Edith Fallon scite author profile

Improvements of nitrogen use effi ciency (NUE) may be achieved through the use of sensing tools for N status determination. Leaf and canopy chlorophyll, as well as leaf polyphenolics concentrations, are characteristics strongly aff ected by N availability that are oft en used as a surrogate to direct plant N status estimation. Approaches with near-term operational sensors, handheld and tractor-mounted, for proximal remote measurements are considered in this review. However, the information provided by these tools is unfortunately biased by factors other than N. To overcome this obstacle, normalization procedures such as the well-fertilized reference plot, the no-N reference plot, and relative yield are oft en used. Methods to establish useful relationships between sensor readings and optimal N rates, such as critical NSI (nitrogen suffi ciency index), INSEY (in-season estimated yield), and the relationship between chlorophyll meter readings, grain yield, and sensor-determined CI (chlorophyll index) are also reviewed. In a few cases, algorithms for translating readings into actual N fertilizer recommendation have been developed, but their value still seems limited to conditions similar to the ones where the research was conducted. Near-term operational sensing can benefi t from improvements in sensor operational characteristics (size and shape of footprint, positioning) or the choice of light wavebands more suitable for specifi c conditions (i.e., genotype, growth stage, or crop density). However, one important limitation to their widespread use is the availability of algorithms that would be reliable in a variety of soil and weather conditions.

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Sensing of Crop Nitrogen Status: Opportunities, Tools, Limitations, and Supporting Information Requirements

Tremblay

Fallon

Ziadi

2011

hortte

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Diagnosing nitrogen (N) sufficiency in crops is used to help insure more effective management of N fertilizer application, and several indicators have been proposed to this end. The N nutrition index (NNI) offers a reliable measurement, but it is relatively difficult to determine. This index is based on the relationship between plant tissue N concentration and the biomass of the plant's aerial parts. However, a good estimate of the NNI should be obtained by nondestructive methods that can be carried out quickly. Although dependent on sites, chlorophyll meter (CM) measurements have been correlated with the NNI in corn (Zea mays). Since chlorophyll can be estimated through remote sensing, the possibility of quickly obtaining measurements for large surface areas points to practical applications for precision agriculture. When combined with the mapping of soil properties such as apparent electrical conductivity (EC), elevation and slope, such chlorophyll measurements make it possible to derive N fertilization recommendations by taking into account natural variations in the soil. Recently, an instrument called the Dualex (FORCE-A, Orsay, France) is marketed, which uses measurement methods based on the fluorescent properties of plant tissues. It is similar to the CM in terms of its operating principle but it measures polyphenolics (Phen), compounds that accumulate in the epidermis of leaves under N stress. Epidermal transmittance to ultraviolet light is assessed by the fluorescence excitation ratio F(ultraviolet)/F(REF), where F(ultraviolet) is the fluorescence excitation detected following ultraviolet excitation, and F(REF) is the fluorescence detected on excitation at a reference wavelength, not absorbed by the epidermis. Although the Dualex generally did not identify more differences among treatments than the CM in our studies on wheat (Triticum aestivum), corn, and broccoli (Brassica oleracea ssp. italica), combining the two measurements in a chlorophyll/Phen ratio improved the relationships with crop N nutrition status appreciably. This ratio can also be estimated by remote sensing techniques. The NNI on its own does not constitute an economically optimal recommendation for N fertilizer [economically optimal N rate (EONR)]. The EONR is the N rate at which profit is greatest. Work is currently being done to use overfertilized reference plots for this purpose and to permit an improved correlation between the indicator (NNI or chlorophyll) and EONR.

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N₂O emissions from an irrigated and non‐irrigated organic soil in eastern Canada as influenced by N fertilizer addition

Rochette

Tremblay

Fallon

et al. 2010

European J Soil Science

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Drainage and cultivation of organic soils often result in large nitrous oxide (N 2 O) emissions. The objective of this study was to assess the impacts of nitrogen (N) fertilizer on N 2 O emissions from a cultivated organic soil located south of Montréal, QC, Canada, drained in 1930 and used since then for vegetable production. Fluxes of N 2 O were measured weekly from May 2004 to November 2005 when snow cover was absent in irrigated and non-irrigated plots receiving 0, 100 or 150 kg N ha −1 as NH 4 NO 3 . Soil mineral N content, gas concentrations, temperature, water table height and water content were also measured to help explain variations in N 2 O emissions. Annual emissions during the experiment were large, ranging from 3.6 to 40.2 kg N 2 O-N ha −1 year −1 . The N 2 O emissions were decreased by N fertilizer addition in the non-irrigated site but not in the irrigated site. The absence of a positive influence of soil mineral N content on N 2 O emissions was probably in part because up to 571 kg N ha −1 were mineralized during the snow-free season. Emissions of N 2 O were positively correlated to soil CO 2 emissions and to variables associated with the extent of soil aeration such as soil oxygen concentration, precipitation and soil water table height, thereby indicating that soil moisture/aeration and carbon bioavailability were the main controls of N 2 O emission. The large N 2 O emissions observed in this study indicate that drained cultivated organic soils in eastern Canada have a potential for N 2 O-N losses similar to, or greater than, organic soils located in northern Europe.

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Edith Fallon

Strategies to Make Use of Plant Sensors‐Based Diagnostic Information for Nitrogen Recommendations

Sensing of Crop Nitrogen Status: Opportunities, Tools, Limitations, and Supporting Information Requirements

N₂O emissions from an irrigated and non‐irrigated organic soil in eastern Canada as influenced by N fertilizer addition

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Edith Fallon

Strategies to Make Use of Plant Sensors‐Based Diagnostic Information for Nitrogen Recommendations

Sensing of Crop Nitrogen Status: Opportunities, Tools, Limitations, and Supporting Information Requirements

N2O emissions from an irrigated and non‐irrigated organic soil in eastern Canada as influenced by N fertilizer addition

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Resources

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N₂O emissions from an irrigated and non‐irrigated organic soil in eastern Canada as influenced by N fertilizer addition