Introduction

During the last decade (2006–2015), the Greenland Ice Sheet (GrIS) has been rapidly losing mass, contributing on average 0.9 mm yr${}^{-\mathrm{1}}$ to global mean sea level rise . The NASA/German Space Agency (DLR) Gravity Recovery and Climate Experiment (GRACE) mission is a powerful tool with which to monitor ice mass variations in Greenland, including the ice sheet and its peripheral glaciers and ice caps, from monthly to multi-year timescales. The total mass balance (TMB) of the ice sheet represents the summation of processes summarized in Eq. (): (i) surface mass balance (SMB); (ii) ice discharge (D); and (iii) mass variations ($\mathrm{\Delta }m/\mathrm{\Delta }t$), which include all processes not related to SMB and ice discharge, for instance, en- and subglacial meltwater storage. GRACE ice mass balance is calculated after removing the impacts of glacial isostatic adjustment (GIA), atmospheric and oceanic variability, and other time-variable geophysical processes. $$\mathrm{TMB}=\mathrm{SMB}-D+\mathrm{\Delta }m/\mathrm{\Delta }t$$

The quantities in Eq. () refer to fluxes (in mass per unit time). Recent GrIS mass loss has been quantified in numerous studies e.g.,. Furthermore, several authors have estimated the contribution to this mass loss from SMB and ice discharge individually . To quantify the contribution of SMB, regional climate models (RCMs) are typically used, such as the Regional Atmospheric Climate Model v. 2 (RACMO2) , Modèle Atmosphérique Régional (MAR) , and HIRHAM . The annual ice discharge rates are estimated by combining ice flow velocity data and ice thickness data at the flux gates . Importantly, ice flow velocities have increased during the last decade and shown different spatial and temporal patterns .

The analysis of GrIS mass variations at the seasonal timescale is still limited. This is largely because (i) the accuracy and spatial resolution of GRACE monthly solutions is relatively poor, as compared to long-term trend estimates, and (ii) ice velocity data at this timescale are scarce (typically, only a few estimates per year are available, often spanning only a few years). A first attempt to combine GRACE data and SMB modeling in order to evaluate an ice dynamics model of the GrIS at the monthly timescale was made by . examined spatial patterns of GrIS seasonal mass variations using a regional climate model, a model of ice dynamics, and GRACE. The seasonal variabilities of the ice velocities of a few marine-terminating glaciers were investigated by, e.g., , , and . The only study of multi-regional seasonal variations of GrIS outlet glacier velocities was conducted by , who analyzed 55 marine-terminating glaciers in northwest and southeast Greenland over the period 2009–2013.

GrIS mass balance also depends on supra-, en-, and subglacial meltwater storage. An example is the abundance of supraglacial lakes primarily in west Greenland, which store water during the melt season . Subglacial hydrology is an area of active research see, e.g.,. However, time-varying total englacial and subglacial meltwater storage (included in $\mathrm{\Delta }m/\mathrm{\Delta }t$ of Eq. ) has been poorly quantified and mostly investigated at a local scale. For instance, quantified meltwater storage in a small watershed (36–65 km${}^{\mathrm{2}}$) near Kangerlussuaq. They suggested that $\sim \mathrm{54}$ % of liquid water is retained for 1–6 months in this watershed. To date, only one study has utilized GRACE data to quantify meltwater storage at ice-sheet-wide scales . By fitting de-trended GRACE observations and SMB model output, it was found that the mean period of meltwater storage at the whole-ice-sheet scale is $\sim \mathrm{18}$ days. So far, no attempt to quantify the meltwater storage with GRACE has been made at the drainage system scale.

In this study, we analyze the individual mass variation contributors (see Eq. ) to total interannual and seasonal mass variations over Greenland at both regional and whole-ice-sheet scales. In particular, this study makes a first ice-sheet-wide attempt to quantify the amplitude and timing of short-term meltwater storage. For this purpose, we combine observations of total mass variations from GRACE with observations of ice discharge to the ocean , as well as modeled SMB output from RACMO2.3 , SNOWPACK , and MAR3.9 . Since the spatial resolution of GRACE data is limited, the obtained estimates cover both the GrIS and the parts of Greenland outside the GrIS, including the tundra and the peripheral glaciers disconnected from the GrIS. Furthermore, there are also meltwater storage estimates of the Greenland Ice Sheet using in situ core data e.g.,. Usually, the authors collected the data during a short period, to characterize the state of the firn in a transect, in order to understand the capacity of the firn to store meltwater. These findings are then applied to the whole ice sheet based on a firn model. The meltwater storage estimated by those studies is significant, e.g., at the level of a few hundred or even thousand gigatonnes. Those studies, however, are quite different from this study. Those studies estimated the total meltwater storage in the firn, whereas our study addresses the water storage (i) in all components (supra-, en-, and subglacial) and (ii) at the short timescale.

