CI-700 Series Blade Spectrometer CI-710S has been upgraded to integrate UMPC with instruments on the basis of CI-710.The battery can be replaced at any time without worrying about insufficient charge; the spectrum range is increased, and the function is more powerful, which can non-destructively measure the transmitted, absorbed and reflected light spectrum of the blade.Through spectroscopy, chlorophyll a or b, proteins, sugars, minerals, etc. in the leaves can be studied qualitatively or quantitatively.Intuitive spectral images and on-site data storage provide reliable analytical methods for research on plant leaf photosynthesis, plant genetic characteristics, plant stress physiology, plant pathology, etc.

Main performance

Ø  Easy to carry, available indoors and outdoors

Ø  Non-destructive and accurate measurement of the reflectivity, transmittance and absorption of the blade in the wavelength range of 360-1100 nm

Ø  Simple operation, real-time measurement on site

Ø  Embedded terminal processor for rapid measurement, storage and analysis

Ø  SpectaSnap analysis software is powerful and has loaded multiple reflection calculation models and absorption calculation models.

Ø  Allow customers to create measurement models themselves

Measurement parameters

Ø  CNVDI, NVDI, ARVI and other parameters

Ø  Reflectivity, transmittance and absorption of plant leaves or reflectivity of fruits

Ø  Qualitative or quantitative study of chlorophyll a or b, protein, sugar, minerals, etc. in the leaves

Application areas

It is widely used in research on plant leaf photosynthesis, plant genetic characteristics, plant stress physiology, plant pathology and other aspects.

Field measurement

Purchase Guide

Spectroscopic detector, CI-700LP leaf clip, manual, charger, portable instrument box

References

Original data source: Google Scholar

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3. Oliveira, L. F. R. d. and R. C. Santana (2020). "Estimation of leaf nutrient concentration from hyperspectral reflection 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., ETA. (2019). "the impact o flight on vase life in (ant suddenly IU man's RA EA num Hort.) cut flowers." post harvest biology and technology.

6. OLIWA, J., et al. (2019). "Response of the photosynthesis 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.