Determination of Carbon and Nitrogen in Plant Tissue
Applications | 2021 | LECOInstrumentation
Accurate measurement of carbon and nitrogen in crop plant tissues is critical for assessing soil organic matter content, estimating nitrogen availability, and optimizing fertilization strategies. This analysis supports growers of high-value crops such as tobacco, cotton, and fruit by diagnosing nutritional status, improving nutrient uptake efficiency, and guiding precision agriculture decisions.
This application note illustrates the use of the LECO CN828 combustion analyzer to quantify total carbon and nitrogen in dried plant tissue samples. The study demonstrates instrument setup, calibration, sample preparation, analysis parameters, and typical performance metrics for reference materials and plant tissue matrices.
A uniform sample preparation protocol involves drying plant tissue at 80–85 °C for two hours, storing samples in a desiccator, and weighing approximately 0.25 g into tin foil cups. Moisture corrections are applied via software if samples are not pre-dried.
Analysis employs high-purity oxygen combustion in a vertical quartz furnace at 950 °C, followed by moisture removal in a thermoelectric cooler. Combustion gases mix in a ballast vessel before a selected aliquot (3 cm³ or 10 cm³) is carried by helium or argon to detectors: non-dispersive infrared (NDIR) for CO₂ (carbon) and thermal conductivity (TC) for N₂ (nitrogen). Key operational parameters include:
The LECO CN828 carbon/nitrogen determinator features a pure oxygen combustion furnace, thermoelectric moisture trap, ballast mixing chamber, and dual detection via NDIR and TC cells. The system supports both helium and argon carrier gases and interchangeable aliquot loops for flexible sensitivity and throughput.
Using linear full-range calibration for carbon and force-through-origin calibration for nitrogen with EDTA reference materials, the CN828 delivered high accuracy (<0.3 % C and <0.06 % N standard deviation) across tobacco, orchard leaf, and alfalfa samples. Helium carrier gas and the 10 cm³ aliquot loop yielded the best precision for low nitrogen levels. Argon showed slightly reduced sensitivity but remained suitable for routine analyses. Results were consistent across matrices with typical values: tobacco ~47 % C, 2.5 % N; orchard leaves ~49.5 % C, 2.3 % N; alfalfa ~44.2 % C, 3.1 % N.
The described approach provides rapid (under five minutes per sample), reproducible, and accurate carbon and nitrogen data. Laboratories benefit from streamlined calibration, minimal sample handling, and software-guided moisture correction. Growers and agronomists can apply results to optimize fertilizer regimes, monitor soil organic matter, and troubleshoot crop nutritional disorders.
Emerging developments include coupling CN analysis with isotope ratio mass spectrometry for traceability studies, integration of high-throughput autosamplers for large agronomic trials, and adaptation to alternative green carrier gases. Advances in software algorithms may further automate blank corrections and drift compensation, while miniaturized combustion modules could enable field-deployable C/N analyzers.
The LECO CN828 provides a robust platform for simultaneous carbon and nitrogen determination in plant tissues. Its configurable carrier gas options, precise thermal conductivity detection, and flexible aliquot loops enable high accuracy and throughput. This methodology supports critical agronomic assessments and contributes to sustainable crop management practices.
Elemental Analysis
IndustriesFood & Agriculture
ManufacturerLECO
Summary
Significance of Carbon and Nitrogen Determination in Plant Tissue
Accurate measurement of carbon and nitrogen in crop plant tissues is critical for assessing soil organic matter content, estimating nitrogen availability, and optimizing fertilization strategies. This analysis supports growers of high-value crops such as tobacco, cotton, and fruit by diagnosing nutritional status, improving nutrient uptake efficiency, and guiding precision agriculture decisions.
Objectives and Study Overview
This application note illustrates the use of the LECO CN828 combustion analyzer to quantify total carbon and nitrogen in dried plant tissue samples. The study demonstrates instrument setup, calibration, sample preparation, analysis parameters, and typical performance metrics for reference materials and plant tissue matrices.
Methodology and Instrumentation
A uniform sample preparation protocol involves drying plant tissue at 80–85 °C for two hours, storing samples in a desiccator, and weighing approximately 0.25 g into tin foil cups. Moisture corrections are applied via software if samples are not pre-dried.
Analysis employs high-purity oxygen combustion in a vertical quartz furnace at 950 °C, followed by moisture removal in a thermoelectric cooler. Combustion gases mix in a ballast vessel before a selected aliquot (3 cm³ or 10 cm³) is carried by helium or argon to detectors: non-dispersive infrared (NDIR) for CO₂ (carbon) and thermal conductivity (TC) for N₂ (nitrogen). Key operational parameters include:
- Furnace temperature: 950 °C
- Afterburner temperature: 850 °C
- Carrier gas: helium (preferred for sensitivity) or argon
- Aliquot loop sizes: 10 cm³ for low nitrogen range precision; 3 cm³ for extended reagent life
- Burn profile flow steps: 5.00 L/min for 40 s, 1.00 L/min for 30 s, then 5.00 L/min until end
Used Instrumentation
The LECO CN828 carbon/nitrogen determinator features a pure oxygen combustion furnace, thermoelectric moisture trap, ballast mixing chamber, and dual detection via NDIR and TC cells. The system supports both helium and argon carrier gases and interchangeable aliquot loops for flexible sensitivity and throughput.
Main Results and Discussion
Using linear full-range calibration for carbon and force-through-origin calibration for nitrogen with EDTA reference materials, the CN828 delivered high accuracy (<0.3 % C and <0.06 % N standard deviation) across tobacco, orchard leaf, and alfalfa samples. Helium carrier gas and the 10 cm³ aliquot loop yielded the best precision for low nitrogen levels. Argon showed slightly reduced sensitivity but remained suitable for routine analyses. Results were consistent across matrices with typical values: tobacco ~47 % C, 2.5 % N; orchard leaves ~49.5 % C, 2.3 % N; alfalfa ~44.2 % C, 3.1 % N.
Benefits and Practical Applications of the Method
The described approach provides rapid (under five minutes per sample), reproducible, and accurate carbon and nitrogen data. Laboratories benefit from streamlined calibration, minimal sample handling, and software-guided moisture correction. Growers and agronomists can apply results to optimize fertilizer regimes, monitor soil organic matter, and troubleshoot crop nutritional disorders.
Future Trends and Potential Applications
Emerging developments include coupling CN analysis with isotope ratio mass spectrometry for traceability studies, integration of high-throughput autosamplers for large agronomic trials, and adaptation to alternative green carrier gases. Advances in software algorithms may further automate blank corrections and drift compensation, while miniaturized combustion modules could enable field-deployable C/N analyzers.
Conclusion
The LECO CN828 provides a robust platform for simultaneous carbon and nitrogen determination in plant tissues. Its configurable carrier gas options, precise thermal conductivity detection, and flexible aliquot loops enable high accuracy and throughput. This methodology supports critical agronomic assessments and contributes to sustainable crop management practices.
Content was automatically generated from an orignal PDF document using AI and may contain inaccuracies.
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