Abstract
The ecosystem light response parameters, i.e. apparent quantum yield (α), maximum rate of ecosystem gross photosynthesis (Amax), and daytime ecosystem respiration (Rd), are very important when estimating regional carbon budgets. But they are not well understood in double cropping systems. Here, continuous flux data were collected from two rotation croplands in Yucheng (YC) and in Luancheng (LC) to describe the among-year variations in α, Amax, and Rd, and to investigate variation mechanism on an annual scale. The three parameters exhibited marked fluctuations during the observation years. The annual α, Amax, and Rd ranged from 0.0022–0.0059 mg CO2 μmol photon−1, from 2.33–4.43 mg CO2 m−2 s−1, and from 0.19–0.47 mg CO2 m−2 s−1 at YC, and from 0.0016–0.0021 mg CO2 μmol photon−1, from 3.00–6.30 mg CO2 m−2 s−1, and from 0.06–0.19 mg CO2 m−2 s−1 at LC, respectively. Annual α and Rd declined significantly when vapor pressure deficit (VPD) exceeded 1.05 kPa and increased significantly when canopy conductance (gc) exceed 6.33 mm/s at YC, but changed slightly when VPD and gc exceeded 1.16 kPa and 7.77 mm/s at LC, respectively. The fact that the negative effects of VPD and gc on α and Rd at LC were not as significant as they were at YC may be attributed to different climate conditions and planting species. A negative relationship (R2 = 0.90 for YC and 0.89 for LC) existed between VPD and gc. Therefore, the VPD, through its negative effect on gc, inhibited α and Rd indirectly. Among-year Amax variation was mainly influenced by the annual mean surface soil temperature (Ts) of non-growing season of wheat significantly (R2 = 0.59, P < 0.01). Therefore, in future climate change scenarios, these environmental effects need to be included in carbon cycle models so that the accuracy of the carbon budget estimation can be improved.
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Introduction
Recently, a large number of studies began to focus on the carbon (CO2) exchange flux at ecosystem level with the eddy covariance (EC) technique1,2,3,4. The net ecosystem carbon exchange (NEE) obtained from the eddy towers often shows high dependence on the photosynthetic proton flux density (PPFD), which can be described well by the Michaelis-Menten rectangular hyperbola model5. This model is extremely important because it is often utilized in gap filling strategies when there is missing flux data6,7. Moreover, deriving this relationship is among the very first steps taken when attempting to understand the effects of potential regulating mechanisms in ecosystem studies8.
The Michaelis-Menten rectangular hyperbola model has three parameters: the ecosystem apparent quantum yield (α), maximum rate of ecosystem gross photosynthesis (Amax), and the bulk daytime ecosystem respiration at PPFD = 0 (Rd). α is the maximum use of PPFD and the initial slope of the NEE-PPFD rectangular curve6. It reflects the utilization efficiency of weak light for ecosystems and biochemical characteristics of photosynthesis9. Amax, the value of asymptote of the light response curve, represents the light – saturated rate of CO2 assimilation10 and is an indicator of activity of the photosynthetic system in plants10,11. Approximately 50% of the photosynthate is back to atmosphere through canopy dark respiration (Rd)12, so Rd is an essential part of ecosystem carbon cycling. Because of their important roles in affecting the shape of NEE light response curves and attempting to examine the balance between plant photosynthesis and respiration13, the three parameters have been extensively researched as part of the overall assessment of the global carbon budget14.
Many studies have discussed the variations in ecosystem α, Amax, and Rd4,15, and their influencing factors16,17. The ecosystem α, Amax, and Rd could be affected by vapor pressure deficit (VPD)3,17,18,19, soil water content (SWC)1,20,21, temperature4,22, and biotic factors, such as leaf area index (LAI) and canopy conductance (gc)15. The variations in ecosystem α, Amax, and Rd usually show similar patterns and coincide with the trends of canopy development on a seasonal scale18. Some studies indicated that the light response parameters were stimulated under elevated air temperature (Ta)4,18,23, but other studies showed no relationship between them probably due to the photosynthate allocation and stomatal factors3. Dry condition, which is commonly characterized by high temperature, high VPD and deficient surface soil water, can greatly inhibit the parameters by promoting stomatal closure21, but some ecosystems were not affected by high VPD due to their tolerance of drought stress20.
