The study site (N51°7′21.9, W3°44′52.9) (Fig. ) was selected as characteristic of the drained peatland areas currently being restored (Grand‐Clement et al. ) in Exmoor National Park, southwest England. It lies between 380 and 445 m above sea level, is dominated by the grass Molinia caerulea and classified as M25: Molinia caerulea – Potentilla erecta mire (Rodwell ). Long‐term (1910–2012) average annual rainfall totals 1221 mm with daily mean air temperature ranging from 4.4 to 15.4°C (Fig.  (UK Meteorological Office )).

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Location of study site within the UK and Exmoor National Park (A). Location of time‐lapse camera (star), CO2 flux monitoring locations (cross) and extent of the 250, 500 and 1000 m MODIS pixels (B). Long‐term (1910‐2012) monthly mean total precipitation (mm) and daily temperature (°C). (C) (UK Meteorological Office 2012) 1:25 000 Ordnance Survey Map (Ordnance Survey ).

A battery powered Brinno TLC100 (Brinno Design, CA) time‐lapse camera was installed at 0.95 m above the ground‐facing magnetic north at an angle of 5° from the horizontal to maximize reflected back‐scatter. The field of view was approximately 49.5° facing towards the centre of an experimental catchment with a uniform vegetation cover dominated by Molinea caerulea (Grand‐Clement et al. ; Gatis et al. ; Luscombe et al. ,b, ). A daily true‐colour image was taken at solar noon (13:00 British Summer Time) to minimize the angular effect of the canopy's bidirectional reflectance function (Ahrends et al. ). Between 23‐Apr‐2013 (DOY 113) and 29‐Oct‐2013 (DOY 302), 190 images were collected. The camera records 256 possible brightness values (0–255) for three broad bands (red, green and blue) using an 8‐bit charge‐coupled device.

A region of interest (ROI) was selected (Fig. ) where the distribution of species was known to be spatially uniform with a dominant cover of Molinia caerulea tussocks. The ROI aimed to maximize spatial sampling of the foreground canopy without giving undue weighting to the closest vegetation. Background vegetation was excluded as it was more likely to have different light conditions, contain a mix of species and be increasingly affected by atmospheric moisture content. The exact areal coverage of the ROI is not known, and is difficult to measure precisely given the orientation of the camera lens coupled with landscape and topographic distortion. However, assuming that the area covered is a rhombus, with the horizontal axes in the foreground being 2 m in length, and at distance, 6 m in length, with an extent of 4 m, we have estimated that the size of this ROI is around 16 m² in area. The red and green digital numbers were extracted and averaged across the ROI using MATLAB (R2011b The Mathworks Inc, Natick, Massachusetts). From this the green‐red vegetation index (camera‐GRVI) (Tucker ) was calculated (eq ).

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Image taken on DOY 201 (20/07/2012) showing the Region of Interest (ROI) (black rectangle) within the landscape. Given topographic and lens distortions, the areal coverage of the ROI is not known precisely but we estimate it to be 16 m2 given field knowledge of the scale of objects within this system.

[Image Omitted. See PDF]where G_DN and R_DN are green and red brightness values, respectively. Chromatic coordinates and green excess index showed greater sensitivity to illumination conditions in initial trials. As blue light has greater day‐to‐day variation dependent on the quality of incident radiation (Richardson et al. ) an index insensitive to blue was selected.

Rain, condensation on the lens and uneven illumination adversely affected image quality. A paired t‐test was carried out to test the effect of condensation on GRVI. To remove noise, a third‐order Fourier adjustment was fitted to the data, points outside the 95% confidence interval were excluded and replaced by interpolation. A third‐order Fourier adjustment was chosen above Gaussian (Jonsson and Eklundh ) or logistic (Zhang et al. ) growth models as camera‐GRVI showed a distinct secondary maxima possibly reflecting a decrease in the red band as purple flowers senesced. An 8‐day moving average was calculated, selected to match the frequency of MODIS data (Supplementary information (SI) section 2 evidences these data processing steps). It was assumed that the effect of seasonal variation in solar altitude (Ahrends et al. ) was negligible.

Terra Earth Orbiting System's Moderate‐resolution Imaging Spectroradiometer (MODIS) data were selected as they are freely available and a good compromise between spatial and temporal resolution. Tile h17v3 of MOD09A1 (land surface reflectance), MOD13Q1 (vegetation indices), MOD15A2 (LAI/fPAR) and MOD17A2 (Gross Primary Productivity (GPP8)) products were downloaded (USGS Earth Explorer, http://earthexplorer.usgs.gov) for the period 11‐Mar‐2013 to 24‐Oct‐2013. Spatial and temporal resolution details for the datasets are given in Table .

