科研成果

2013
Li X-Z, Walker B, Probert MIJ, Pickard CJ, Needs RJ, Michaelides A. Classical and quantum ordering of protons in cold solid hydrogen under megabar pressures. [Internet]. 2013;(8). 访问链接
Li X-Z, Walker B, Probert MIJ, Pickard CJ, Needs RJ, Michaelides A. Classical and quantum ordering of protons in cold solid hydrogen under megabar pressures. [Internet]. 2013;(8). 访问链接
Wang R, Cong L-J, Yu C. The classical TDT perceptual learning is mostly temporal learning. Journal of Vision [Internet]. 2013;(5). 访问链接
Li Y, Wang X, Zheng H, Wang C, Minvielle S, Magrangeas F, Avet-Loiseau H, Shah PK, Zhang Y, Munshi NC, et al. Classify Hyperdiploidy Status of Multiple Myeloma Patients Using Gene Expression Profiles. [Internet]. 2013;(3). 访问链接
Parkin B, Ouillette P, Li Y, Keller J, Lam C, Roulston D, Li C, Shedden K, Malek SN. Clonal evolution and devolution after chemotherapy in adult acute myelogenous leukemia. [Internet]. 2013;(2):369-377. 访问链接
Ouillette P, Saiya-Cork K, Seymour E, Li C, Shedden K, Malek SN. Clonal evolution, genomic drivers, and effects of therapy in chronic lymphocytic leukemia. [Internet]. 2013;(11):2893-2904. 访问链接
Qu F, Zhang C, Du R-R, Lu L. Coexistence of bulk and surface Shubnikov-de haas oscillations in Bi 2Se3. Journal of Low Temperature Physics. 2013;170(5-6):397-402.
Qu F, Zhang C, Du R-R, Lu L. Coexistence of bulk and surface Shubnikov-de haas oscillations in Bi 2Se3. Journal of Low Temperature Physics. 2013;(5-6):397-402.
Dong GX, Wang XB, Liu HL, Xu FR. Collectivity of neutron-rich magnesium isotopes investigated by projected shell model calculations. Phys. Rev. C [Internet]. 2013;88:024328. 访问链接
Huang H, Li Y, Liu Z, Wu J, Duan W. Comment on “Structural and electronic properties of t graphene: a two-dimensional carbon allotrope with tetrarings”. Phys. Rev. Lett. 2013;110:029603.
Huang H, Li Y, Liu Z, Wu J, Duan W. Comment on "structural and electronic properties of T graphene: A two-dimensional carbon allotrope with tetrarings". Physical Review Letters. 2013;(2).
Yue DL, Hu M, Wang ZB, Wen MT, Guo S, Zhong LJ, Wiedensohler A, Zhang YH. Comparison of particle number size distributions and new particle formation between the urban and rural sites in the PRD region, China. Atmospheric EnvironmentAtmospheric Environment. 2013;76:181-188.Abstract
Particle number size distributions were simultaneously measured at the Guangzhou (GZ) urban site (23.13 degrees N, 113.26 degrees E) and the Back-garden (BG) rural site (23.5 degrees N, 113.03 degrees E) in the Pearl River Delta (PRD) region in July, 2006. It provided new findings into the evolution of particle number size distribution and new particle formation (NPF) in two different environments. Number concentration of particles (20 nm-10 mu m diameter) at GZ was about 70% higher than at BG and significantly affected by traffic emission. However, number concentrations of the regional aerosols (100-660 nm) were (6 +/- 3) x 10(3) cm(-3) at both sites. At BG, the diurnal variation of particle number size distributions showed an obvious particle growth process beginning at about 9:00 (LT), probably caused by NPF. In contrast, particle number concentrations in the size rages of 20-45 nm, 45-100 nm, and 100-660 nm showed similar trends with two main peaks at about 12:00 (LT) and 19:00 (LT) at GZ. NPF events were observed at both sites, but the occurrence frequency at GZ was about 50% lower than at BG. Regional NPF events at both sites probably in the same air mass were simultaneously observed with similar growth rates, concentrations and production rates of the condensable vapors, and condensational sinks on July 6. On the whole, deceasing traffic emission will improve air quality efficiently in the aspect of particle number concentration and fine particulate pollution in the summer of PRD should be controlled in a regional scale, especially with stagnant air mass from South China Sea. Crown Copyright (C) 2012 Published by Elsevier Ltd. All rights reserved.
