AUTOMATED ULTRAFILTRATION DEVICE FOR EFFICIENT COLLECTION OF ZEOLITE A AND SOIL NANOPARTICLES FROM AQUEOUS SUSPENSION-A REVIEW
スポンサーリンク
概要
- 論文の詳細を見る
Environmental nanoparticles exist in the hydrosphere, pedosphere, biosphere and atmosphere. However, efficiently collecting nanoparticles in large quantities of time consuming from both pure and natural systems is a major challenge in nanoscience. This review paper aimed to use zeolite A and highly weathered red soils as examples, employed an automated ultrafiltration device (AUD) to fractionate nanoparticles (i.e., 1-100nm) from aqueous suspensions, and characterized the properties of nanoparticles. We have successfully overcome the problems and collected large quantities of nanoparticles with AUD system. Freeze-dried zeolite A and soil nanoparticles were characterized by conventional and synchrotron X-ray diffraction (XRD) with petrographic glass slides of oriented samples and random powder samples, as well as by synchrotron powder XRD analysis. The chemical properties of a zeolite are dependent on its framework structure, which is formed by connecting truncated octahedra (sodalite) through the simple double four rings (D4-R) with external linkage in each sodalite. With decreasing particle size, the T(Si, Al)-O asymmetric and symmetric stretching vibrations shifted toward higher frequencies and the Si to Al molar ratio increased consistently from 1.8 to 5.2. Comparing the various particle-size fractions (PSFs) showed significant differences in surface area, Si to Al molar ratio, morphology, crystallinity, framework structure, and surface atomic structure of nanoparticles from those of the bulk sample (i.e., <2000nm) prior to particle-size fractionations. Our results reveal the degree of crystallinity of the soil particles, and they can be used to identify the presence or absence of minerals at various PSFs (450-2000, 100-450, and 1-100nm). Kaolinite, illite, goethite and hematite were identified in the 1-100nm size fraction by synchrotron high-resolution XRD and by transmission electron microscopy (TEM). The XRD patterns of the various PSFs, shows that synchrotron XRD is better at identifying soil nanoparticles (1-100nm) than conventional XRD using powder samples due to its use of higher photon energies. Synchrotron XRD analysis is also a more straightforward and powerful technique for identifying mineral nanoparticles, particularly those of phyllosilicate minerals.
著者
-
Wang Ming
Department Of Agricultural Chemistry National Taiwan University
-
Tsao Tsung
Experimental Forest National Taiwan University:department Of Agricultural Chemistry National Taiwan
関連論文
- Net nitrogen mineralization and nitrification rates in forest soil in northeastern Taiwan(Environment)
- 台湾の犬における初めての東洋眼虫感染症例(寄生虫病学)
- Isolated Recurrence of Granulocytic Sarcoma : Two Case Reports
- Anoxia survival in common carp and crucian carp is related to high zinc concentration in tissues
- TED-AJ03-596 Effects of Temperature and Corrosion Thickness and Composition on Magnetic Measurements of Structural Steel Wires
- AUTOMATED ULTRAFILTRATION DEVICE FOR EFFICIENT COLLECTION OF ZEOLITE A AND SOIL NANOPARTICLES FROM AQUEOUS SUSPENSION-A REVIEW
- New β-class milbemycin compound from Streptomyces avermitilis NEAU1069 : fermentation, isolation and structure elucidation
- Myxopapillary Ependymoma in the Third Ventricle Area and Sacral Canal: Dropped or Retrograde Metastasis?:—Case Report—