Vegetation products at this site with coarser spatial resolution (1000 m) contain mixed land cover content, encompassing both Molinia caerulea‐dominated peatland (the target area imaged by the field camera) and areas of improved acidic grassland pasture (Fig.  shows the coarse pixel containing both peatland and rough pasture).

MODIS products selected were either estimated from Earth surface reflectance values (Vermote et al. ) or derived from these values using an observation operator such as radiative transfer model (Knyazikhin et al. ; Running et al. ). Radiometrically calibrated data were corrected by NASA for the effects of scattering and absorption by atmospheric gases and aerosols, contamination by thin cirrus clouds and bidirectional reflectance distribution function (Vermote and Vermeulen ).

NASA assesses data quality based on cloud cover, observation geometry (solar and satellite zenith angles) and the radiographic testing method was used. MOD9A1 is the best quality observation within the 8‐day period. MOD13Q1 is the maximum Normalized Difference Vegetation Index (referred to as NDVI16) and the Enhanced Vegetation Index (EVI16) value within a 16‐day period. The acquisition date (MOD9A1 and MOD13Q1), first day of the interval (MOD15A2 and MOD17A2) and data quality data were extracted. Band 1 (near infrared) and Band 2 (red) from MOD9A1 were used to calculate NDVI8, where NDVI8 = (Band 1–Band 2)/(Band 1 + Band 2). GRVI8 (Eq. ) was also calculated from MOD9A1 data allowing a comparison with camera‐GRVI, although one uses physically meaningless digital numbers (dependent on the camera sensor), the other (MODIS) uses surface reflectance; a physical property of the vegetation denoting the ratio of radiance out to irradiance

NDVI has widely been used to track spring green‐up (e.g. Zhang et al. ) as it is known to relate to Leaf Area Index (LAI) and total biomass. EVI was developed to overcome problems associated with NDVI such as saturation at high LAI and sensitivity to variation in background canopy/soil and atmospheric conditions. Both vegetation products have been included in the analysis as NDVI was found by others to be better at predicting the timing of onset of greenness and maturity in deciduous forest (Ahl et al. ), but worse than EVI at predicting GPP8 in a northern peatland (Schubert et al. ).

Two further 8‐day Earth observation products, Leaf Area Index (LAI8) and fraction of absorbed Photosynthetically Active Radiation (fPAR8) were also used in the analysis. LAI is the one‐sided green leaf area per unit ground area in broadleaf canopies, whereas fPAR is the fraction of photosynthetically active radiation (400–700 nm) absorbed by green vegetation. The MODIS fPAR8 and LAI8 product is an 8‐day composite dataset with 500‐m pixel size. The algorithm chooses the “best” pixel available from all the acquisitions of the Terra sensor from within the 8‐day period (Myneni et al. ). These are known to vary seasonally in Molinia‐dominated ecosystems (Nieveen and Jacobs ) and are important variables in estimating primary productivity (e.g. Street et al. ). LAI8 and fPAR8 (MOD15A2) products are reverse modelled from reflectance values using a biome classification (Knyazikhin et al. ), good quality data are then averaged over an 8‐day period. The biome assigned was annual grassland, which although not appropriate for most peatlands was suitable for this Molinia caerulea‐dominated peatland.

MOD17A2 GPP8 is an 8‐day cumulative composite of values calculated using a radiation efficiency use model based on fPAR, LAI, minimum air temperature and vapour pressure deficit (Running et al. ). The satellite‐derived GPP8 measure has shown potential for monitoring CO₂ fluxes (both GPP and NEE) in northern peatlands (Schubert et al. ; Kross et al. ).

