Assessing the surface heating effect of the open-path analyzer of an eddy covariance system with fine-wire thermocouples

doi:10.13287/j.1001-9332.201703.023

Abstract

Abstract: The open-path CO₂/H₂O analyzer that is currently widely used in the eddy covariance (EC) system possesses a surface heating effect, which may influence the accuracy of the eddy-flux measurements. Taking the open-path EC system in the temperate deciduous forest of the Maoershan Ecosystem Research Station as a case, we assessed the heating effect of the open-path CO₂/H₂O ana-lyzer (Li-7500) with fine-wire thermocouples and tested the applicability of Burba’s equations. The results indicated that between April 23 and May 28 in 2016, the daytime air temperature in the mid-optical-path of the Li-7500 was on average 0.2 ℃ higher than the ambient air temperature, while the nocturnal temperature was almost equal, with the peak of the heating often occurring in the morning transition period and at noon or in the early afternoon. The diurnal variation in the heating effect on the sensible heat flux (H_S,HE) estimated from the simple linear-fitting models in the fourth method by Burba (BurbaLF) was overall a rectangle-like wave, whereas that from the multiple regression models (BurbaMR) showed a weak mono-peak shape. Compared with direct mea-surements (K079) with the K-type fine-wire thermocouples (with a 0.079 mm diameter of single bare wire) and the H_S,HE modeled with two fine-wire thermocouples (K079Model), the estimated H_S,HE with the BurbaLF and BurbaMR varied little in the daytime with a lower but wider daytime-peak (20 W·m^-2), a sharp transition between daytime and nighttime, and a typical nocturnal va-lue of ＜ 5 W·m^-2. The peak values of H_S,HE estimated from the K079 and K079Model could be higher than 40 W·m^-2, and the values at night fluctuated around zero. The sensible heat flux in the optical-path of the Li-7500 was increased by 13.6% during the daytime. The value of the daytime heating effect on the CO₂ turbulent flux (F_c,HC) estimated from the K079 and K079Model was averaged about 0.5 mg CO₂·m^-2·s^-1, twice of the value estimated previously. Compared with the direct measurements, the Burba equations underestimated the F_c,HC around the noon due to the inadequate H_S,HE, but overestimated the F_c,HC in the morning, the late afternoon and the night because of over-corrections of H_S,HE, resulting in an overall overestimate of F_c,HC. These findings validated that both K079 and K079Model methods can be used to estimate the F_c,HC.

WANG Xing-chang, WANG Chuan-kuan, LIU Fan, ZHEN Xiao-jie. Assessing the surface heating effect of the open-path analyzer of an eddy covariance system with fine-wire thermocouples[J]. Chinese Journal of Applied Ecology, 2017, 28(3): 983-991.