In Sect. 2, we discuss the methods and data utilized. The results are presented and analyzed in Sect. 3. Finally, the conclusions are presented in Sect. 4.

Data and methods

The 28-mascon parameterization of Greenland used in this study for GRACE data processing. For the purpose of further analysis, these patches are merged into five drainage systems (N, NE, SE, SW, and NW). Nine mascons (filled in blue) outside Greenland are added to absorb signals from the surrounding areas. Fifty-five glaciers utilized to compute seasonal ice discharge variations are marked in red.

[Figure omitted. See PDF]

GRACE

We use the fifth release of GRACE monthly gravity field solutions from the Center for Space Research (CSR) at the University of Texas as input to compute total mass variations. Each solution is provided as a set of spherical harmonic coefficients up to degree/order 96 and supplied with a full error covariance matrix. For the sake of consistency with previous GRACE-based estimates, we limit the considered time interval to January 2003–December 2013. Since data for 9 months are missing, 123 months in total are used. Furthermore, a reduced time interval (January 2003–December 2012) is also considered in order to make the obtained estimates consistent with ice discharge data from ; see Sect. 2.3 for a further discussion. Due to strong noise in the $C_{\mathrm{2},\mathrm{0}}$ coefficients, we replaced them with available estimates based on satellite laser ranging . The degree-one coefficients, which are not included in the GRACE products, are taken from . The GRACE solutions are corrected for GIA, which is triggered by a relief of ice load since the Last Glacial Maximum, with the model from .

To estimate mass variations over Greenland at a regional scale, we make use of a novel data processing methodology , which is based on the mascon approach. Greenland is split into 28 patches, or “mascons” (Fig. ), which are complemented by nine patches outside Greenland to absorb signals from the surrounding areas. Temporal variations (anomalies) of surface density (i.e., mass variations per unit area) within each patch are assumed to be spatially homogeneous. Thus, the total mass anomaly within each patch is just a product of surface density anomaly and patch area. Those mass anomalies are computed for each month independently, without any regularization. Ultimately, mass anomalies are summed up over individual drainage systems or the entirety of Greenland.

A further description of the adopted GRACE data processing methodology is provided in the Appendix A. In order to investigate the robustness of GRACE-based mass anomalies, we estimate them using different processing parameters. This leads to multiple sets of GRACE solutions: two primary ones (estimated with and without applying data weighting) and alternative ones. We also consider the estimates produced by other research teams: the Jet Propulsion Laboratory (JPL) mascon solutions by , the CSR mascon solutions by , the Goddard Space Flight Center (GSFC) mascon solutions by , and the solutions by .

Similar to , we aggregate the 28 mascons inside Greenland into five drainage systems. We refer to these drainage systems as (a) north (N), (b) northwest (NW), (c) southeast (SE), (d) southwest (SW), and (e) northeast (NE) (Fig. ). We slightly shifted southwards the border between NW and SW drainage systems as compared to , in order to ensure that the SW drainage system is mostly limited to land-terminating glaciers.

SMB modeling

SMB values over 2003–2013 from three models (i.e., RACMO2.3, SNOWPACK, and MAR3.9) are analyzed. The SMB estimates are obtained as the sum of individual SMB components: $$\mathrm{SMB}=P_{\mathrm{tot}}-{\mathrm{SU}}_{\mathrm{tot}}-{\mathrm{ER}}_{\mathrm{ds}}-\mathrm{RU},$$ where ${\mathrm{P}}_{\mathrm{tot}}$ and ${\mathrm{SU}}_{\mathrm{tot}}$ are the total precipitation and sublimation, respectively; ${\mathrm{ER}}_{\mathrm{ds}}$ is erosion/deposition due to drifting snow; and RU is runoff. The units are mass per unit time. The SMB mass anomalies used in this study are from RACMO2.3 unless stated otherwise. The output from SNOWPACK is included to evaluate the robustness of our findings with respect to the choice of SMB outputs simulated by different snow/firn models. Output of another regional climate model, MAR3.9, is also investigated in this study to demonstrate the robustness of the results, considering the large discrepancies among SMB outputs from different regional climate models in the past .

