科研成果

2006
Prediction and possible observation of an oblate shape isomer in W-190. Physics Letters B. 2006;635:286.
Peng Y-B, Zou C, Wang D-H, Gong H-Q, Xu Z-H, Bai S-N. Preferential localization of abscisic acid in primordial and nursing cells of reproductive organs of Arabidopsis and cucumber. New Phytologist [Internet]. 2006;(3):459-466. 访问链接
Martinez-Canales M, Bergara A, Feng J, Grochala W. Pressure induced metallization of Germane. Journal of Physics and Chemistry of Solids. 2006;(9-10):2095-2099.
Martinez-Canales M, Bergara A, Feng J, Grochala W. Pressure induced metallization of Germane. Journal of Physics and Chemistry of Solids [Internet]. 2006;67:2095-2099. 访问链接
Guo L, Cheng Y, Wang Z, He B, Zhang J, Liu S, Liu M, Chen Z, Qu L, Gu H. Primary study on gene expression during root differentiation from rice calli. Beijing Daxue Xuebao (Ziran Kexue Ban)/Acta Scientiarum Naturalium Universitatis Pekinensis. 2006;(2):175-179.
Ren Z, Che L, Qiu M, Wang X, Dai D, Harich SA, Wang X, Yang X, Xu C, Xie D, et al. Probing Feshbach resonances in F + H2(j=1)→HF+H: Dynamical effect of single quantum H2-rotation. Journal of Chemical Physics. 2006;(15).
Wang C, Zhang C, Ouyang Q. Propagation of wave modes and antispiral waves in a reaction-diffusion system. Physical Review E - Statistical, Nonlinear, and Soft Matter Physics. 2006;(3).
Shi J, Zhang P, Xiao D, Niu Q. Proper definition of spin current in spin-orbit coupled systems. Physical Review Letters. 2006;(7).
Shi J, Zhang P, Xiao D, Niu Q. Proper definition of spin current in spin-orbit coupled systems. Physical Review Letters. 2006;(7).
Pei J, Wang Q, Liu Z, Li Q, Yang K, Lai L. PSI-DOCK: Towards highly efficient and accurate flexible ligand docking. Proteins: Structure, Function and Genetics [Internet]. 2006;(4):934-946. 访问链接
Jia Y, Wu B, Weitering HH, Zhang Z. Quantum size effects in Pb films from first principles: The role of the substrate. Physical Review B - Condensed Matter and Materials Physics. 2006;(3).
Chen B, Zhu Z, Xie XC. Quantum size effects in thermodynamic superconducting properties of ultrathin films. Physical Review B - Condensed Matter and Materials Physics. 2006;(13).
Quan HT, Zhang P, Sun CP. Quantum-classical transition of photon-Carnot engine induced by quantum decoherence. 2006;(3).
Lai L, Han X, Chen H, Wei P, Huang C, Liu S, Fan K, Zhou L, Liu Z, Pei J, et al. Quaternary structure, substrate selectivity and inhibitor design for SARS 3C-like proteinase. Current Pharmaceutical Design [Internet]. 2006;(35):4555-4564. 访问链接
Gao Y, Sun L, Dong J, Xu X, Shu Y, Chen M, Yin L, Liang Z, Jin Q. Rapid identification of small interfering RNA that can effectively inhibit the replication of multiple influenza B virus strains. Antiviral Therapy [Internet]. 2006;(4):431-438. 访问链接
Chen ZM, Wang CX. Rate constants of the gas-phase reactions of CH3OOH with O3 and NOx at 293 K. Chemical Physics Letters. 2006;424(4-6):233-238.
Wang CX, Chen ZM, Xu JR. Reaction mechanisms of the UV-photolysis of methyl hydroperoxide. Spectroscopy and Spectral Analysis. 2006;26(12):2222-2225.
Yang J, Wang EG. Reaction of water on silica surfaces. Current Opinion in Solid State and Materials Science. 2006;(1):33-39.
Liggio J, Li S-M. Reactive uptake of pinonaldehyde on acidic aerosols. JOURNAL OF GEOPHYSICAL RESEARCH-ATMOSPHERES. 2006;111.Abstract
[ 1] The reactive uptake of pinonaldehyde, a monoterpene oxidation product, on aerosols has been studied in a reaction chamber. Monodisperse inorganic seed aerosols, consisting of acidic mixtures of (NH4)(2)SO4 and H2SO4, were exposed to gaseous pinonaldehyde for several hours within the chamber under relative humidity conditions of 3-65%. The aerosol inorganic and organic mass were quantitatively monitored in real time with an aerosol mass spectrometer (AMS) which also measured the mass spectra of the aerosols. Numerous fragments in the mass spectra were observed with masses greater than what can be accounted for by pinonaldehyde alone and have arisen from oligomerization in reactive uptake processes. The evolution of the mass spectra also revealed a progression toward larger oligomers over time. Significant organic mass was added to the aerosols in most experiments immediately upon exposure, resulting in maximum organic mass loadings from 3.5-110 mu gm(-3) depending on the experiments. Organic mass to seed aerosol SO4= ratios were also highly variable (0.06-4.75), resulting in particles ranging in composition from primarily inorganic to mostly organic. This reactive uptake was highly dependent upon the aerosol water activity, and hence acidity and did not occur on neutral (NH4)(2)SO4 aerosols suggesting that acidity is necessary. Reactive uptake coefficients (g) of pinonaldehyde were calculated by fitting a model of organic mass growth to the data. The coefficients spanned two orders of magnitude (1.2 x 10(-5)-1.3 x 10(-3)) and were primarily dependent upon aerosol water activity and acidity but independent of gas phase pinonaldehyde concentrations. These coefficients indicated that the heterogeneous reactions of pinonaldehyde are of little importance as a gas phase loss mechanism but potentially of major importance as a source of secondary organic aerosols (SOA). Estimates of SOA production via pinonaldehyde, using the derived gamma, suggest that 1-750 ng m(-3) of organic material can be formed in a short time, consistent with ambient measurements.
Fang Y-X, Wang Y-B, Shi J, Liu Z-M, Lu L. Recent trends in drug abuse in China. Acta Pharmacologica Sinica [Internet]. 2006;(2):140-144. 访问链接

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