Previous studies provided insight into the characteristics of NEE-PPFD relationship in terrestrial ecosystems under the scenario of global change. However, most studies were conducted over a single growing season per year in forests18,24, grassland3,4, and cropland21, which means that the fluctuation patterns for the parameters and the affecting mechanism in double cropping systems are still unknown. However, it is necessary to explore the light response characteristics of carbon exchange in such ecosystems because field management processes, such as frequent tilling and residue return, in a double cropping system could directly affect the soil organic carbon content and soil microorganism biomass25,26, both of which can influence the carbon cycle in double cropping agricultural areas. Furthermore, most previous studies that focused on agreoecosystem were based on short term flux databases (1~3 years). For example, Stirling, et al.27 investigated changes in the light response curve and parameters only during leaf development stage of maize. Zhang, et al.20 examined the effect of environmental factors on the light response parameters based on one year flux data. Zhang, et al.3 used three consecutive years to evaluate the seasonal variations in the light model parameters and the underlying mechanism. The short – term flux measurement can not produce statistical and reliable relationship between the parameters and potential affecting factors, so more long-term flux data are needed to improve our understanding of how the carbon exchange rate response to a wide range of different factors28.
In China, croplands cover the third largest area after forests and grassland29. The agroecosystem is easier to be affected by human activities than other ecosystems because farm land is intensively managed by humans30 who can increase carbon uptake through efficient crop management practices31. Therefore, agriculture is considered to be a strong contributor to the regional carbon budget32. The North China Plain is 3 × 105 km2 in size33. It is the largest agricultural production center in China and occupies approximately 18.6% of the total national agricultural area21. The North China Plain provides more than half of the wheat and about 33% of maize consumed in China34. A winter wheat-summer maize rotation cropping system is the main planting pattern in this area. Its large area and its importance to national economics mean that the North China Plain has a considerable effect on the regional carbon balance35,36. Therefore, exploring the photosynthetic features of the agricultural ecosystem in this region will help improve carbon cycle models and the accuracy of future net ecosystem carbon exchange predictions. Based on CO2 flux and micrometeorological measurements, the objectives of this study were to (1) describe the among-year variations in annual ecosystem α, Amax, and Rd by using continuous eddy covariance data for Yucheng (YC) from 2003 to 2012 and Luancheng (LC) from 2008 to 2012; and (2) analyze how environmental and biotic factors affect the annual ecosystem α, Amax, and Rd.
Results and Discussion
Variations in environmental and biotic factors
Figure 1 shows the seasonal and interannual patterns for monthly environmental factors, and the LAI at the YC and LC sites. The maximum and minimum values for the air and soil temperatures (Ts) occurred between July and August and between November and January of the next year, respectively. The annual mean air temperature (M-Ta) varied from 11.5 °C to 13.9 °C with a multi-year mean of 12.9 ± 0.7 °C (mean ± standard deviation) at the YC site and from 8.0 °C to 12.7 °C with a multi-year mean of 10.4 ± 2.2 °C at the LC site during the observation years. The annual mean for Ts varied from 11.2 °C to 13.5 °C at the YC site and from 12.5 °C to 13.6 °C at the LC site. The straw residue from the summer maize remained in the field after harvesting. Therefore, the Ts decrease was not as great as the Ta decrease when extreme cold weather occurred (Fig. 1a,b). As a result, the Ts was higher than the Ta in 2008–2009 and 2011–2012 at the LC site. Generally, the seasonal pattern for the monthly mean VPD had a single-peak curve at both sites, except for 2009 at the YC site. The annual mean VPD varied from 0.57 to 1.14 kPa at the YC site and from 0.32 to 1.07 kPa at the LC site during the observation years (Fig. 1a). Precipitation mainly occurred from June to September every year and the annual accumulated value was 528.3 mm and 399.5 mm at the YC and LC sites, respectively (Fig. 1c). The seasonal SWC variation often produced two peaks in one year, which occurred during the two growing seasons, respectively. The peak summer maize SWC value was higher than that for winter wheat, partially because of the routine irrigation during the growing season and the high precipitation frequency in summer. The annual mean SWC ranged from 0.34 to 0.48 m3 m−3 and from 0.29 to 0.33 m3 m−3 during the observation years at the YC and LC sites, respectively (Fig. 1b). The LAI was relatively low during the period from late October to mid-March of the next year, but then gradually increased to reach a maximum in May. The maximum LAI value for summer maize often occurred in August (Fig. 1c). Therefore, the relevant meteorological and biotical factors showed marked interannual variability, providing an opportunity to study the underlying mechanisms of the interannual variations in light response parameters, which will be discussed later in this paper.