Time series of mass anomalies over the period 2003–2013 for the entire GrIS: total mass anomalies from GRACE produced with and without data weighting (solid blue and dashed black, respectively), cumulative SMB anomalies from RACMO2.3 (green), the difference between them, the “total–SMB” residuals (solid red and dashed pink: with and without data weighting, respectively), and cumulative ice discharge (cyan).

[Figure omitted. See PDF]

RACMO2.3

RACMO2.3 was developed by the Royal Netherlands Meteorological Institute (KNMI) and Institute for Marine and Atmospheric Research (IMAU), which is a part of Utrecht University in the Netherlands . RACMO2.3 provides daily SMB values with a spatial resolution of 11 km.

SNOWPACK

In addition to the daily SMB provided by RACMO2.3, we use SMB output from SNOWPACK . SNOWPACK is a state-of-the-art snow model that offers a more physically based snow densification scheme, the simulation of microstructural snow properties, and a higher near-surface vertical resolution compared with the snow/firn module of RACMO2.3. A comparison of SNOWPACK with IMAU-FDM, a snow/firn model nearly identical to the one implemented in RACMO2.3, revealed a better performance of SNOWPACK for the GrIS, particularly for locations with comparably high amounts of liquid water input due to snowmelt and rainfall . SNOWPACK was coupled offline to RACMO2.3 and run for the full period 1960–2014 with the same surface mask (ocean, tundra, ice sheet) and horizontal resolution as RACMO2.3. As a consequence of forcing SNOWPACK with mass fluxes from RACMO2.3 at the snow–atmosphere interface, differences in the simulated SMB from SNOWPACK and RACMO2.3 are thus only caused by unequal partitioning of meltwater and rainfall into refreezing and runoff.

MAR3.9

The MAR3.9 model was developed by the Laboratory of Climatology at the Department of Geography, University of Liège . It provides daily SMB values for both the ice sheet and tundra areas with a spatial resolution of 5 km and uses ERA-Interim as forcing like RACMO2.3. The only differences between the version 3.8 of MAR used in and the version 3.9 used here are improvements in the MAR stability when it is applied at high resolution as well as in its computational efficiency.

Processing the SMB outputs from RACMO2.3, SNOWPACK, and MAR3.9

In this study, we integrate SMB outputs from RACMO2.3, SNOWPACK, or MAR3.9 in time, which results in cumulative values that can be interpreted as daily SMB mass anomalies. These values are averaged over monthly intervals for the sake of temporal consistency with the GRACE solutions. In order to make the SMB outputs (11 km resolution for RACMO2.3 and SNOWPACK, or 5 km in the case of MAR3.9) spatially match the GRACE resolution (around 300 km), we process them consistently with the GRACE data. This scheme is similar to the GRACE-like processing of SMB data by and . More specifically, we convert the SMB outputs to gravity disturbances at the satellite altitude and limit their spectra to spherical harmonic degree/order 96. Then the SMB per mascon is estimated by a least-squares adjustment (see the Appendix A).

Greenland mean annual cycle of total mass anomalies from GRACE produced with data weighting (dark-blue), cumulative SMB anomalies (green), and the difference between them (brown) for the period 2003–2013. The latter curve reflects the cumulative sum of seasonal ice discharge variations and meltwater storage, as well as GRACE errors and SMB model bias. The shaded strips show the 1$\mathit{\sigma }$ error bars. Labels at the horizontal axis indicate month of the year (e.g., month “J” denotes January, while month “D” is December).

[Figure omitted. See PDF]

Previous studies on the sources of current GrIS mass loss used relative SMB outputs, i.e., anomalies with respect to an equilibrium state (1961–1990) . Effectively, this means that the time series of mass anomalies were de-trended to ensure that they are close to zero during the reference equilibrium period. In other words, it assumes that the ice discharge and SMB were balanced during the reference period. In contrast, we use time series of absolute SMB mass anomalies, i.e., without referring to a hypothesized equilibrium state. In this way, we are able to extract more information from the data sets: absolute mass anomalies related to ice discharge (i.e., the difference between GRACE- and SMB-based mass anomalies) cannot increase over time, which is a valuable constraint that facilitates the correct interpretation of the obtained results.

