CI-700系列叶片光谱分析仪 CI-710S在CI-710的基础进行了升级将UMPC与仪器整合。电池可随时更换无需担心电量不足问题;光谱范围增加,功能更加强大可以非破坏性测量叶片的透射光、吸收光、反射光光谱。通过光谱可以定性或定量地研究叶片内各组分叶绿素a或b、蛋白质、糖、矿物质等。直观的光谱图像和现场数据存储,为植物叶片光合作用、植物遗传特性、植物胁迫生理、植物病理等方面研究提供可靠的分析方法。
主要性能
Ø 携带方便,室内野外均可使用
Ø 非破坏性精确的测量叶片在360-1100 nm波长范围内的反射率、透射率和吸收率
Ø 操作简单,现场实时测量
Ø 内嵌式终端处理器,快速测量、存储和分析
Ø SpectaSnap分析软件功能强大,已装载多种反射计算模型和吸收计算模型
Ø 允许客户自己创建测量模型
测量参数
Ø CNVDI、NVDI、ARVI等多个参数
Ø 植物叶片反射率、透射率和吸收率或果实的反射率
Ø 定性或定量研究叶片内各组分叶绿素a或b、蛋白质、糖、矿物质等
应用领域
广泛的应用于植物叶片光合作用、植物遗传特性、植物胁迫生理、植物病理等方面研究。
野外测量
选购指南
光谱探测器、CI-700LP叶夹、说明书、充电器、便携式仪器箱
参考文献
原始数据来源:Google Scholar
1. Kaivosoja, J., et al. (2021). "Reference Measurements in Developing UAV Systems for Detecting Pests, Weeds, and Diseases." Remote Sensing 13(7): 1238.
2. Gruszka, D., et al. (2020). "Insights into Metabolic Reactions of Semi-Dwarf, Barley Brassinosteroid Mutants to Drought." International Journal of Molecular Sciences 21(14): 5096.
3. Oliveira, L. F. R. d. and R. C. Santana (2020). "Estimation of leaf nutrient concentration from hyperspectral reflectance in Eucalyptus using partial least squares regression." Scientia Agricola 77.
4. Saja, D., et al. (2020). "Powdery Mildew-Induced Hormonal and Photosynthetic Changes in Barley Near Isogenic Lines Carrying Various Resistant Genes." International Journal of Molecular Sciences 21(12): 4536.
5. Evelyn, S., et al. (2019). "The impact of light on vase life in (Anthurium andraeanum Hort.) cut flowers." Postharvest Biology and Technology.
6. OLIWA, J., et al. (2019). "Response of the photosynthetic apparatus in the tropical fern Platycerium bifurcatum to increased ozone concentration." Photosynthetica 57(4): 1119-1129.
7. RB, B., et al. (2019). "Phenotyping Capsicum spp. for luminosity and temperature effects in the field and greenhouse." Proceedings of the 17th EUCARPIA Meeting on Genetics and Breeding of Capsicum and Eggplant,.
8. Shaar-Moshe, L., et al. (2019). "Phenotypic and metabolic plasticity shapes life-history strategies under combinations of abiotic stresses." Plant direct 3(1): e00113-e00113.
