2.1 Layout

Managed by the Polar Research Institute of China, Zhongshan Station is located in the Larsemann Hills near Prydz Bay in East Antarctica. To verify the feasibility of retrieving sea-ice freeboard and snow depth using floating GPS, the Chinese 33^rd Antarctic Scientific Research team carried out field experiments on land-fast sea ice in Nella Fjord near Zhongshan Station. Figure 1 shows the locations of Zhongshan Station and our study area, as well as the locations of the reference and floating GPS, bottom pressure gauge, and drilling points in the study area. A Leica dual-frequency GPS receiver (floating GPS, photo is shown in Figure S1 in the Supporting Material) was deployed on land-fast sea ice ~100 m away from the coastline and 150 m away from a continuously operational Leica dual-frequency GPS receiver (reference GPS) on the bedrock of Tian-e Ling. To resist the strong wind, we placed the tripod with its legs frozen on the sea ice and keep the height of the GPS antenna ~1 m above the sea-ice surface. To remove the effects of, for example, ocean tides and time-varying dynamic ocean topography on the retrieval of sea-ice freeboard, the floating GPS was deployed on the top of a bottom pressure gauge (BPG), which could accurately observe the total pressure upon it. Combined with the atmospheric pressure observations from a barometer at the Zhongshan Station, we could subtract the atmospheric pressure from BPG observations and then calculate the sea-water depth and its variations. During the observations, we also conducted manual drilling measurements at two points on the sea ice (Zhao and others, Reference Zhao, Cheng, Yang, Vihma and Zhang2017). The two drilling points were ~300 metres northeast of the floating GPS, and the distance between the two drilling points was several tens of metres (shown as a single point in Fig. 1). At the drilling points, the snow depth, sea-ice freeboard and thickness were measured. These manual measurements were used to assess the sea-ice freeboard and snow depth derived from the floating GPS.

Fig 1. Map of Zhongshan Station and study area, as well as the locations of reference and floating GPS receivers, bottom pressure gauge and drilling points.

2.2 Data

The sea-ice motion, including the variations in sea-ice freeboard and sea-water depth, were observed by a floating GPS receiver during sea-ice growth in Nella Fjord near Zhongshan Station. Figure 2 shows the relationship among snow depth h _s, freeboard h _f, total freeboard h _t, sea-ice draft h _d, and sea-ice thickness h _i (left), as well as the schematic diagram of freeboard and snow depth observed by the floating GPS (right). At the beginning of the observation, the height from the GPS antenna to the sea-ice surface (h ₁) and the height from the GPS antenna to the waterline (h _r) were measured manually, and the h ₁ was measured several times during the observations. Due to bad weather and logistical reasons, the experiment in 2017 consists of two periods: the first period is from day of year (DOY) 235 to 252 (18 d) and the second period is from 286 to 324 (39 d). The values of h ₁ measured repeatedly during the experiments only vary on the order of mm, indicating that the freezing and melting on the sea ice upper surface is negligible. This is reasonable because during our observation, there was >10 cm snow cover, which isolated the sea ice from air-ice energy exchange to a great extent.

Fig 2. Relationship among snow depth h _s, freeboard h _f, total freeboard h _t, sea-ice draft h _d, and sea-ice thickness h _i (left), as well as the schematic diagram of freeboard and snow depth observed by floating GPS (right).

The BPG deployed beneath the floating GPS could observe the sea-water depth h _w in combination with the atmospheric pressure observation from an onshore barometer (corrected to sea level). The inverse barometer effect influenced both BPG and GPS measurements and was thus ignored. The pressure P at depth h _w in a liquid is represented by the following formula:

(1)$$P = \rho _{\rm w}gh_{\rm w}$$

where P is pressure caused by sea water, h _w is the sea-water depth, ρ _w = 1.028  g cm⁻³ is the sea-water density when the sea-water temperature is −1.8° and the salinity is 3.5%, and g = 982.57  cm s⁻² is the gravity observed by an high-accuracy absolute gravimeter at the Zhongshan Station after reduction to sea level. The sea-water density is the main source of uncertainty in the computation of sea-water depth. During the observations, we collected several sea-water temperatures and salinity measurements. With different combinations of these variables, the sea-water density ranged from 1027.5 to 1028.5 g cm⁻³. Thus, the uncertainty caused by density is ~0.1% in our case. The sea-water depth in our study area is ~8 metres, so the absolute accuracy of BPG-observed sea-water depth is ~1 cm. The sea-water depth consists of a constant height h _msl from the long-term mean dynamic ocean topography (MDT) to the BPG location (including the height from the long-term MDT to the geoid and the height from the geoid to the sea floor), periodic ocean tides h _tides caused by the sun and moon, the time-varying dynamic ocean topography h _topo and the high-frequency variation Δh caused by currents and surges. The different locations of the floating GPS, BPG and drilling points would cause systematic deviations in the freeboard time series. We first calculated the absolute accuracy of freeboard estimates with respect to drilling measurements, and then, by using the drilling measurements as reference, we removed the average bias between drilling measurements and freeboard time series for each observation period and focused on verifying the potential of using a floating GPS to monitor the freeboard variations. Periodic ocean tides h _tides and dynamic topography h _topo are functions of time and cannot be eliminated by long-term synchronous observation. We studied the effects of using different ocean tide corrections derived from BPG, GPS and global ocean tide models on the accurate retrieval of freeboard. We selected TPXO9 as the representative of the global tide model for the follow-up study (see the accuracy assessment of different ocean tide models in Fig. S2 in Supporting Material) (Dushaw and others, Reference Dushaw1997 (update); Lei and others, Reference Lei2018).