The light response characteristic of NEE and a comparison with other studies
The parameters of the light response model exhibited distinct variations among years. Figures 2 and 3 show the relationship of NEE-PPFD at a half hourly scale from 2003–2012 and from 2008–2012 at the YC and LC sites, respectively. The absolute value of NEE (│NEE│, namely the carbon absorbed by the ecosystem) rose as the PPFD increased at low-to-intermediate PPFD levels, but │NEE│began to decline when the PPFD exceeded the light saturation point. Table 1 lists the annual ecosystem light response parameters derived from Eq. 2 using the collective averages for incident valid daytime PPFD and NEE. The annual ecosystem α, Amax, and Rd ranged from 0.0022–0.0059 mgCO2 μmol photon−1, from 2.33–4.43 mg CO2 m−2 s−1, and from 0.19–0.47 mg CO2 m−2 s−1 between 2003 and 2012 at the YC site, respectively. The annual ecosystem α, Amax, and Rd at the LC site ranged from 0.0016–0.0021 mg CO2 μmol photon−1, from 3.00–6.30 mg CO2 m−2 s−1, and from 0.06–0.19 mg CO2 m−2 s−1 between 2008 and 2012, respectively (Table 1). The multi-year means for annual ecosystem α and Rd were 0.0032 ± 0.0011 mg CO2 μmol photon−1 and 0.31 ± 0.077 mg CO2 m−2 s−1 at the YC site, respectively, which were higher than those recorded at the LC site (0.0018 ± 0.00018 mg CO2 μmol photon−1 for α and 0.13 ± 0.056 mg CO2 m−2 s−1 for Rd). However, the long term mean for annual ecosystem Amax at the YC site (3.15 ± 0.62 mg CO2 m−2 s−1) was lower than at the LC site (4.40 ± 1.22 mg CO2 m−2 s−1). The annual ecosystem α for the YC site was slightly higher than the results obtained for a winter wheat field in central Germany32 and a spring wheat field in Canada37 (0.0028 mg CO2 μmol photon−1 and 0.0016 mg CO2 μmol photon−1, respectively), but were still within the moderate range. The annual ecosystem Amax for the YC and LC sites in this study were also higher than the results obtained for a winter wheat field in central Germany32 and a spring wheat field in Canada37 (2.78 mg CO2 μmol photon−1, 3.01 mg CO2 μmol photon−1, respectively). However, the combined effects of the differences in raw data processing, curve fitting methods, environmental conditions, species composition, the photosynthesis pathway in different species, and land management could explain the dissimilarities in light response characteristics between different ecosystems or regions38.
Factors influencing the annual ecosystem light response parameters
Water conditions
Annual ecosystem α and Rd were inhibited when the annual mean for main growing season VPD was high at the YC site (Figs. 4 and 5). In this study, high VPDs commonly occur from May to July due to the low rainfall during this period, because a significant and positive relationship between annual mean for the main growing season VPD and annual accumulated precipitation was found, R2 = 0.59, P = 0.0008 (Fig. 6). Figure 4a shows that the annual mean VPD ranged from 0.90~1.14 kPa and from 1.08~1.69 kPa at the YC and LC sites, respectively. The maximum value for annual ecosystem α and Rd for the YC and LC sites occurred when the annual mean of main growing season VPD was 1.05 kPa and 1.16 kPa, respectively. However, the annual ecosystem α and Rd declined when the VPD exceeded the thresholds at the two sites. At the YC site, the multi-year means for annual ecosystem α and Rd when the VPD >1.05 kPa were significantly lower than when the VPD ≤1.05 kPa (P = 0.044) (Fig. 5), which indicated that VPD had negative effects on annual ecosystem α and Rd. The conclusion that a high VPD limited ecosystem light response parameters was consistent with previous studies. For example, Zhang, et al.18 thought that the ecosystem α of a subtropical Pinus plantation declined significantly when high VPD happened. The results of Zhang, et al.3 showed that the NEE light response coefficients were prohibited under dry conditions accompanied by high VPD in a steppe ecosystem. A study conducted in a grassland and cropland indicated that the α of both ecosystem decreased with increasing in VPD20.