Ice discharge

We examine ice discharge from two different data sets. The first set was presented in . Here, it is used to reconstruct the 2003–2012 multi-year mass trends and accelerations, as well as to separate the contributions from SMB and ice discharge. It covers 178 outlet glaciers with annual resolution. Ice discharge observations of these glaciers are estimated by multiplying ice flow velocities with ice thickness values. Annual velocities are retrieved by means of feature tracking from (winter) Landsat 7 Enhanced Thematic Mapper Plus and the Advanced Spaceborne Thermal and Reflectance Radiometer (ASTER) data. Ice discharge is calculated within 5 km of the grounding lines. The ice thicknesses at the flux gates are computed by subtracting bed elevations from surface elevations. Bed elevations are derived from NASA's Operation IceBridge airborne ice-penetrating radar data, whereas surface elevations are obtained from digital elevation models .

In addition, we produce the second data set, which is used to examine monthly variations of ice discharge. It covers 55 marine-terminating glaciers with sub-annual resolution for 2009–2013. The exploited ice flow velocities were obtained from TerraSAR-X images delivered by DLR . Ice thicknesses at the flux gates are interpolated from the IceBridge BedMachine Greenland version 2 data . Ice discharge ($D$) for a given glacier is defined as the ice mass flux across the flux gate ($f$) close to the glacier terminus (within $\sim \mathrm{5}$ km): $$D=\mathit{\rho }\int h(\mathit{\upsilon }\cdot \mathit{n})\mathrm{d}f,$$ where $h$ is the ice thickness, $\mathit{n}$ is the unit vector directed outwards normally to the flux gate, $\mathit{\upsilon }$ is the ice flow velocity, and $\mathit{\rho }$ is the ice density. When selecting flux gates, we pay attention to variations of the terminus position by checking the images of glaciers during the whole time interval, to make sure that the flux gate is upstream of the terminus all the time. Furthermore, a flux gate should span the whole outlet glacier to the ice flow edges. To compute $D$, we discretize the flux gates into nearly 200 m long intervals. The length of the last interval is adjusted to make sure that the ice flow edge is sampled. We then use the values ($h$, $\mathit{\upsilon }$, and $\mathit{n}$) defined for the center of each interval, assuming that they are constant over the interval. Then Eq. () becomes $$D=\mathit{\rho }\sum _{i=\mathrm{1}}^N{d}^i{h}^i({\mathit{\upsilon }}^{\mathit{i}}\cdot \mathit{n}),$$ where $N$ is the total number of intervals of the flux gate and $d^i$ is the length of the $i$th interval.

Results and discussion

Multi-year mass trend and acceleration budgets

First, we examine multi-year mass trends and accelerations in terms of the total mass balance and the contributions thereto from SMB and ice discharge. For more details about the estimation of multi-year trend and accelerations, please refer to Appendix B.

Our estimate of the total-mass linear trend, which is based on the primary GRACE data time series produced with optimal data weighting, is $-\mathrm{286}\pm \mathrm{21}$ Gt yr${}^{-\mathrm{1}}$ for 2003–2013. The estimate obtained without data weighting is $-\mathrm{279}\pm \mathrm{21}$ Gt yr${}^{-\mathrm{1}}$. The individual contributors to the errors in the trend estimates are shown in Table . Our estimates are in agreement with those published earlier for the time interval 2003–2013: $-\mathrm{280}\pm \mathrm{58}$ Gt yr${}^{-\mathrm{1}}$ and $-\mathrm{278}\pm \mathrm{19}$ Gt yr${}^{-\mathrm{1}}$ .

Similar to Fig. , but only for mean annual cycle of cumulative SMB anomalies of different drainage systems (SE: black; NW: green; NE: blue; N: red; SW: pink). The SMB outputs are computed in three different ways: (i) consistently with GRACE data (with or without data weighting) and (ii) by a direct estimation of mass anomalies per drainage system.

