A Novel Biocontrol Strain FS6 for Excellent Control of Gray Mold and Seedling Diseases of Ginseng.

The biocontrol efficacy of FS6 against seedling diseases and gray mold of ginseng (), as well as application techniques, were evaluated in a series of field trials. FS6 fermentation broth showed a strong antagonistic effect against the ginseng fungal pathogens, and the inhibition rates on mycelial growth and spore germination were 84 to 88% and 71 to 72%, respectively. Field evaluation showed that combination of seed and soil treatments exhibited better protection than that of individual treatment alone.

Visible-light driven photodegradation on Ag nanoparticle-embedded fullerene (C) heterostructural microcubes.

Three-dimensional Ag(I)-fullerene hybrid microcrystal is fabricated by AgNO assisted liquid-liquid interfacial precipitation, containing the abundant sp-π-electron system. With a mild chemical reduction, it produces the massive Ag nanocluster/fullerene junctions, on which fullerene doubles role as the excellent electron acceptor and photon scavenger, enabling the Plasmon-driven catalytic reaction. Ag nanocluster employed alone could not perform this photocatalytic reaction, neither of fullerene (C) crystal.

Improving the transmission efficiency of the Cassegrain optical system for Bessel-Gaussian beams.

With the improvement of the transmission efficiency, the Cassegrain antenna can be widely used in space optical communication. In this paper, the Bessel-Gaussian (BG) beam is used to avoid the central energy loss of a Cassegrain antenna system. The intensity distribution and the phase distribution of the BG beam passing through a Cassegrain antenna are theoretically derived and simulated.

Ag(I)-Hived Fullerene Microcube as an Enhanced Catalytic Substrate for the Reduction of 4-Nitrophenol and the Photodegradation of Orange G Dye.

We report a facile approach to fabricate an Ag-embedded fullerene (C) catalyst by the chemical reduction of the AgNO complex encapsulated fullerene microcrystal, which showed an enhanced catalytic reduction of 4-nitrophenol because of the strong absorption and propagation of H along the fullerene surface. With the aid of visible-light radiation, photodegradation of orange G dye is achieved through the formation of an electron donor-acceptor dyad between plasmon Ag nanostructures and fullerene molecules, which effectively offsets the "electron-hole" recombination. Neither Ag nanoparticle nor fullerene crystal used in isolation could perform this chemical conversion, implying that the metal-fullerene hybrid structure is imperative for performing the catalytic reaction.

A real-time fluorescence turn-on assay for trypsin based on a conjugated polyelectrolyte.

We report a continuous and sensitive fluorescence turn-on assay for trypsin by using an anionic conjugated polyelectrolyte (PPE-CO2H) and a cationic peptide substrate labelled with p-nitroaniline (RG-pNA). Applications of the assay in trypsin activity study and high-throughput screening of protease inhibitors were demonstrated.

Continuous and sensitive acid phosphatase assay based on a conjugated polyelectrolyte.

We report a novel continuous and sensitive fluorescence turn-on assay for ACPs, which consists of a cationic conjugated polyelectrolyte (PPE4+) and a commonly used phosphatase substrate p-nitrophenyl phosphate (pNPP). The kinetics of the ACP catalyzed hydrolysis of the substrate pNPP was monitored by the fluorescence change of PPE4+ and corresponding kinetic parameters were derived to be consistent with the literature reports. The applications of PPE4+/pNPP-based ACP assay in high-throughput screening of ACP inhibitors and detection of prostatic acid phosphotase (PAP) in vitro were demonstrated.

A band dispersion mechanism for Pt alloy compositional tuning of linear bound CO stretching frequencies.

The C-O stretching frequency (nu(CO)) of atop CO/Pt in PtRu alloys is compositionally tuned in proportion to the Pt mole percent. The application of a Blyholder-Bagus type mechanism (i.e.

Laser-activated membrane introduction mass spectrometry for high-throughput evaluation of bulk heterogeneous catalysts.

Laser-activated membrane introduction mass spectrometry (LAMIMS), a high-throughput screening method, evaluates heterogeneous catalysts under realistic reactor conditions. It is a precise, versatile system requiring no moving parts. The catalyst array is supported on carbon paper overlaid upon a silicone rubber membrane configured in a variation of membrane introduction mass spectrometry as introduced by Cooks.