Yue DL, Hu M, Wang ZB, Wen MT, Guo S, Zhong LJ, Wiedensohler A, Zhang YH. Comparison of particle number size distributions and new particle formation between the urban and rural sites in the PRD region, China. Atmospheric EnvironmentAtmospheric Environment. 2013;76:181-188.Abstract
Particle number size distributions were simultaneously measured at the Guangzhou (GZ) urban site (23.13 degrees N, 113.26 degrees E) and the Back-garden (BG) rural site (23.5 degrees N, 113.03 degrees E) in the Pearl River Delta (PRD) region in July, 2006. It provided new findings into the evolution of particle number size distribution and new particle formation (NPF) in two different environments. Number concentration of particles (20 nm-10 mu m diameter) at GZ was about 70% higher than at BG and significantly affected by traffic emission. However, number concentrations of the regional aerosols (100-660 nm) were (6 +/- 3) x 10(3) cm(-3) at both sites. At BG, the diurnal variation of particle number size distributions showed an obvious particle growth process beginning at about 9:00 (LT), probably caused by NPF. In contrast, particle number concentrations in the size rages of 20-45 nm, 45-100 nm, and 100-660 nm showed similar trends with two main peaks at about 12:00 (LT) and 19:00 (LT) at GZ. NPF events were observed at both sites, but the occurrence frequency at GZ was about 50% lower than at BG. Regional NPF events at both sites probably in the same air mass were simultaneously observed with similar growth rates, concentrations and production rates of the condensable vapors, and condensational sinks on July 6. On the whole, deceasing traffic emission will improve air quality efficiently in the aspect of particle number concentration and fine particulate pollution in the summer of PRD should be controlled in a regional scale, especially with stagnant air mass from South China Sea. Crown Copyright (C) 2012 Published by Elsevier Ltd. All rights reserved.
Yue DL, Hu M, Wang ZB, Wen MT, Guo S, Zhong LJ, Wiedensohler A, Zhang YH. Comparison of particle number size distributions and new particle formation between the urban and rural sites in the PRD region, China. Atmospheric EnvironmentAtmospheric Environment. 2013;76:181-188.Abstract
Particle number size distributions were simultaneously measured at the Guangzhou (GZ) urban site (23.13 degrees N, 113.26 degrees E) and the Back-garden (BG) rural site (23.5 degrees N, 113.03 degrees E) in the Pearl River Delta (PRD) region in July, 2006. It provided new findings into the evolution of particle number size distribution and new particle formation (NPF) in two different environments. Number concentration of particles (20 nm-10 mu m diameter) at GZ was about 70% higher than at BG and significantly affected by traffic emission. However, number concentrations of the regional aerosols (100-660 nm) were (6 +/- 3) x 10(3) cm(-3) at both sites. At BG, the diurnal variation of particle number size distributions showed an obvious particle growth process beginning at about 9:00 (LT), probably caused by NPF. In contrast, particle number concentrations in the size rages of 20-45 nm, 45-100 nm, and 100-660 nm showed similar trends with two main peaks at about 12:00 (LT) and 19:00 (LT) at GZ. NPF events were observed at both sites, but the occurrence frequency at GZ was about 50% lower than at BG. Regional NPF events at both sites probably in the same air mass were simultaneously observed with similar growth rates, concentrations and production rates of the condensable vapors, and condensational sinks on July 6. On the whole, deceasing traffic emission will improve air quality efficiently in the aspect of particle number concentration and fine particulate pollution in the summer of PRD should be controlled in a regional scale, especially with stagnant air mass from South China Sea. Crown Copyright (C) 2012 Published by Elsevier Ltd. All rights reserved.
Liu W, Sun W, Borthwick AGL, Ni J. Comparison on aggregation and sedimentation of titanium dioxide, titanate nanotubes and titanate nanotubes-TiO 2: Influence of pH, ionic strength and natural organic matter. Colloids and Surfaces A: Physicochemical and Engineering Aspects. 2013;434:319-328.
Taylor MJ, Cullen DM, Procter MG, Bäck T, Cederwall B, Doncel M, Braunroth T, Dewald A, Pakarinen J, Grahn T, et al. Competing single-particle and collective states in the low-energy structure of $^113$I. Phys. Rev. C [Internet]. 2013;88:054307. 访问链接
Haxton TK, Zhou H, Tamblyn I, Eom D, Hu Z, Neaton JB, Heinz TF, Whitelam S. Competing thermodynamic and dynamic factors select molecular assemblies on a gold surface. 2013;(26).
Zhang Y. Y., Sun Z. D., Meng W.G. Complex non-marine deep-water reservoir prediction: a case study from Xingma area, Liaohe Oil field, China, in 75th EAGE Expanded Abstract.; 2013. 访问链接
Yin N, Pei J, Lai L. A comprehensive analysis of the influence of drug binding kinetics on drug action at molecular and systems levels. Molecular BioSystems [Internet]. 2013;(6):1381-1389. 访问链接
Zhang C, Shen Q, Tang B, Lai L. Computational design of helical peptides targeting TNFα. Angewandte Chemie - International Edition [Internet]. 2013;(42):11059-11062. 访问链接

Pages