[Figure omitted. See PDF]

We also examine the SMB and ice discharge contributions to the total mass trend. In this case, we consider the reduced time interval, 2003–2012, in order to be consistent with the ice discharge record, which ends in 2012 (Table ). The multi-year average mass gains from SMB (RACMO2.3) over that period processed consistently with GRACE via data weighting and without data weighting are $\mathrm{216}\pm \mathrm{122}$ and $\mathrm{214}\pm \mathrm{122}$ Gt yr${}^{-\mathrm{1}}$, respectively. The uncertainty is computed by assuming a 9 % error in accumulation and a 15 % error in meltwater runoff signals modeled by RACMO2.3, which is the typical uncertainty of RACMO2.3 . The time series of cumulative mass anomalies due to ice discharge and other processes not related to SMB is obtained as the difference between the total mass variations and the cumulative SMB-related ones; this difference will be referred to as the “total–SMB” residuals (“total minus SMB”; cf. red and pink curves in Fig. ). The associated rates of linear changes over 2003–2012 estimated with and without data weighting are $\mathrm{493}\pm \mathrm{124}$ and $\mathrm{483}\pm \mathrm{124}$ Gt yr${}^{-\mathrm{1}}$, respectively. Those estimates agree with the ice discharge estimate from , $\mathrm{520}\pm \mathrm{31}$ Gt yr${}^{-\mathrm{1}}$, shown as the cyan curve in Fig. , which is shifted to best fit the GRACE-SMB time series. Notice that the GRACE time series obtained with the optimal weighting shows a smoother behavior than that produced without data weighting. This is consistent with the analysis presented in , who found that data weighting substantially reduces the level of random noise in the GRACE GrIS mass change time series.

Mean monthly meltwater production per calendar month (gigatonnes) for the entirety of Greenland (a), for individual drainage systems in gigatonnes (b), and for individual drainage systems in meters of equivalent water height (c) modeled by RACMO2.3.

[Figure omitted. See PDF]

Next, we present the results of a similar analysis for the individual drainage systems. The greatest total mass losses are observed by GRACE in drainage systems NW and SE (cf. Fig.  and Table ). These two drainage systems account for $\sim \mathrm{73}$–76 % of the total mass loss over Greenland, depending on whether data weighting is applied or not. The interannual behavior of these drainage systems is, however, different. SE loses mass with an approximately constant rate over the whole considered period. In contrast, NW is relatively stable over the period 2003–2005, but starts losing mass thereafter. The remaining three drainage systems lose mass at much smaller rates. Remarkably, two of these drainage systems (N and SW) show a similar behavior: they are relatively stable over the period 2003–2009 but start losing mass in 2010. These findings are consistent with . The SMB is negative in two drainage systems (N and SW) (cf. Table ). However, with a large fraction of land-terminating glaciers, ice losses from ice discharge are an order of magnitude lower there than in the NW and SE drainage systems (cf. Fig. ), resulting in only modest total mass loss in spite of the negative SMB.

Estimates of seasonal meltwater storage, obtained as the monthly deviations from the April–May and September–November linear fit of “total–SMB” residuals (brown line in Fig. ): for the whole GrIS (in gigatonnes). Labels along the horizontal axis represent months between April (“A”) and November (“N”). The shaded strip shows the 1$\mathit{\sigma }$ error bar for the estimates by Delft University of Technology (TuD) with data weighting (the mean standard deviation is 23 Gt).

[Figure omitted. See PDF]

The long-term trends of total–SMB residuals in the drainage systems of NW, NE, and SW are consistent with the ice discharge estimates from within the error bar (Table ). This suggests robustness of RACMO2.3 long-term SMB trends there, under the assumption that the meltwater storage signal is mainly seasonal. In the SE and N, however, we find relatively large discrepancies between the total–SMB residuals and ice discharge observations from . Under the conditions of realistic GRACE error estimates and minimal multi-year meltwater storage, all these inconsistencies suggest a precipitation overestimation in the SE and underestimation in the N in RACMO2.3.

Monthly ice discharge estimates from 55 major marine-terminating glaciers for the glaciers in the NW drainage system (a) and the SE drainage system (b) individually, and for the NW and SE drainage systems together (c).

