基本情况

张科锋,博士,浙江大学宁波理工学院教授。19975月至20005月苏格兰丹迪大学进修博士后;2000620023月苏格兰作物研究所担任研究助理;20024月至20123月英国华威大学国际园艺研究所任研究员。

 

研究领域

农业水文动力学建模、模拟土壤–植物–大气连续体(SPAC)系统中水、碳和养分循环及对作物生产对环境的影响、研发基于模型的在作物生产中水和养分优化利用的决策系统、计算流体力学及计算水文学、沉积物和溶解物在地表水和地下水中的迁移、逆向建模与优化

 

论文发表

  1. Sun Y., Hu K., Zhang K., Jiang L., Xu Y. (2012). Simulation of nitrogen fate for greenhouse cucumber grown under different water and fertilizer management using the EU-Rotate N model.Agricultural Water Management. http://dx.doi.org/10.1016/j.agwat.2012.06.001
  2. Burns I. G., Zhang K., Turner M. K., Lynn J., McClement S., Hand P., Pink D. (2011). Genotype and Environment effects on nitrate accumulation in a diversity set of 48 lettuce accessions at commercial maturity: their association with shoot weight and development, and with the concentrations of water,assimilated carbon and assimilated nitrogen in their tissues. Journal of the Science of Food and Agriculture 91: 2217–2233.3
  3. Zhang K., Hilton H. W., Greenwood D.J., Thompson A. J. (2011). A rigorous approach of determining FAO56 dual crop coefficient using soil sensor measurements and inverse modeling techniques. Agricultural Water Management 98: 1081-1090
  4. Burns I. G., Zhang K., Turner M. K., Meacham M., Al-Redhiman K., Lynn J., Broadley M., Hand P.,Pink D. (2011). Screening for the effects of genotype and environment on nitrate accumulation in lettuce species. Journal of the Science of Food and Agriculture 91: 553–562
  5. Burns I. G., Zhang K.*, Turner M. K., Edmondson R. (2011). Iso-osmotic regulation of nitrate accumulation in lettuce. Journal of Plant Nutrition 34: 283-313
  6. Zhang K., Zhang T., Yang D. (2010). An explicit hydrological algorithm for basic flow and transport equations and its application in agro-hydrological models for water and nitrogen dynamics. Agricultural Water Management 98: 114–123
  7. Zhang K., Greenwood D. J., Spracklen W. P., Rahn C. R., Hammond J. P., White P. J., Burns I. G. (2010). A universal agro-hydrological model for water and nitrogen cycles in the soil-crop system SMCR_N: critical update and further validation. Agricultural Water Management 97: 1411–1422
  8. Zhang K. (2010). Evaluation of a generic agro-hydrological model for water and nitrogen dynamics (SMCR_N) in the soil-wheat system. Agriculture, Ecosystems & Environment 137: 202–212
  9. Zhang K., Burns I. G., Greenwood D. J., Hammond J. P., White P. J. (2010). Developing a reliable strategy to infer the effective soil hydraulic properties from field evaporation experiments for agrohydrological models. Agricultural Water Management 97: 399–409
  10. Rahn C. R., Zhang K., Lillywhite R., Ramos C., Doltra J., de Paz J. M., Riley H., Fink M., Nendel C., Thorup Kristensen K., Pedersen A., Piro F., Venezia A., Firth C., Schmutz U., Rayns F.
  11. Strohmeyer K. (2010). EU-Rotate_N – a European decision support system – to predict environmental and economic consequences of the management of nitrogen fertiliser in crop rotations. European Journal of Horticultural Science 75: 20–32
  12. Pedersen A., Zhang K., Thorup-Kristensen K., Jensen L. S. (2010). Modelling diverse root density dynamics and deep nitrogen uptake – A simple approach. Plant and Soil 326: 493–510
  13.  Greenwood D. J., Zhang K., Hilton H., Thompson A. (2010). Opportunities for improving irrigation efficiency with quantitative models, soil water sensors and wireless technology. Journal of Agricultural Science 148: 1–16
  14. Zhang K., Yang D., Greenwood D. J., Rahn C. R., Thorup-Kristensen K. (2009). Development and critical evaluation of a generic 2-D agro-hydrological model (SMCR_N) for the responses of crop yield and nitrogen composition to nitrogen fertilizer. Agriculture, Ecosystems and Environment 132: 160–172
  15. Yang D., Zhang T., Zhang K.*, Greenwood D. J., Hammond J., White P. J. (2009). An easily implemented agro-hydrological procedure with dynamic root simulation for water transfer in the crop-soil system: validation and application. Journal of Hydrology 370: 177–190