There often exist high autocorrelation between Ta and VPD, so it is necessary to deconvolute whether the decrease in α and Rd was due to high atmosphere evaporative demand or to heat stress. This study adopted an approach that recommended by Zhang, et al.18 to distinguish which factor was more important. Figure 7a,b show the relationship between the residuals of the NEE – PPFD regression and Ta and VPD. The residuals did not change when Ta increased, but depended on VPD above 1.0–1.1 kPa. Moreover, we did not found relationship between M-Ta and annual light response parameters (Fig. 7c). The reason that no change of residuals with Ta may be related to that the drought stress was not prone to occur under the heat conditions at the two sites. In a word, the relationship between the residuals and VPD indicated VPD played an important role in depressing annual α and Rd compared with Ta.
The index of gc can explain why annual mean value of main growing season VPD depressed annual α and Rd. It is widely accepted that a high VPD would strongly limit plant photosynthesis due to stomata closure on a leaf scale39. Stomata closure can cause a decrease in the leaf internal CO2 concentration, which leads to a decline in net CO2 uptake and an imbalance between photochemical activity and the electron requirements for photosynthesis40. Stomata conductance is a parameter quantifying leaf stomata behavior, but on ecosystem scale, the stomata behavior of the whole ecosystem commonly quantified by gc41. The EC technique provides a good change to obtain the Bowen ratio (the ratio of the sensible heat flux to the latent heat flux), which is a key parameter for estimating gc. We found that there was a negative relationship between annual means for main growing season gc and VPD (Fig. 8), which meant that a high VPD restrain the gc significantly. The negative relationship between gc and VPD determined that the response trends of annual α and Rd to gc were similar to their responses to VPD (Fig. 9a,c). Figure 8b,d indicated that the multi-year means for annual ecosystem α and Rd when the gc < 6.33 mm/s were significantly lower than the gc ≥ 6.33 mm/s (P < 0.05). Therefore, the low annual ecosystem α and Rd in this study was partially result from weak annual mean gc, which was commonly caused by high annual mean VPD. As a result, the annual means for VPD, through its negative effect on gc, inhibited annual α and Rd indirectly at the YC site.
The effects of annual mean VPD and gc on α and Rd at LC site were not as significant as they were at YC site. The multi-year means for annual ecosystem α (0.0018 mg CO2 μmol photon−1) and Rd (0.13 mg CO2 m−2 s−1) when the VPD > 1.16 kPa were slightly lower than the multi-year means for annual ecosystem α (0.0019 mg CO2 μmol photon−1) and Rd (0.14 mg CO2 m−2 s−1) when the VPD ≤ 1.16 kPa (Fig. 5). The α and Rd when gc < 7.77 mm s−1 did not significantly differ from that when gc ≥ 7.77 mm s−1 (Fig. 9c,d). The different impact of VPD or gc on α and Rd between the two sites may be attributed to the climate condition and planting species. The annual rainfall at the LC site was 399.5 ± 170.0 mm (mean ± standard deviation) during 2008–2012, whereas it was 528.3 ± 197.2 mm at the YC site during 2003–2012, which meant that the climate at the LC site was more drier than the YC site, indicating that the wheat and maize cultivars planting in the LC site were the drought – tolerance cultivars. Previous studies indicated that the drought – tolerance cultivars of winter wheat have higher net photosynthetic rate under dry conditions compared with common cultivar42,43, this is because the decrement of photosynthesis for the drought – tolerance cultivars was smaller than common cultivars when water stress happened43. However, less rainfall would lead to an increase in VPD in this study, thereafter, lead to a decrease in gc (Figs. 8 and 9), indicating that the photosynthetic rate of these cultivars was still higher when the gc was lower. The conclusion that the VPD and gc had minor effects on α and Rd at the LC site indicated that field management practice was an potential factor influencing the characteristics of ecosystem light response.