[Figure omitted. See PDF]

Average accelerations of mass change anomalies over the period 2003–2012 are also estimated using Eq. () (parameter $a_{\mathrm{3}}$). Over the entirety of Greenland, the SMB ($-\mathrm{23.3}\pm \mathrm{2.7}$ Gt yr${}^{-\mathrm{2}}$) contributes 75 % of the total acceleration observed by GRACE (Table ). This is close to the estimates of , who assessed the contribution of SMB to the total GrIS mass loss acceleration as 79 %. The contribution of the total–SMB residuals to the mass loss acceleration for the entirety of Greenland is statistically insignificant. Analysis of individual drainage systems leads to similar conclusions (cf. Table ). However, we note that the acceleration estimates cannot be simply extrapolated onto a longer time interval and may not properly represent the ice sheet behavior at the decadal timescale, because of the large climate variability in a limited time span of data .

Linear mass change rates over the period 2003–2012 for individual drainage systems and the entirety of Greenland: total, SMB-related, and total–SMB residuals (GRACE–SMB), as well as ice discharge (Gt yr${}^{-\mathrm{1}}$). The sign of total–SMB residuals is changed to make them directly comparable with ice discharge estimates.

Seasonal mass variations

We analyze the mean annual cycles of total (GRACE) and cumulative SMB (RACMO2.3) mass anomalies over the period 2003–2013 (Fig. ). To derive them, we divide the entire period into 11 overlapping 13-month time intervals, each of which starts in December of the previous year and ends in December of the current year. Then, the mean mass anomaly for each calendar month is estimated by linear regression, together with one bias parameter per time interval, which accounts for a long-term variability. This scheme is less sensitive to gaps in data time series than the plain averaging of mass anomalies per calendar month. For more details about this scheme, we refer the reader to . The uncertainties of mean mass anomalies from GRACE are propagated from errors in each monthly GRACE estimate. The uncertainties of cumulative SMB mean mass anomalies are computed by assuming 9 % and 15 % errors in modeled mean mass anomalies due to precipitation and runoff, respectively, as suggested by . The uncertainties of the total–SMB residuals are the mean root sum square of the standard deviations of noise in GRACE and cumulative SMB estimates.

Similar to Fig.  but for mean ice-discharge-related variations over 2009–2013. The cumulative mass anomalies are computed from glaciers in NW (a) and SE (b) drainage systems individually, and for glaciers in NW and SE together (c).

[Figure omitted. See PDF]

The whole-Greenland mean annual cycles of total and cumulative SMB mass anomalies present smooth month-to-month variations (Fig. ). Importantly, the estimates of both types refer to the mean values for the months considered. The total mass anomaly from GRACE reaches its maximum in March and then steadily decreases until September. The most rapid monthly mass loss is observed in July–August ($\sim \mathrm{200}$ Gt). In contrast, the cumulative SMB decreases over a much shorter period – only from May to August.

suggested that the inconsistency between the spatial resolution of GRACE-based estimates and that of the SMB model (11 km) may have a large impact on the difference between the two time series. In response to this concern, we investigate the effect of using an alternative scheme to process SMB mass anomalies. Instead of processing them consistently with GRACE data, as was explained in Sect. , we directly compute SMB-related mass anomalies per drainage system from the RACMO2.3 grid with a spatial resolution of 11 km. We find that the difference for the entirety of Greenland is negligible: smaller than 2 Gt. For individual drainage systems, we find that the impact is also relatively small ($<\mathrm{12}$ Gt, which is around 10 % of the signal) (see Fig. ). Still, this effect shows a systematic behavior and may introduce some bias into GRACE-SMB estimates. For this reason, we prefer to process SMB estimates consistently with GRACE data .

Similar to Fig. , but the estimates of seasonal meltwater storage are extracted from different mascon solutions for individual drainage systems: NW, SE, and N. The errors are not shown in the plot for the sake of its readability. The mean standard deviations of the errors for NW, SE, and N are 25, 26, and 9 Gt, respectively.

[Figure omitted. See PDF]

A simple method of quantifying short-term meltwater storage

The total–SMB residuals show some periods of almost null variations (nearly flat segments in Fig. ): February–March, May–July, and November–December. The total–SMB residuals represent the cumulative sum of ice discharge, meltwater storage, GRACE errors, and SMB model biases. If we assumed that the main contributor to the total–SMB residuals is ice discharge, these nearly flat features would indicate that ice discharge is negligible or even negative, which is unphysical, since this implies that discharge is contributing to Greenland mass gain. Therefore, these features should be explained either by meltwater storage or by errors in SMB- and GRACE-based estimates. Based on the robustness analysis of the total–SMB estimates in Appendix C, we infer that the quasi-null total–SMB variations during February–March and November–December are likely caused by noise in the estimates. In the following, therefore, they will not be discussed. The summer flat feature of May–July, however, always persists, no matter what data processing scenario is followed. Thereby, we suggest that it is attributed to a physical signal, i.e., short-term meltwater storage.