During the growth of sea ice, we also carried out surface drillings at two fixed points (~300 m away from the floating GPS), where snow depth, sea-ice freeboard and thickness are measured (Zhao and others, Reference Zhao, Cheng, Yang, Vihma and Zhang2017). The time span of surface drillings is from DOY 101 to 341, and its interval is approximately once a week. The surface drillings were mostly collected at 3:00 p.m. local time, which is 10:00 a.m. UTC time. Snow depth, sea-ice freeboard and thickness were measured each time from tworandomly chosen boreholes and their mean value was used to represent a single measurement. If the difference between the two boreholes was >1 cm for sea-ice freeboard or thickness, we drilled a third (or even fourth) borehole and then discarded the greatest outlier and averaged the others. In some instances, the seawater would flow through the borehole so that the sea ice was under the sea water, producing negative freeboard. In these cases, we waited until the upward-flowing sea water was still, measured the water depth above the sea-ice surface and assigned a negative value to these freeboard measurements. The total surface drillings included 33 and 31 sets of measurements at drilling point 1 and drilling point 2, respectively (Table 1). The accuracy of sea-ice freeboard and thickness measurements was within 1 cm, while the accuracy of snow depth measurements was ~3 cm. Considering the sparsity of drilling measurements, we combined the two drilling measurements into one time series and used it to assess the results of GPS-derived sea-ice freeboard and snow depth.

Table 1. Snow depth, sea-ice freeboard and thickness measured by surface drillings (cm)

3.1 GPS data processing

The TRACK module from GAMIT/GLOBK (Herring and others, Reference Herring, King and McClusky2010) and PPP-AR from the PRIDE group of Wuhan University (Geng and others, Reference Geng2019) were used to resolve the relative positioning and the precise point positioning (PPP) solutions of the vertical displacements of floating GPS, respectively. Relative positioning can eliminate or mitigate most positioning errors, enabling the relative time series to achieve mm-level accuracy. However, relative positioning undergoes significant precision degradation as baseline distances increase, whereas PPP does not. In this study, we used the relative solutions to show the best performance achieved when using floating GPS to monitor sea-ice motion and the corresponding sea-ice freeboard variations, and we used the PPP solutions to test the applicability of using floating GPS to monitor freeboard variations in the locations much farther from shore.

The success of relative processing (TRACK) depends on the separations of the moving station and the reference station; as distance increases, the differences in atmospheric delay also increase. TRACK uses the Melbourne-Wubbena combination to estimate the wide-lane ambiguity first and then determine L1 and L2 cycles separately (Herring and others, Reference Herring, King and McClusky2010). The antenna phase centre offset (PCO) and variation (PCV) of ground antennas are modelled using the azimuth and elevation model (AZEL) while the PCO and PCV of satellite antennas are modelled using the elevation-dependent model (ELEV). The IERS2003 model is used as solid Earth tide corrections while the relative ocean tide loading displacements (OTL) over our short baseline were mostly cancelled; thus, we did not apply OTL corrections. TRACK has the ability to include, for example, IONEX files to help with the ionospheric delay on long baselines. As the distance between the reference GPS in Tian-e Ling and the floating GPS was only ~150 m, the relative processing strategy of TRACK could eliminate most positioning errors such as atmospheric delays. Therefore, we did not further correct or estimate these values but, rather, used the ‘zero’ mode to calculate the displacement of the floating GPS epoch by epoch relative to the reference GPS for L1 and L2 frequencies separately. Not needing to estimate tropospheric parameters or combine ionosphere-free observation for short baselines gives relative positioning (TRACK) higher precision compared with PPP. The average RMSE for all epochs in the TRACK solutions was ~4 mm for both L1 and L2, and we discarded the outliers with RMSE >10 mm (<1% of observations were discarded). We also compared the results between L1 and L2 and found their consistency to be good, with standard deviation <1 cm. To make these results compatible with the GPS-IR results, we used L1 solutions as the relative time series.