Ts
Warm soil condition can not only enhance soil respiration44, but also impact the photosynthesis by affecting nutrient availability45. In this study, a significant and positive relationship was found between annual mean Ts for the non-main winter wheat growing season (the period from October to mid-March of the next year) and annual ecosystem Amax (R2 = 0.59, P < 0.01) (Fig. 4b), which showed that there was a lag response by the parameter to changing environmental conditions45. This result may be related to the long non-main growing season for winter wheat, during which the growth of the crop almost stopped. This period included the following stages: seedling growth, tillering, overwintering, green return, and standing. During this period, winter wheat LAI only changed slightly and ranged from 0.19 ± 0.015–0.21 ± 0.012 from the tillering stage to the standing stage at the YC site and from 0.17 ± 0.009–0.18 ± 0.008 at the LC site. The small change in LAI meant that the non-main growing season can be considered as the no-growth season for winter wheat. This finding was consistent with the study by Li, et al.4, who found that Ts in the non-growth season of an alpine dwarf shrubland had important effects on the interannual variation in ecosystem Amax. In this study, the crop management regime at both sites was straw return to the field after harvest, which meant that the soil could accumulate nutrients during non-main growing season for subsequent rapid plant growth from late March because the higher Ts in the non-main growing season stimulated litter decomposition and faster nutrient mineralization46, which would improve the available nutrient supply for subsequent plant growth.
Why did not SWC, M-Ta and leaf area affect light response parameters?
The effect of SWC on photosynthetic process of ecosystem may depend on soil moisture level. Although previous studies have indicated that SWC affected light response parameters20, we did not find any relationships between the photosynthetic characteristics and annual mean SWC (y = −0.0089X + 0.0067, R2 = 0.12, P = 0.40 for α vs. SWC, y = 9.37X − 0.41, R2 = 0.43, P = 0.07 for Amax vs. SWC and y = −0.29X + 0.42, R2 = 0.03, P = 0.69 for Rd vs. SWC). Fu, et al.1 and Tong, et al.21 concluded that the reason that ecosystem photosynthetic characteristics hardly varied at different soil moisture levels was related to sufficient irrigation or abundant precipitation. The SWC in this study was at a moderate level because there was sufficient irrigation twice per season for winter wheat and concentrated rain between June and September. Therefore, we suggested that the suitable soil water conditions were the main reason why SWC only had a minimal effect on the light response parameters. However, a high VPD still occurred despite there being enough water, which indicated that the soil structure, soil composition, and farmland management at the two sites may have enhanced soil water holding capacity and reduced soil water evaporation.
M-Ta did not affect annual α or the other model parameters (Fig. 7c) (P > 0.05), albeit close relationship between them reported by other studies4. The reason that M-Ta affected the interannual variations in ecosystem α, according to previous studies, was that soil and plant enzymatic reaction rates increased exponentially with rising temperature47. Furthermore, the variation in LAI has also been closely correlated with Ta4. However, the variations in LAI or plant enzymatic reactions were not completely affected by Ta in the rotations used in this study because the enzymatic reaction rates for winter wheat during the late growing stages were not affected by the Ta completely. Ta commonly reached its maximum value in August, which meant that when the winter wheat began to enter its senescence stage (mid-May to mid-June), Ta was beginning to continually increase. Furthermore, the correlation analysis suggested that Ta could only explain 9% of the change in LAI on a seasonal scale. The inconsistent decrease in the enzymatic activity of winter wheat or its LAI during the senescence stage, and the increase in Ta might impair the effect of M-Ta on the crop light response parameters on an annual scale. Li, et al.2 found a significant reduction in carbon assimilation when the Ta was >25 °C above cropland in the north of China. Therefore, the finding that light response parameters were not affected by Ta in this study might be a combined consequence of the special physiological characteristics of winter wheat and the non-moderate Ta.
LAI is an important factor affecting plant photosynthetic capability7. Although ecosystem carbon uptake has been found to be positively correlated with leaf assimilation area48, we did not find any relationship between the annual light parameters and maximum LAI (LAImax) (y = −0.0015X + 0.0053, R2 = 0.19, P = 0.27 for α vs. LAImax, y = 0.16X + 2.98, R2 = 0.007, P = 0.84 for Amax vs. LAImax, y = −0.12X + 0.45, R2 = 0.25, P = 0.21 for Rd vs. LAImax). This result indicated that the planting density of the crops in this study might not suitable for canopy light interception because the shade effect caused by high planting densities and a large leaf area reduce ecosystem photosynthesis capacity49. Furthermore, plant population photosynthesis is also closely related to the duration of the plant functional leaf50 other than LAI.