As blanket peatlands typically form in wet areas (>1000 mm per year) (Lindsay et al. ) the probability of cloud cover is high. Therefore, a processing method where questionable data are not immediately omitted, but rather excluded based on an objective assessment against good quality data is required to minimize data loss. Poor quality data (cloudy, high aerosol concentrations or poor geometry) were given a weighting of zero and all other data a weighting of one. To minimize variation due to atmospheric conditions, illumination and observation geometry, a smoothing filter was applied. Logistic functions (Zhang et al. ; Fisher et al. ; Richardson et al. ), high‐order polynomials (Cook et al. ), asymmetrical Gaussian functions (Jonsson and Eklundh ) and second‐ and third‐order Fourier (Fontana et al. ) functions were tested. Third‐order Fourier series were found to be the best fit (similar to camera‐GRVI) as they allowed for the multiple senescence periods observed but did not assume that all data were exact and temporally accurate. Points outside the 99% confidence interval were excluded similar to camera‐GRVI but not infilled due to their lower temporal resolution. All remaining points (those inside the 99% confidence interval) were then weighted equally, regardless of quality flag, and a Fourier third‐order series fitted. A continuous time series was derived for the MODIS vegetation products (8‐ and 16‐day) using a Fourier third‐order series rather than a moving average, as for the camera‐GRVI (daily), due to the lower temporal resolution.

The rate of CO₂ accumulation in a closed chamber (55 × 55 cm) over 2 min was measured monthly between May and September (EGM‐4 infrared gas analyser; PP Systems, Hitchin, UK), at 100, 60, 40, 10 and 0 % light levels (following Shaver et al. ) concurrent with photosynthetic active radiation (PAR) inside the chamber (PAR Quantum, Skye Instruments, Llandrindod Wells, UK). Measurements were taken at 18 Molinia caerulea‐dominated locations within 500 m of the camera location (Fig. ). Net ecosystem exchange (NEE) measurements from all locations were used to derive parameters (P_max, K and R_Eco) for a hyperbolic light response curve (Eq. ) for each sample campaign (monthly). Using these parameters gross primary productivity (GPP) at a PAR of 600 μmol Photons m⁻² sec⁻¹ (equivalent to a clear, sunny day) was estimated (eq. ) for each sample campaign, giving five mean GPP values from 18 replicates across the peatland over the growing season.[Image Omitted. See PDF]where NEE is the net ecosystem exchange (μgC m⁻² sec⁻¹), R_eco the ecosystem respiration (μgC m^‐2 sec^‐1), GPP is the gross primary productivity at 600 μmol Photons m⁻² sec⁻¹ (μgC m⁻² sec⁻¹), P_max the light saturated photosynthetic rate (μgC m⁻² sec⁻¹), k the half‐saturation constant of photosynthesis (μmol Photons m^‐2 sec⁻¹) and PAR the photosynthetic active radiation (μmol Photons m^‐2 sec⁻¹). See Gatis () and Gatis et al. () for more details. This enabled the relationship between mean GPP values and MODIS vegetation products for the mean GPP date to be assessed. A more detailed explanation of the NEE measurement and GPP modelling approach is given in the Supplementary Information (SI) section 1.

Four phenological metrics were identified to enable an objective and quantifiable comparison of the timing of seasonal vegetation change; start, peak and end of growth and season length. Several methods have been proposed to identify the start and end of growth; the slope method selects the steepest part of the curve (e.g. Ahrends et al. ), the half‐maximum selects the value half‐way between minimum and maximum values (e.g. Coops et al. ), other threshold methods use site‐specific percentages on a cumulative frequency curve (e.g. Fontana et al. ), with noisy or complex data, visual inspection has been used (Ide and Oguma ). The slope method is considered more ecologically meaningful (Zhang et al. ) as it does not use arbitrary thresholds and is independent of the amplitude of maximum and minimum values. However, in a direct comparison the half‐maximum method was found to more accurately capture traditionally observed phenological events than the slope method (Studer et al. ).

The start and end of growth were identified as the DOY when the value first reached half the maximum value, each limb calculated separately. Peak was the DOY when maximum value occurred. The season length is the number of days between the start and end of growth. The average number of days difference between the three phenological metrics (start, peak and end of growth) estimated by camera‐GRVI and the MODIS vegetation products were calculated (Days Out).

When GRVI goes from negative winter values to positive summer values (i.e. GRVI = 0) offers another possible metric of phenology (from here on referred to as the zero‐threshold method (Motohka et al. )), independent of maximum and minimum values, enabling dates estimated by these two methods to be compared.

To test for correlations between camera‐GRVI and MODIS‐derived vegetation products, a Pearson's test was applied to data from DOY 116–302. Two‐tailed Pearson's tests were also carried out to test for correlations between vegetation products and GPP. A two‐tailed approach was followed for testing the significance of the Pearson correlation coefficient.

