Automated Determination of Nitrogen-15-Labeled Dinitrogen and Nitrous Oxide by Mass Spectrometry

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Automated Determination of Nitrogen-15-Labeled Dinitrogen and Nitrous Oxide by Mass Spectrometry

R. J. Stevens^* and R. J. Laughlin

Dep. of Agriculture for Northern Ireland, Newforge Lane, Belfast, BT9 5PX, UK

G. J. Atkins and S. J. Prosser

Europa Scientific Ltd., Electra Way, Crewe, CW1 1ZA, UK

*Corresponding author.

ABSTRACT

The ¹⁵N content of N₂ and N₂O emitted from ¹⁵N-enriched soilsconveys information about their sources; such information canonly be obtained by mass spectrometry. Conventional dual-inletisotoperatio mass spectrometry (IRMS) involve complex gas samplingand inlet systems, which limit the use of the technique. Continuous-flowIRMS was evaluated for the automated analysis of ¹⁵N-labeledN₂ or N₂O. A gas sample is flushed from a vial by a He carrierstream. Carbon dioxide, NO, and water are chemically removedprior to chromatographic separation of N₂ from N₂O. For N₂ analysis,the carrier stream is passed through a Cu reduction column toremove O₂. A triple-collector isotope-ratio mass spectrometeranalyzes a portion of the carrier stream for N₂ at m/z 28, 29,and 30. Accurate values for ratio (29/28 and 30/28) differencesin normal and enriched atmospheres were obtained from enrichmentsup to 2 atom % ¹⁵N with coefficients of variation (CVs) rangingfrom 0.07 to 1.37%. The reduction column is bypassed for theanalysis of N₂O at m/z 44, 45, and 46. From the 45/44 ratios,the ¹⁵N content of the N₂O could be determined accurately withenrichments up to 40 atom %. Precision depended on concentrationand enrichment, with CVs ranging from 10% for 15 µL N₂OL^–1 at natural abundance to <1% for 100 µL N₂OL^–1 at 10 atom % ¹⁵N. The concentration of N₂O could bequantified from the ion currents at m/z 44, 45, and 46 witha detection limit of 2.1 µL N₂O L^–1. A batch of132 samples can be analyzed automatically for N₂ or N₂O at arate of six determinations per hour. Automation of ¹⁵N determinationin N₂ and N₂O should aid the study of the processes resultingin evolution of these gases from soil.

Received for publication July 24, 1992.

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The SCI Journals	Agronomy Journal		Crop Science
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				T. J. Clough, F. M. Kelliher, R. R. Sherlock, and C. D. Ford Lime and Soil Moisture Effects on Nitrous Oxide Emissions from a Urine Patch Soil Sci. Soc. Am. J., September 1, 2004; 68(5): 1600 - 1609. [Abstract] [Full Text] [PDF]

				C. Muller, M. K. Abbasi, C. Kammann, T. J. Clough, R. R. Sherlock, R. J. Stevens, and H.-J. Jager Soil Respiratory Quotient Determined via Barometric Process Separation Combined with Nitrogen-15 Labeling Soil Sci. Soc. Am. J., September 1, 2004; 68(5): 1610 - 1615. [Abstract] [Full Text] [PDF]

				Y. Master, R. J. Laughlin, R. J. Stevens, and A. Shaviv Nitrite Formation and Nitrous Oxide Emissions as Affected by Reclaimed Effluent Application J. Environ. Qual., May 1, 2004; 33(3): 852 - 860. [Abstract] [Full Text] [PDF]

				Y. Master, R. J. Laughlin, U. Shavit, R. J. Stevens, and A. Shaviv Gaseous Nitrogen Emissions and Mineral Nitrogen Transformations as Affected by Reclaimed Effluent Application J. Environ. Qual., July 1, 2003; 32(4): 1204 - 1211. [Abstract] [Full Text] [PDF]

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