Conclusions
The long-term continuous eddy covariance data suggested that the among-year fluctuations in the light response parameters derived from the Michaelis-Menten rectangular hyperbola equation, i.e. ecosystem α, Amax, and Rd, were considerable during observation years at the YC and LC site. Annual mean of main – growing season VPD and gc had significant effects on the annual α and Rd at the YC site but minor effects on the parameters at the LC site. The different response of the annual α and Rd to VPD and gc might be related to differences in climate conditions and planting species between the two sites. A negative relationship existed between VPD and gc. So we indicated that the VPD inhibited α and Rd through its negative effect on gc. Among-year Amax variation was significantly affected by Ts of non-growing season of wheat. This study implied that sufficient rainfall and warm soil conditions during winter will enhance the ecosystem photosynthetic capacity under future climate change scenarios.
Materials and Methods
Site descriptions
The field experiments were conducted at Yucheng (YC) Comprehensive Experimental Station (36°57′N, 116°38′E; elevation: 23.4 m) in Shandong Province and at Luancheng (LC) Comprehensive Experimental Station (37°50′N, 114°40′E; elevation: 50.1 m) in Hebei Province. Both of the sites are within the East Asia monsoon region, which has a semi-humid and warm temperate climate. The mean annual temperature and precipitation are 13.1 °C and 528 mm, respectively, in YC (1975–2005)35 and 12.8 °C and 485 mm, respectively, in LC (1990–2010)36. Winter wheat (Triticum aestivum L.) and summer maize (Zea mays L.) were cultivated in rotation over the observational periods. At the YC site, the sowing and harvest dates for winter wheat varied from the 10th October to the 29th October and from the 7th June to the 16th June during the observation years, respectively, and the sowing and harvest dates for summer maize varied from the 13th June to the 22nd June and from the 30th September to the 14th October, respectively. At the LC site, the sowing and harvest dates for winter wheat varied from 7th October to 19th October and from 11th June to 17th June, and the sowing and harvest dates for summer maize varied from 6th June to 19th June and from 23rd September to 2nd October during the observation years, respectively. All of the straw residues from winter wheat and summer maize were returned to the field after harvest. Well water was used to irrigate the crops during the winter wheat reviving and jointing stages, and during the summer maize planting stages. Around 100–150 mm of water was added at each irrigation time36. The soil in the 1~20 cm layer consisted of clay loam (22.1%), silt loam (65.1%), and sandy loam (12.8%) at the YC site51 and was predominately sandy loam at the LC site52.
Flux and meteorological measurements
The monitoring instruments and data collection methods used at the YC and LC site were similar. A three-dimensional sonic anemometer (Model CSAT 3, Campbell Scientific Inc., Logan, Utah, USA) was used to monitor fluctuations in vertical wind velocity. The CO2 concentration and water vapor were monitored by an open-path and fast-response infrared gas analyzer (Model LI-7500, Li-Cor Inc., Nebraka, USA). The eddy covariance instruments were placed on the towers at a height of 2.8 m and 3.5 m at the YC and LC sites, respectively. The raw flux data were collected continuously at a frequency of 10 Hz using a Campbell Scientific data logger (Model CR5000, Scientific Inc.). Average values were calculated and recorded every 30 min.
The micrometeorological measurement system consisted of a net radiometer (Model CNR-1, Kipp and Zonen, The Netherlands), a quantum sensor (LI190SB, Li-Cor Inc.), a temperature/humidity probe (Model HMP45C, Vaisala Inc., Helsinki, Finland), and an anemometer (Model AR-100, Vector Instruments), which measured net radiation, PPFD, Ta and relative humidity, and wind speed and direction, respectively. Other sensors measured SWC (Model CS615-L, Campbell Scientific), Ts (TCAV, Campbell Scientific), and rainfall (Model 52203, RM Young Inc., Traverse City, MI, USA). All the data were recorded using data loggers (Model CR23XTD, Campbell Scientific) and the data were collected every half hour36.