Retrieving the integer property of single-station ambiguities in PPP is more difficult, which makes the PPP accuracy worse than that of the relative positioning. The processing strategy of PPP-AR is as follows: the vertical coordinate is calculated using the kinematic processing mode with a 30 s time interval; the elevation cut-off is set to 10° to mitigate the potential multipath. The antenna phase centre offset (PCO) and variation (PCV) are corrected using the IGS14 atx file. The undifferentiated ionospheric-free pseudorange and phase combination observable are used to remove the first-order ionospheric delays, and the impacts of higher-order delays are ignored. Notably, the ionospheric-free combination would amplify noise ~threefold compared with those using L1 or L2 independently for baselines less than several kilometres (Schaffrin and Bock, Reference Schaffrin and Bock1988). The tropospheric delays are first corrected with the Saastamonion model for a priori wet and dry delays, and then the residual zenith delays are estimated as random-walk parameters for each epoch with the GMF mapping function. Solid Earth tides of IERS2003 and ocean tide loading calculated using TPXO9 are used as tidal corrections. The fiducial satellite orbit and clock information is obtained from IGS final SP3 precise ephemeris in the IGS14 reference frame, and the receiver clocks are estimated as white-noise-like parameters. Other settings and parameters were default. The single-station ambiguity resolution makes use of the phase clock/bias products released by the PRIDE lab (ftp://igs.gnsswhu.cn/pub/) to recover its integer nature and then carry out integer ambiguity resolution. To assess the PPP accuracy, we calculated the difference in time series between PPP-AR solutions and TRACK L1 solutions; the standard deviation of the difference in time series was ~2.5 cm.

After GPS data processing, we obtained two types of solutions. The PPP kinematic solutions were in the IGS14 reference frame, while TRACK solutions were based on the onshore reference GPS. We also used the PPP-AR to calculate the daily coordinates of reference GPS and used the mean coordinates during the two experimental periods to transform the TRACK relative solutions into the IGS14 reference frame.

3.2 Sea-ice freeboard

The sea water in Nella Fjord begins to freeze in early March. The new land-fast sea-ice gains thickness until December and rapidly melts in a few months. In the following February, the sea ice disappears, and a new cycle begins again in March. During its growth, the vertical motion of sea ice was observed by a floating GPS deployed on it. Figure 3 illustrates the processing scheme used to retrieve the sea-ice freeboard.

Fig 3. The processing scheme to retrieve the sea-ice freeboard. The factors in the dashed boxes were further analysed by using different combinations of them.

The height H from the floating GPS antenna to the sea floor (BPG) mainly consists of two parts:

(2)$$H = h_{\rm w} + h_{\rm r}$$

(3)$$\eqalign{h_{\rm w} = & h_{{\rm msl}} + h_{{\rm tides}} + h_{{\rm topo}} + \Delta h \cr h_{\rm r} = & h_1 + h_{\rm f}} $$

where h _w is the sea-water depth, including the height from long-term mean ocean topography to the BPG h _msl, ocean tides h _tides, time-varying dynamic topography h _topo and high-frequency variation Δh caused by currents and surges, etc.; h _r is the distance from the GPS antenna to the sea-water surface, including freeboard h _f and the distance from the GPS antenna to the sea-ice surface h ₁. By manually measuring the sea-ice freeboard h _f, antenna height h ₁, as well as the h _w observed by BPG at the time t ₀, we could link the floating GPS displacement to the sea-ice motion (Huang and Zhang, Reference Huang and Zhang2012). To eliminate or weaken the influence of high-frequency signals (Δh) as well as the potential multipath effect on the GPS positioning time series, the hourly median of sea-ice freeboard was calculated. The constant h _msl can be obtained from previous simultaneous observations, while the variations in the hourly GPS displacement at any time t with respect to t ₀ are only related to ocean tides h _tides, dynamic topography h _topo, and the sea-ice freeboard h _f. BPG can provide observations of ocean tides h _tides, dynamic topography h _topo with respect to t ₀. Alternatively, periodic ocean tides can be calculated from the floating GPS or global tidal models. The high-accuracy time-varying dynamic topography h _topo is difficult to obtain in the Southern Ocean, especially for those areas where sea-ice exists (King and others, Reference King2009; Griesel and others, Reference Griesel, Mazloff and Gille2012). In Section 5, we will discuss the effects of using different GPS processing data, different ocean tide corrections, and whether or not dynamic topography is considered on the accurate retrieval of freeboard (factors in dashed boxes in Fig. 3). For the freeboard h _r, if the melting and freezing of sea ice on the upper surface can be neglected compared with those of the lower surface (confirmed by manual measurements), that is, the distance from the GPS antenna to the sea-ice surface (h ₁) is fixed and measured, then the freeboard h _f can be obtained from the GPS-observed vertical displacement.