Gross Primary Productivity (GPP) calculated using model parameters derived from closed chamber NEE measurements increased at the same time as all vegetation products increased indicating greater CO₂ uptake (Fig. ). The highest modelled GPP value was measured only 4 days before peak growth as determined by camera‐GRVI. (Fig. I). All vegetation products showed strong correlations (r > 0.75) but only MODIS‐GRVI and camera‐GRVI significantly correlated with modelled GPP (Fig. A and H). NDVI8, NDVI16 and EVI16 did not significantly correlate with modelled GPP (high P ‐values) as they remained high and relatively constant despite a large range in modelled GPP (Fig. ). Vegetation indices which best captured the minima around DOY 234 (camera and MODIS‐GRVI) showed the strongest correlation with modelled GPP (Figs  and ). Modelled GPP was significantly underestimated by MODIS‐GPP8; −41 to −84 μgC m^‐2 sec⁻¹ compared to −11 to −304 μgC m⁻² sec⁻¹ measured.

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Relationship between time‐matched mean Gross Primary Productivity (GPP) at 600 μmol Photons m−2 sec−1 (μgC m‐2 sec−1) (collected monthly n = 18) and digital camera Green‐Red Vegetation Index (A), MODIS‐derived Vegetation Products (B–H) and day of year (I). Linear correlations shown solid where P < 0.050 and dashed where P < 0.099. Error bars show 95% confidence intervals.

Vegetation products of 1000‐m spatial extent (LAI8, GPP8 and fPAR8) predicted start of growth earlier than camera‐GRVI and were the best predictors of peak (fPAR8) and end of growth (LAI8 and GPP8). This is most likely as the coarser‐grained vegetation products contain a mix Molinia caerulea‐dominated peatland and areas of improved acidic grassland pasture (Fig. ) and will therefore reflect the phenology of both land cover types. Start of growth may therefore be measured earlier in the 1000‐m vegetation products as pasture species sprout earlier than M. caerulea which dominates the peatland (Proffitt ). However, many species typical of upland pastures (e.g. Common Bent grass (Agrostis capillaris), Sheep's Fescue (Festuca ovina), Sweet Vernal Grass (Anthoxanthum odoratum) and Wavy Hair Grass (Deschampsia flexuosa)) are also present within the Molinia caerulea‐dominated peatland, albeit the species dominance is different in the pasture sward compared to the peatland. The good day‐to‐day correlations and the ability of these 1000‐m vegetation products to accurately depict peak and end of growth suggests that once growth had been initiated, the pasture and peatland vegetation responded similar to environmental conditions.

Comparing data across scales (field to landscape) introduces additional uncertainty (Morisette et al. ). As discussed above, the greater spatial extent of the MODIS data resulted in mixed pixels measuring the seasonality of a vegetation community rather than a single species. Given it is not feasible to ground validate at a scale equivalent to MODIS pixel size, the photographic method provides a larger footprint than traditional manual techniques and is seen by many as a “bridge” to assist scaling across data products (Coops et al. ; Hufkens et al. ; Klosterman et al. ). This study aimed to test whether useful correlations exist between these data sources despite their inherent uncertainties and an order of magnitude difference in the spatial extent being sampled.

This study tested both MODIS vegetation products with an acquisition date (NDVI8, GRVI8, NDVI16 and EVI16) and composite vegetation products averaged over an 8‐day interval arbitrarily assigned to the first day of the interval (LAI8, fPAR8 and GPP8). Using the first date of the interval rather than acquisition date for 16‐day NDVI has been shown to bias the resultant time series, reducing the accuracy of start of growth estimation (Testa et al. ). GPP8, LAI8 and fPAR8 estimated start of growth earlier than camera‐GRVI (Table ) indicating a potential bias in spring, possibly due to using the first date in the interval. However, these vegetation products both over‐ and underestimated peak and end of growth suggesting the parameters used to derive each vegetation product (e.g. leaf structure, chlorophyll content) are more influential than the choice of date assigned.

For ecosystems where green‐up occurs rapidly, such as temperate woodlands (bud burst to canopy maturity in 10–12 days (Ahl et al. )), a higher temporal resolution vegetation product (NDVI8) has been found to better predict start of growth as at least one data point lies within the greening‐up period. If there are no data within the period of rapid change, for example, due to cloud cover, the accuracy of start of growth estimated dramatically decreased (Zhang et al. ). The deciduous grasses of Exmoor took around 75 days to go from small shoots to maximum green leaf extent (Fig. ), comparable to the 40–60 days to maximum leaf height observed for alpine grasslands (Migliavacca et al. ). Therefore, neither 8‐day nor 16‐day MODIS data are likely to “miss” green‐up in these ecosystems where the green‐up periods are longer. NDVI16 (250‐m spatial resolution) estimated start of growth 2 days later than the half‐maximum method suggesting spatial resolution is more important than temporal resolution for accurately predicting start of growth in these fragmented grassland ecosystems.