Data processing
The half-hourly NEE (μmol CO2 m−2 s−1) of an ecosystem can be calculated from the covariance between the vertical wind velocity fluctuation (w, m s−1) and the CO2 density fluctuation (ρc, μmol CO2 m−3) using the following equation:
where the primes denote the turbulent fluctuations (departures from the mean) and the overbar indicates the time-averaged mean (30 min). Several procedures were performed to correct the 30 min mean output data before calculating the NEE: (1) a tilt correction for the error caused by non-parallel fixation was necessary to satisfy the requirements of the eddy covariance technology53; (2) the eddy covariance system cannot completely capture the true turbulence when a certain number of high and low frequencies occur, which results in the loss of information compared to ideal conditions. Several situations can result in missing raw flux data, such as an inadequate sensor frequency response, separation of the instruments (particularly the sonic anemometer and the infrared gas analyzer), line averaging, and distributed sampling54. Therefore, aspectral correction was required to compensate for the missing raw covariance data; and (3) the Webb-Pearman-Leuning (WPL) correction was applied to correct the error caused by the transfer of heat and water vapor55.
After calculating the NEE, a flux data filtering process was needed to reduce uncertainties in the subsequent analyses. In this study, the apparently abnormal flux data (│NEE│ >4.0 mgCO2 m−2 s−1) and flux data collected under precipitation and extremely cloudy conditions were removed. After data filtering, 86% and 76% of the daytime flux data were retained for the YC and LC sites, respectively. In the NEE response to light analysis, only daytime NEE was used to describe the NEE responses to PPFD changes on an annual scale.
The ecosystem light response parameters were estimated by the Michaelis-Menten rectangular hyperbola6:
where α is the initial slope of the ecosystem light-response curve, i.e. the apparent quantum yield or the apparent light-use efficiency (mgCO2 μmol photon−1), Amax is the maximum rate of ecosystem gross photosynthesis (GPP, mgCO2 m−2 s−1) at the infinite PPFD, (μmol photon m−2 s−1), and Rd (mgCO2 m−2 s−1) is the daytime ecosystem respiration. The determination coefficient (R2) and the confidence level (p) of the relationship between carbon flux and PPFD were also calculated.
The light response curves and the annual values for the light response parameters were fitted by the collective averages for PPFD and the incident NEE within a 100 PPFD interval using the valid daytime data (unfilled) for the main winter wheat and summer maize growing seasons. When the collective value was calculated, the value was not considered to be valid and was not fitted if the number of raw data was less than 10 per interval. In this study, due to the slight fluctuations in sowing and harvest dates for the two crops among the years, we defined the period from late March to May for winter wheat and the period from July to September for summer maize as the two main growing seasons at both sites. Other periods during the year were considered to be part of the non-main growing season and were not included when the light response curves were fitted because the carbon fluxes were close to zero from the sowing stage in October to the reviving stage during mid-March of the next year. This is due to the extremely slow growth of winter wheat. The carbon flux in June was also close to zero because it was the winter wheat harvest period and the summer maize germination stage. This study considered the winter wheat and summer maize crops as a whole ecosystem and did not analyze the differences between the two crops.
gc was calculated using the Penman-Monteith equation56:
where ρ (kg m−3) is air density, cp (J kg−1 K−1) is the specific heat of the air, s (kPa K−1) is the change of saturation vapor pressure with temperature, γ (kPa °C−1) is the psychrometric constant, β is the Bowen ration (H/LE), VPD (kPa) is the vapor pressure deficit of air and ga (m s−1) is the aerodynamic conductance of the air layer between the canopy and the flux measurement height. The ga was calculated using:
where u (m−1) is wind speed and u* (m s−1) is the friction velocity56.
The processes used to analyze the raw flux data, fit the curves, and calculate the light response parameters were performed by MATLAB 7.4 (Mathworks Inc.).
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Acknowledgements
This study was funded by National Natural Science Foundation of China (31260310) and Science and Technology Reserve Project of Inner Mongolia Autonomous Region (2018MDCB02).
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Conceived and designed by X.B., Z.L. Performed by X.B., Z.L. and F.X. Analyzed data by X.B. Wrote paper by X.B., Z.L.
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Bao, X., Li, Z. & Xie, F. Environmental influences on light response parameters of net carbon exchange in two rotation croplands on the North China Plain. Sci Rep 9, 18702 (2019). https://doi.org/10.1038/s41598-019-55340-2
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DOI: https://doi.org/10.1038/s41598-019-55340-2
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