비하여 7V에서 최대 10V가 낮아진 결과를 얻었다. 소자에 흐르는 최대 전류값은 인가 전압 DC21V일 때 BaTIO₃첨가량에 비례하여 4배에서 5.5배까지 증가하였다. BaTIO₃의 첨가효과는 20wt% 이상 첨가된 경우 효과가 포화되기 시작하여, 30wt%의 BaTIO₃를 첨가한 시편의 전류량은 오히려 감소하였고 전류주입도 어려워지는 상반된 결과를 얻었다. 이것은 첨가한 나노 분말의 표면전하가 만드는 미세전계의 영향이 인접한 거리에서 서로 중첩되어 전류의 흐름이 오히려 감소하는 결과를 보인 것을 판단된다. 이로서 강유전체가 첨가된 전도성 고분자/금속 계면의 I-V 특성은 나노 세라믹스 분말의 표면전하가 만드는 국소미세전계의 영향을 받아 Trap Charge Limited Current 모델에 부합하는 결과를 가짐을 알 수 있었다.
Hollow silica spheres were prepared by spray drying of precursor solution of colloidal silica. The precursor solution is composed of 10-20 nm colloidal silica dispersed in a water or ethanol-water mixture solvent with additives of tris hydroxymethyl aminomethane. The effect of pH and concentrations of the precursor and additives on the formation of hollow sphere particles was studied. The spray drying process parameters of the precursor feeding rate, inlet temperature, and gas flow rate are controlled to produce the hollow spherical silica. The mixed solvent of ethanol and water was preferred because it improved the hollowness of the spheres better than plain water did. It was possible to obtain hollow silica from high concentration of 14.3 wt% silica precursor with pH 3. The thermal conductivity and total solar reflectivity of the hollow silica sample was measured and compared with those values of other commercial insulating fillers of glass beads and TiO2 for applications of insulating paint, in which the glass beads are representative of the low thermal conductive fillers and the TiO2 is representative of infrared reflective fillers. The thermal conductivity of hollow silica was comparable to that of the glass beads and the total solar reflectivity was higher than that of TiO2.
식품산업에서의 나노기술은 많은 연구와 가능성 있는 제품으로 새롭게 각광받는 분야이다. 나노와 마이크로 크기의 고체 입자는 유화된 오일 또는 물 입자를 함유하는 분산계의 처방에 적용 가능성이 매우 높은 것으로 인식되고 있다. 본 논문은 식용의 지방 결정, 실리카 나노 입자 및 생체 유래의 나노 결정체에 기반을 둔 식품 에멀젼의 성질과 개발에 관한 리뷰논문으로 다양한 피커링 안정화 분야에 관하여 검토하였다. 특히, 단백질로 안정화된 일반적인 에멀젼과 비교하여 Pickering 안정화 입자에 대해 초점을 맞추고자한다. 또한, 식품 산업에서 이들의 응용 예를 다루고자한다.
Zinc oxide nanoparticles (nZnO) are used in a various range, including ceramic manufacture, photocatalysis, UV filters, and the food industry. However, little is known about the effects of micro- and nano-particles during mouse embryo organogenesis. To determine whether ZnO affects size-dependent anomalies during embryonic organogenesis, mouse embryos were cultured for two days with 300 ug/ml micro ZnO (mZnO;80±25 μm) and nZnO (< 100 nm) and the developmental changes were then investigated. Quantity of Zn by inductively coupled plasma mass spectrometry analysis, and expression patterns of various antioxidant enzymes in the embryos were investigated. Embryos exposed to mZnO or nZnO exhibited severe retardation of growth and development. In embryos exposed to mZnO and nZnO, yolk sac diameter, crown-rump length, and head length were significantly diminished. The morphological parameters, including yolk sac circulation, allantois, flexion, heart, hindbrain, midbrain, forebrain, otic system, optic system, branchial bars, maxillary process, mandibular process, olfactory system, caudal neural tube, forelimb, hindlimb, and somites in mZnO and nZnO-treated groups were significantly decreased. Zn absorption of the nZnO-treated group was significantly higher than that of the mZnO-treated group. Significantly decreased levels of CuZn-SOD, Mn-SOD, cGPx, and PHGPx mRNA were observed in the ZnO-treated group. In addition, antioxidant enzyme mRNA expressions of the nZnO group were significantly diminished, less than those of the mZnO treated group. These findings indicate that 300 ug/ml ZnO showed abnormality and nZnO may have a more severe effect than mZnO in developing embryos.
Multi shell graphite coated Ag nano particles with core/shell structure were successfully synthesized by pulsed wire evaporation (PWE) method. Ar and (10 vol.%) gases were mixed in chamber, which played a role of carrier gas and reaction gas, respectively. Graphite layers on the surface of silver nano particles were coated indiscretely. However, the graphite layers are detached, when the particles are heated up to in the air atmosphere. In contrast, the graphite coated layer was stable under Ar and atmosphere, though the core/shell structured particles were heated up to . The presence of graphite coated layer prevent agglomeration of nanoparticles during heat treatment. The dispersion stability of the carbon coated Ag nanoparticles was higher than those of pure Ag nanoparticles.