Vegetation products with 8‐day temporal resolution (GPP8, fPAR8 and LAI8) had the strongest day‐to‐day correlations with camera‐GRVI (Table ). Indicating to capture full‐season phenology rather than start of growth, finer temporal resolution becomes more important than spatial resolution.

Green vegetation was observed in the images from DOY 143 to 302. These dates coincide with the base of the rising and falling limbs (Fig. ) but not the estimated start and end of growth dates. These thresholds (half‐maximum and zero‐threshold) were selected to enable an objective and quantifiable comparison between vegetation products rather than for their ability to reflect more traditional phenological metrics. Both the zero‐threshold (Motohka et al. ) and half‐maximum (Fisher and Mustard ; Coops et al. ; Henneken et al. ) methods showed agreement for both start and end of growth (2 and 1 days), excluding the first crossing of the zero threshold (Fig. ) (DOY 234), indicating their robustness. However, the zero‐threshold method can have multiple values if the GRVI fluctuates around zero. In addition, the gradual green‐up and senescence in this ecosystem make the timing of start and end of growth estimated using the half‐maximum method sensitive to maximum and minimum values. It also explains why there was greater uncertainty in the estimates of end of growth, with a shallower gradient, compared to start of growth within this study (Table ). Filippa et al. () found more data were required to accurately predict autumn phenology compared to spring phenology.

The range in dates for start, peak and end of growth is progressively larger (Table ) particularly for higher‐order vegetation products such as GPP8, LAI8 and FPAR8 derived using more complex models containing parameters such as chlorophyll and carotenoid content, leaf structure and angle, vapour pressure deficit, etc., that are more variable as the growing season progresses. GPP8 showed the most asymmetry with a small autumnal increase, possibly as meteorological variables are included in the algorithm (Running et al. ). GPP8 also showed the earliest end of growth (Fig. B, Table ) reflecting a decline in chlorophyll content, whereas NDVI16, EVI16, NDVI8, fPAR8 showed a delayed but more rapid autumnal decline (Fig. D, E, F and G, Table ) as leaves, which may not have photosynthesized for a number of weeks, finally degraded. These physiological controls on vegetation properties appear to have had a greater impact on the timing of peak and end of growth than either spatial or temporal resolution (Table ).

MODIS‐GRVI8 might be expected to have the strongest correlation with camera‐GRVI as it has an 8‐day temporal resolution and uses the same wavelengths of light albeit one measures camera‐specific digital numbers the other reflectance. However, MODIS‐GRVI8 showed an autumnal increase resulting in the weakest day‐to‐day correlation possibly in part because GRVI8 uses only visible wavelengths where the noise‐to‐signal ratio is greater than in other bands such as near infrared used by NDVI8.

Studies using digital images to track phenology have typically used relative brightness of green (Richardson et al. ; Ahrends et al. ; Parihar et al. ; Alberton et al. ), greenness excess index (Ide and Oguma ; Coops et al. ; Hufkens et al. ; Saitoh et al. ) or both (Migliavacca et al. ; Mizunuma et al. ). However, these products are strongly affected by illumination conditions (Sonnentag et al. ), with the blue band showing most variability. GRVI (Tucker ) was selected for this study as it does not use the blue band and is therefore less sensitive to variation in illumination conditions. This is in keeping with Zhou et al. () who found the ratio of green to red better suited to monitor winter wheat phenology than relative brightness of green.