References

[1] Leuning R, Judd M. The relative merits of open- and closed-path analysers for measurements of eddy fluxes. Global Change Biology, 1996, 2: 241-253
[2] Hirata R, Hirano T, Mogami J, et al. CO₂ flux mea-sured by an open-path system over a larch forest during the snow-covered season. Phyton, 2005, 45: 347-351
[3] Amiro B, Orchansky A, Sass A. A perspective on carbon dioxide flux measurements using an open-path infrared gas analyzer in cold environments. Proceedings of 27^th Annual Conference of Agricultural and Forest Meteorology, San Diego, California, 2006: 23-34
[4] Burba GG, McDermitt DK, Grelle A, et al. Addressing the influence of instrument surface heat exchange on the measurements of CO₂ flux from open-path gas analyzers. Global Change Biology, 2008, 14: 1854-1876
[5] Reverter B, Carrara A, Fern Y, et al. Adjustment of annual NEE and ET for the open-path IRGA self-heating correction: Magnitude and approximation over a range of climate. Agricultural and Forest Meteorology, 2011, 151: 1856-1861
[6] Amiro B. Estimating annual carbon dioxide eddy fluxes using open-path analysers for cold forest sites. Agricultural and Forest Meteorology, 2010, 150: 1366-1372
[7] Ueyama M, Hirata R, Mano M, et al. Influences of various calculation options on heat, water and carbon fluxes determined by open- and closed-path eddy cova-riance methods. Tellus B, 2012, 64: 19048. DOI: 10.3402/tellusb.v64i0.19048
[8] Xiao J, Sun G, Chen J, et al. Carbon fluxes, evapotranspiration, and water use efficiency of terrestrial ecosystems in China. Agricultural and Forest Meteorology, 2013, 182/183: 76-90
[9] Chen Z, Yu G, Ge J, et al. Temperature and precipitation control of the spatial variation of terrestrial ecosystem carbon exchange in the Asian region. Agricultural and Forest Meteorology, 2013, 182/183: 266-276
[10] Oechel WC, Laskowski CA, Burba G, et al. Annual patterns and budget of CO₂ flux in an Arctic tussock tundra ecosystem. Journal of Geophysical Research: Biogeosciences, 2014, 119: 323-339
[11] Bowling D, Bethers-Marchetti S, Lunch CK, et al. Carbon, water, and energy fluxes in a semiarid cold desert grassland during and following multiyear drought. Journal of Geophysical Research: Biogeosciences, 2010, 115: doi:10.1029/2010JG001322
[12] Lüers J, Westermann S, Piel K, et al. Annual CO₂ budget and seasonal CO₂ exchange signals at a high Arctic permafrost site on Spitsbergen, Svalbard archipe-lago. Biogeosciences, 2014, 11: 6307-6322
[13] Frank JM, Massman WJ, Ewers BE, et al. Ecosystem CO₂/H₂O fluxes are explained by hydraulically limited gas exchange during tree mortality from spruce bark beetles. Journal of Geophysical Research: Biogeosciences, 2014, 119: 1195-1215
[14] Emmerton CA, St. Louis VL, Humphreys ER, et al. Net ecosystem exchange of CO₂ with rapidly changing high Arctic landscapes. Global Change Biology, 2016, 22: 1185-1200
[15] Zhu X-J (朱先进), Yu G-R (于贵瑞), Wang Q-F (王秋凤), et al. Instrument heating correction effect on estimation of ecosystem carbon and water fluxes. Chinese Journal of Ecology (生态学杂志), 2012, 31(2): 487-493 (in Chinese)
[16] Ji X-B (吉喜斌), Zhao W-Z (赵文智), Kang E-S (康尔泗), et al. Effect of the instument surface heating on CO₂ flux from open-path eddy covariance system at Linze station. Plateau Meteorology (高原气象), 2013, 32(1): 65-77 (in Chinese)
[17] Jrvi L, Mammarella I, Eugster W, et al. Comparison of net CO₂ fluxes measured with open- and closed-path infrared gas analyzers in an urban complex environment. Boreal Environment Research, 2009, 14: 499-514
[18] Grelle A, Burba G. Fine-wire thermometer to correct CO₂ fluxes by open-path analyzers for artificial density fluctuations. Agricultural and Forest Meteorology, 2007, 147: 48-57
[19] Wang X-C (王兴昌), Wang C-K (王传宽). Effects of coordinate rotations on eddy fluxes over a forest on a mountainous terrain in Northeast China. Chinese Journal of Applied Ecology (应用生态学报), 2016, 27(9): 2779-2788 (in Chinese)
[20] Liu F (刘帆), Wang C-K (王传宽), Wang X-C (王兴昌). Monitoring temporal dynamics in leaf area index of the temperate broadleaved deciduous forest in Maoershan region with tower-based radiation measurements. Chinese Journal of Applied Ecology (应用生态学报), 2016, 27(8): 2409-2419 (in Chinese)
[21] Liu Z, Wang X, Chen JM, et al. On improving the accuracy of digital hemispherical photography measurements of seasonal leaf area index variation in deciduous broadleaf forests. Canadian Journal of Forest Research, 2015, 45: 721-731
[22] Wang X, Wang C, Li Q. Wind regimes above and below a temperate deciduous forest canopy in complex terrain: Interactions between slope and valley winds. Atmosphere, 2015, 6: 60-87
[23] Jiao Z (焦振), Wang C-K (王传宽), Wang X-C (王兴昌). Spatio-temporal variations of CO₂ concentration within the canopy in a temperate deciduous forest, Northeast China. Chinese Journal of Plant Ecology (植物生态学报), 2011, 35(5): 512-522 (in Chinese)
[24] Webb EK, Pearman GI, Leuning R. Correction of flux measurements for density effects due to heat and water vapour transfer. Quarterly Journal of the Royal Meteorological Society, 1980, 106: 85-100
[25] Warton DI, Wright IJ, Falster DS, et al. Bivariate line-fitting methods for allometry. Biological Reviews, 2006, 81: 259-291
[26] Wang X, Wang C, Guo Q, et al. Improving the CO₂ storage measurements with a single profile system in a tall-dense-canopy temperate forest. Agricultural and Fore-st Meteorology, 2016, 228/229: 327-338
[27] Burba G, Anderson D. A brief practical guide to eddy covariance flux measurements: Principles and workflow examples for scientific and industrial applications. Li-Cor Biosciences, Lincoln, USA, 2010: 56-65
[28] Zhang JH, Han SJ, Yu GR. Seasonal variation in carbon dioxide exchange over a 200-year-old Chinese broad-leaved Korean pine mixed forest. Agricultural and Forest Meteorology, 2006, 137: 150-165