Monthly variations of ice discharge of Jakobshavn Glacier over the period 2009–2013 (Gt yr${}^{-\mathrm{1}}$).

[Figure omitted. See PDF]

Hereafter, we propose a simple method with which to elucidate and quantify short-term meltwater storage. According to RACMO2.3, meltwater is mostly produced between May and September, and peaks in July (cf. Fig. ). Averaged over the GRACE period, approximately 800 Gt of meltwater is produced on average in Greenland during the melt season from May to September, of which $\sim \mathrm{250}$ Gt is estimated to refreeze within the snowpack, and the rest runs off of the ice sheet. RACMO2.3 does not calculate lateral meltwater transport, i.e., the time lag between meltwater production and the moment when the runoff reaches the ocean. During late spring and early summer, this lag is particularly significant due to an inefficient subglacial channelized network and replenishing of firn aquifers (mainly in the SE and NW) .

In order to estimate the instantaneous amount of meltwater subject to runoff, we first fit the total–SMB residuals in two periods, before and after the flat feature (i.e., in April–May and September–November), with a linear function. This function can be interpreted as an empirical estimation of the mean combined effect of ice discharge and the difference between the modeled meltwater refreezing and the actual one. Then, we force the mass budget at the beginning and the end of the melt season to be closed by subtracting the obtained linear function from the total–SMB residuals (Fig. ). In this way, we find that meltwater is retained in Greenland between May and October, with a $\mathrm{100}\pm \mathrm{20}$ Gt maximum in July. Note that the estimates of meltwater storage are sufficiently robust with respect to the choice of the GRACE-based mascon solution, but they may vary in a small range in timing and amplitude (Fig. ). The uncertainties of meltwater storage are computed as the root sum square of the standard deviations of noise in GRACE- and SMB-based estimates. It is worth mentioning that the error in the SMB estimates is then computed assuming 9 % and 15 % errors in modeled mean mass anomalies due to precipitation and runoff signals, respectively, after applying the same linear regression function (see above) to each component.

Estimates of non-SMB mass anomalies could reflect the delayed release of meltwater into the ocean and the variability of ice discharge. We test the effects of ice discharge variability using a monthly resolved data set of ice discharge for 55 glaciers in Greenland (See Fig. ). These glaciers are largely located in the NW and SE Greenland drainage systems, which are the largest contributors of ice mass wastage into the ocean. The sum of the obtained estimates over all 55 glaciers is shown in Fig. a. One can see that at the whole-ice-sheet scale the increase in ice discharge during the melt season is minor in all years ($\sim \mathrm{10}$ % or less). In the absence of complete coverage of the GrIS with observations of glacier velocities at the seasonal timescale, we compute a scale factor as the ratio between the ice discharge estimates from 55 glaciers considered in this study and the discharge over the entire GrIS in terms of the long-term linear trend by , and apply this scale factor (i.e., $\sim \mathrm{2}$) to the ice discharge estimate of each glacier. Then, similar to Fig. , we represent the ice discharge related mean mass anomaly per calendar month in terms of the deviation from the linear function fitting the values in April–May and September–November (cf. Fig. c). One can see that the effect of ice discharge amounts to only a few gigatonnes; i.e., its contribution to the total signal is negligible. This supports our hypothesis that that delayed runoff is likely the major contributor to the signal isolated in Fig. .

Finally, we examine individual drainage systems (cf. Figs.  and ). We refrain from an analysis of the SW and NE regions due to a relatively high level of noise in the obtained meltwater storage estimates. Regionally, the SE shows the largest meltwater accumulation per unit area. This is consistent with the fact that the rate of meltwater production is large in the sector (Fig. ), as is the storage potential owing to high accumulation rates . In the N and NW regions, the signal related to meltwater storage is less pronounced, which can be explained by the dry climate of this region, meaning that less pore space is available in the firn layer to store liquid water.

In terms of the total mass, the largest meltwater accumulation takes place in the NW and SE regions: the contribution of each region may reach around 40 Gt in July–August (cf. Figs.  and ).