This study examined the biostability and drug delivery efficiency of g-Fe2O3 magnetic nanoparticles (GMNs) by cytotoxicity tests using various tumor cell lines and normal cell lines. The GMNs, approximately 20 nm in diameter, were prepared using a chemical coprecipitation technique, and coated with two surfactants to obtain a water-based product. The particle size of the GMNs loaded on hangamdan drugs (HGMNs) measured 20-50 nm in diameter. The characteristics of the particles were examined by X-ray diffraction (XRD), field emission scanning electron microscopy (FE-TEM) and Raman spectrometer. The Raman spectrum of the GMNs showed three broad bands at 274, 612 and 771 cm1. A 3-(4, 5-dimethylthiazol-2-yl)-2, 5-diphenyltetrazolium bromide (MTT) assay showed that the GMNs were non-toxic against human brain cancer cells (SH-SY5Y, T98), human cervical cancer cells (Hela, Siha), human liver cancer cells (HepG2), breast cancer cells (MCF-7), colon cancer cells (CaCO2), human neural stem cells (F3), adult mencenchymal stem cells (B10), human kidney stem cells (HEK293 cell), human prostate cancer (Du 145, PC3) and normal human fibroblasts (HS 68) tested. However, HGMNs were cytotoxic at 69.99% against the DU145 prostate cancer cell, and at 34.37% in the Hela cell. These results indicate that the GMNs were biostable and the HGMNs served as effective drug delivery vehicles.
목적: 본 연구는 안경수건에 함유된 은나노 입자의 항균효과를 연구하기 위해 수행되었다. 방법: 은나노 입자가 함유된 안경수건과 함유되지 않은 안경수건의 세균수를 비교하였다. 결과: 은나노입자가 함유된 안경수건에서 뚜렷한 세균수의 감소가 관찰되었으며, 이 결과는 안경렌즈에 존재하는 세균에 대해 은나노 입자가 높은 항균성을 가짐을 의미한다. 결론: 가까운 미래에 나노기술을 이용한 항균작용 안경수건의 개발이 기대된다.
Titanium carbides are widely used for cutting tools and grinding wheels, because of their superior physical properties such as high melting temperature, high hardness, high wear resistance, good thermal conductivity and excellent thermal shock resistance. The common synthesizing method for the titanium carbide powders is carbo-thermal reduction from the mixtures of titanium oxide() and carbon black. The purpose of the present research is to fabricate nano TiC powders using titanium salt and titanium hydride by the mechanochemical process(MCP). The initial elements used in this experiment are liquid (99.9%), (99.9%) and active carbon(<, 99.9%). Mg powders were added to the solution in order to induce the reaction with Cl-. The weight ratios of the carbon and Mg powders were theoretically calculated. The TiC and powders were milled in the planetary milling jar for 10 hours. The 40 nm TiC powders were fabricated by wet milling for 4 hours from the +C+Mg solution, and 300 nm TiC particles were obtained by using titanium hydride.
Principles and historical background of high pressure liquid jet (HPLJ) technology is presented in the paper. This technology can be applied, among others, for production of nano particles. This target can be achieved in various type of disintegration systems developed and designed on the base of this technology. The paper describes principles of two examples of such systems: HPLJ-reactor, called also a linear comminuting system, HPLJ- centrifugal comminuting system, which prototypes have been manufactured. A linear mill, being high energy liquid jet reactor, has been developed and tested for micronization of various types of materials. The results achieved so far, and presented in the paper, show its potential for further improvement toward nano-size particle production. Flexibility of adjustment of the reactors and the mechanism of the process allows for the creation of particles with unprecedented rheology. The reactor can be especially suitable to micronize, mix and densify materials with a wide range of mechanical properties for various industrial needs. Presented prototypes of comminution systems generate interesting potentials toward production of nano particles. Their performance, based on up today research, confirms expected high efficiency of materials disintegration, which opens a new challenge for industrial applications. The paper points out benefits and area of possible applications of presented technology.
Silver particles were synthesized from silver nitrate by homogeneous precipitation and chemical reduction methods involving the intermediate silver cyanate. The obtained silver particles were characterized by XRD, SEM, TEM, and BET. Urea which could prevent the agglomeration of the reduced silver particles was used as a homogeneous precipitator. The spherical silver particles with average particle diameter of 100 nm were obtained under the optimum reaction conditions. The optimum synthetic conditions were found as follows: reaction temperature , reaction time 60 min, concentration of silver nitrate mol, urea mol, and sodium citrate mol. The phase of obtained silver particles was crystalline state and the silver particles were relatively dense, which had the surface area of .
Bioaerosols become a more noticed and important problem in indoor air quality (IAQ) control. In this study, we investigated antibacterial effects of silver nano-particles on Escherichia coli, the common Gram negative bacteria and Staphylococcus aureus, the well-mown Gram positive bacteria under aerosol conditions. The bioaerosols containing each bacterial culture were contacted with silver nano-particles sprayed in a closed chamber. Experimental results showed that the silver nano-particles had strong antibacterial activity against E. coli and S. aureus, respectively. As anticipated, high antibacterial activity was found at a high silver concentration and a long the contact time. It was also found that the bactericidal rate decreased with time due to the aggregation of silver nano-particles. Overall, the experimental finding suggested that silver nano-particles could be successfully applied to improve indoor air quality.
Al-Cu alloy nano powders have been produced by the electrical explosion of Cu-plated Al wire. The porous nano particles were prepared by leaching for Al-Cu alloy nano powders in 40wt% NaOH aqueous solution. The surface area of leached powder for 5 hours was 4 times larger than that of original alloy nano powder. It is demonstrated that porous nano particles could be obtained by selective leaching of alloy nano powder. It is expected that porous Cu nano powders can be applied for catalyst of SRM (steam reforming methanol).