A key consideration when using digital camera imagery to validate MODIS vegetation products is the uncertainty in the digital camera measurement (Keenan et al. ). For example, as the elevation of the camera was limited, the viewing angle was low therefore, early green shoots were not observed within the previous year's dead biomass. As a result camera‐GRVI started to increase only once shoots protruded above the dead biomass, resulting in a late start of growth date, a similar effect was observed in European grasslands by Wingate et al. (). As another example, LAI8 showed rapid spring growth to DOY 180 (Fig. B) then continued to increase to a late peak (DOY 238) before rapid senescence, this is consistent with the expected pattern of leaf growth (Nieveen et al. ) for Molinia caerulea but in contrast to the phenology measured by camera‐GRVI. MODIS‐LAI8 uses canopy structural attributes typical of annual grasslands (e.g. no stems, no understory, etc.) in the radiative transfer model for the pixel of interest, appropriate in this deciduous grass‐dominated peatland. LAI8 continued to increase beyond maximum camera‐GRVI probably as leaf area continued to increase but the canopy had closed in the direction of the camera. Wingate et al. () found greenness to be insensitive to LAI > 1. Without ground validation it is not possible to assess if MODIS‐LAI8 accurately measured the dynamics of LAI. However, as both leaf structure and pigment influence photosynthetic activity, it is the combined affect that is of interest.

It is known that seasonal variation in physiological pigments as well as leaf area, both measurable by digital camera vegetation products, results in variation in photosynthesis (Muraoka and Koizumi ; Migliavacca et al. ; Saitoh et al. ; Mizunuma et al. ; Westergaard‐Nielsen et al. ; Zhou et al. ; Toomey et al. ). This study investigated if MODIS vegetation products could also identify this seasonal variation.

MODIS‐GPP8 significantly underestimated GPP when compared to measured values (Fig. B) possibly due to the overly strong influence of temperature and assumptions about the effect of water availability in the MODIS‐GPP8 algorithm that are incorrect in a peatland ecosystem. This agrees with direct comparisons between GPP and MODIS‐GPP8 in northern peatlands (Moore et al. ; Kross et al. ). In tropical deciduous woodland MODIS‐GPP did not track seasonal dynamics as water availability rather than phenology controlled leaf‐on GPP (Christian et al. ). Other studies have found MODIS‐GPP8 to correlate more strongly with ecosystem respiration (Schubert et al. ) as the radiation efficiency use model used to derive MODIS‐GPP8 includes air temperature.

NDVI8 and NDVI16 were non‐significantly correlated with GPP (r > 0.77, P < 0.128) (Fig. E and F). This reflects both the limited number of samples (n = 5) and aggregated short‐term variation in illumination, wetness and temperature in this study. NDVI16 explained 39–71% of the temporal variation in 8‐day averaged GPP (Kross et al. ) across four northern peatland sites, whereas NDVI16 and EVI16 explained 71% and 44% of the variation in GPP (Rossini et al. ) in alpine grasslands. It is likely correlations were lower in these studies as they compared average GPP, including cloudy periods, to MODIS data from cloud‐free days, whereas in this study best quality (e.g. fPAR8) or greatest value (e.g. NDVI8) data have been compared to date‐matched GPP for the equivalent of a clear, sunny day.

In this study, vegetation indices which best captured the minima about DOY 234, most likely reflecting a period of flowering, had the strongest correlation with GPP (Figs.  and ). Biscoe et al. () found photosynthesis from barley decreased 3 weeks before flowering demonstrating how GPP may be limited by biotic and abiotic factors which do not equally affect vegetation indices. It is not, therefore, proposed that these vegetation indices be used as a direct proxy for GPP, but rather a proxy for vegetation phenology to be used in conjunction with meteorological data to assess GPP. Where meteorological data such as PAR and/or temperature have been used in conjunction with MODIS data the explanatory power has increased markedly (Rossini et al. ). At a global scale fPAR has been found to be a key variable for spatially upscaling FLUXNET measurements influencing both seasonal and interannual variability (Jung et al., ).

The ability to model interannual CO₂ fluxes would enable NEE for a given vegetation community, and thus the potential carbon saved, to be better characterized. In addition, the spatial coverage and temporal resolution of MODIS enables measured fluxes to be spatially and temporally extrapolated making the cost of monitoring any effects due to wetland restoration more practical. The results indicate, despite a small sample size that fPAR8, GPP8 and LAI8 show good day‐to‐day agreement with camera‐GRVI (Table ) highlighting their potential to be used as phenological proxies in CO₂ models. Bearing in mind the small sample size used in this study we recommend two areas for further work. Firstly, research to determine the best MODIS proxy for vegetation phenology across a wider range of grassland ecosystems. Secondly, determining whether a CO₂ model derived for a Molinia caerulea‐dominated site, based on meteorological data and a MODIS vegetation product, is transferable to other sites thereby providing a means of upscaling CO₂ fluxes to landscape and global scales.