3.3 Inversion of snow depth

GPS-IR is a method for estimating environmental parameters around a (nominally multipath suppressed) geodetic-quality GPS antenna without the need for a designed or rotated antenna to measure reflection signals (Roesler and Larson, Reference Roesler and Larson2018). GPS-IR has been demonstrated and validated for measuring surface soil moisture, tides, vegetation water content and snow depth (e.g., Larson, Reference Larson2016; Siegfried and others, Reference Siegfried, Medley, Larson, Fricker and Tulaczyk2017; Roesler and Larson, Reference Roesler and Larson2018). To some extent, GPS-IR studies are based on the analysis of signal-to-noise ratio (SNR) patterns created by the interference of direct and reflected signals, which can be modelled as follows (Axelrad and others, Reference Axelrad, Larson and Jones2005):

(4)$${\rm SNR}\lpar e \rpar = A\lpar e \rpar \sin \left({\displaystyle{{4\pi H_{\rm R}} \over \lambda }\sin e + \phi } \right)$$

where A(e) is the SNR amplitude, H _R is the reflector height that represents the vertical distance from the GPS antenna to the horizontal reflecting surface, e is the elevation angle of the GPS satellite with respect to the horizon, λ is the wavelength of the GPS signal and ϕ is the initial phase. Based on a simple assumption that all other reflected conditions of snow for GPS signals remain unchanged (in other words, the amplitude A and initial phase ϕ are kept fixed), we can estimate the variation in reflector height H _R by the changes in the so-called multipath frequency 2H _R/λ. In our study, H _R is the distance from the antenna to the snow surface, which is the same as h ₂ as shown in Figure 2. Considering that the distance from the antenna to the sea-ice surface remains fixed, the snow depth h _s can be calculated as follows:

(5)$$h_{\rm s} = h_1-h_2$$

3.4 Stefan's law for snow-covered ice

There were only 15 manual measurements of sea-ice thickness during 57 d of floating GPS observations. To fully analyse the relationship among freeboard, snow depth, and sea-ice thickness for all 57 d, we modelled the thermodynamic growth of sea ice based on Stefan's assumption that the heat loss during the freezing process is directed upward and is completely balanced by the latent heat of fusion of the sea ice (Allison, Reference Allison1981; Behrendt and others, Reference Behrendt, Dierking and Witte2015). The energy balance at the ice/ocean interface determines the growth rate of the sea ice dH/dt (Petrich and Eicken, Reference Petrich and Eicken2010):

(6)$$\rho _{\rm i}L_{\rm i}\displaystyle{{{\rm d}h_{\rm i}} \over {{\rm d}t}} = F_{\rm c}-F_{\rm w}$$

where ρ _i is the density of sea ice, L _i is the latent heat of fusion of the sea ice, F _c is the conductive heat flux through the sea ice, and F _w is the oceanic heat flux from below. In the case of snow cover (of thickness h _s) on top of the sea ice (of thickness h _i), the conductive heat flux F _c can be expressed by Fourier's law of heat conduction (Behrendt and others, Reference Behrendt, Dierking and Witte2015):

(7)$$F_{\rm c} = \displaystyle{{T_{\rm w}-T_0} \over {\lpar h_{\rm i}/\lambda _{\rm i}\rpar + \lpar h_{\rm s}/\lambda _{\rm s}\rpar }}$$

where T _w and T ₀ are the sea-water temperatures and snow surface temperature, respectively. λ _i and λ _s are the thermal conductivity of sea ice and snow, respectively. Since the snow surface temperature T ₀ is difficult to measure and thus usually not known, an alternative is to use the air surface temperature. The net heat flux between the air and the snow surface F _a can then be parameterized by the following linear approximation (Leppäranta, Reference Leppäranta1993):

(8)$$F_{\rm a} = \kappa \lpar {T_0-T_{\rm a}} \rpar $$

The air surface temperature T _a is taken from the automatic weather station at Zhongshan Station. As a function of wind speed, snow insulation, humidity, and so on, the effective heat transfer coefficient κ can be determined by measuring the growth of sea ice under different meteorological conditions. By assuming F _c = F _a (Leppäranta, Reference Leppäranta1993; Behrendt and others, Reference Behrendt, Dierking and Witte2015), Eqn (3) can then be written as follows:

(9)$$\rho _{\rm i}L_{\rm i}\displaystyle{{{\rm d}h_{\rm i}} \over {{\rm d}t}} = \displaystyle{{T_{\rm w}-T_{\rm a}} \over {\lpar 1/\kappa \rpar + \lpar h_{\rm i}/\lambda _{\rm i}\rpar + \lpar h_{\rm s}/\lambda _{\rm s}\rpar }}-F_{\rm w}$$

The daily growth rate dh _i/dt of the sea-ice thickness can be obtained by solving Eqn (9), and then, the sea-ice thickness h _i can be obtained.