As for the increase in ice discharge during the melt season, we find that it is relatively minor for both NW and SE drainage systems (less than 20 % and 10 %, respectively; see Fig. ). As such, the contribution of ice discharge to the signal reported in Figs.  and is minor for both drainage systems: not more than $\mathrm{2.0}\pm \mathrm{1.9}$ and $\mathrm{0.3}\pm \mathrm{0.5}$ Gt, respectively (cf. Fig. ). Interestingly, a much larger increase in ice discharge during the melt season is found for the single major contributor to ice discharge, Jakobshavn Glacier: up to 60 % in 2012 (Fig. ). This finding is consistent with that of .

Note that the meltwater storage signal at the drainage system scale is present in all GRACE mascon solutions but shows some discrepancies in the timing and amplitude. This means that further effort is still needed to improve the accuracy of GRACE-based estimates.

Conclusions

GRACE monthly solutions have been applied to systematically analyze the mass budget in the territory of Greenland at various temporal and spatial scales. The obtained estimate of the mean rate of mass loss produced from CSR RL05 solutions with the new variant of the mascon approach with and without data weighting is $-\mathrm{277}\pm \mathrm{21}$ and $-\mathrm{269}\pm \mathrm{21}$ Gt yr${}^{-\mathrm{1}}$ over the period 2003–2012, respectively. The rate of SMB accumulation, as modeled by RACMO2.3 and processed consistently with GRACE data, is 216 or $\mathrm{214}\pm \mathrm{122}$ Gt yr${}^{-\mathrm{1}}$, depending on whether data weighting is applied or not. The differences between GRACE- and RACMO-based trends with or without data weighting are $\mathrm{493}\pm \mathrm{124}$ or $\mathrm{483}\pm \mathrm{124}$ Gt yr${}^{-\mathrm{1}}$, which are consistent with 2003–2012 ice discharge observations by : $\mathrm{520}\pm \mathrm{31}$ Gt yr${}^{-\mathrm{1}}$. On the other hand, we observe relatively large discrepancies between the estimates for the SE and N drainage systems. Those discrepancies imply that the adopted climate model likely overestimates precipitation in the SE drainage system and underestimates it in the N drainage system.

Our estimates of accelerations in SMB-related ($-\mathrm{23.3}\pm \mathrm{2.7}$ Gt yr${}^{-\mathrm{2}}$), ice discharge-related ($\mathrm{2.6}\pm \mathrm{1.5}$ Gt yr${}^{-\mathrm{2}}$), and total ($-\mathrm{31.1}\pm \mathrm{8.1}$ Gt yr${}^{-\mathrm{2}}$) mass anomalies are consistent within error bars. Most of the observed acceleration in mass loss can be attributed to changes in SMB. This is consistent with , who found that 79 % of the mass loss acceleration can be explained by the contribution of SMB. Furthermore, our results indicate that most of the total mass acceleration observed by GRACE is attributed to the SW and NW drainage systems, which is in agreement with .

We found a remarkable seasonal cycle in the difference between monthly total and SMB cumulative mass anomalies (“total–SMB” residuals), which likely reflects significant meltwater storage in the early summer months due to an inefficiency of the subglacial channelized network. The maximum storage is observed in July: 80–120 Gt. To estimate the potential contribution of ice discharge to the observed signals, we exploited the estimates of ice discharge over 55 outlet glaciers obtained with the flux gate method. We showed that seasonality in ice discharge is on the order of a few gigatonnes; i.e., it is negligible compared with meltwater storage. We also analyzed the short-term meltwater storage per drainage system. Our results suggest that the meltwater storage is large in NW and SE drainage systems, whereas it is weak in the northern drainage system.

A comparison of estimates derived from GRACE data with different processing parameters and from different mascon products (e.g., JPL, CSR, and GSFC) revealed the presence of the short-term meltwater storage signal in all the considered solutions. At the same time, noticeable discrepancies are observed in timing and amplitude in meltwater storage estimates. These indicates that further work is needed to improve GRACE-based estimates at both Greenland-wide and drainage system scales.

Finally, this work illustrates the potential of combining multiple observational data sets and model output complemented by simple physical constraints, to better understand the contributors to GrIS mass variations at various timescales. Improving the estimates of (natural and forced) mass variations associated with individual processes is important for robust projections of future GrIS evolution and its contribution to sea level rise.