5.1 A new firn-densification equation

Our measurements allow development of a firn-densification equation framed as a constitutive relationship, in contrast to many previous firn-densification equations that have been developed by converting depth–density–age data to densification rates. The advantage of a constitutive-relation model form is that it should, in theory, be able to reliably predict firn densification on various timescales in variable and transient climates, whereas an equation based on fitting to depth–density profiles may have limited applicability in these applications (Lundin and others, Reference Lundin2017). Note that while we are using a constitutive relationship form tuned with strain-rate data, we are using an empirical, macroscale approach for our proposed equation.

We use our strain-rate and density data, along with our derived weekly parcel viscosities, to derive an expression describing firn densification at USP50. We follow previous work (e.g. Morris and Wingham, Reference Morris and Wingham2014) and assume that the viscosity increases as the porosity decreases (i.e. η ∝ 1/(ρ _i − ρ)), that the densification rate has an Arrhenius dependence on temperature T (unit: K) with activation energy Q, and that the strain rate is linearly related to the stress. It is possible that the firn strain rate has a non-linear stress dependence, as ice visco-plasticity has, but we do not explore that possibility here. We begin by assuming that Q = 60 kJ mol⁻¹ (Arthern and others, Reference Arthern, Vaughan, Rankin, Mulvaney and Thomas2010), but subsequently test this assumption with other values for Q. We also assume that the viscosity increases as the firn ages due to processes operating at the grain scale, such as normal grain growth (Gow, Reference Gow1969). In absence of data that would allow us to determine and model those processes specifically, we introduce a factor f(τ) that is a function of the firn's age τ (years). The equation describing densification then has the form:

(5)$$\dot{\epsilon} = -{1\over \rho}{{\rm D}\rho\over {\rm D}t} = {1\over 2\eta}\sigma = {( \rho_{i}-\rho) {\rm e}^{( -Q/RT) }\over K( \rho) f( \tau) }\sigma,\; $$

where K(ρ) is a density-dependent prefactor (unit: kg² m⁻⁴ s⁻²).

Several previously developed firn-densification models have similarly used a constitutive relation to predict the densification rate (e.g. Alley, Reference Alley1987; Arnaud and others, Reference Arnaud, Barnola and Duval2000); Arthern and others, Reference Arthern, Vaughan, Rankin, Mulvaney and Thomas2010; Morris and Wingham, Reference Morris and Wingham2014). Arthern and others (Reference Arthern, Vaughan, Rankin, Mulvaney and Thomas2010) and Morris and Wingham (Reference Morris and Wingham2014) both used strain-rate measurements to define firn-densification equations, though they did not explicitly define the viscosity. Arthern and others (Reference Arthern, Vaughan, Rankin, Mulvaney and Thomas2010) used a grain growth term in the implied viscosity: as grains grow through time, the firn becomes more viscous. Morris and Wingham (Reference Morris and Wingham2014) introduced a ‘temperature-history’ term, which implies the evolution of the viscosity depends on past temperature in the firn. Though the formulations of these models are different from each other, both imply that the firn's viscosity increases with time. Our proposed equation is also based on the assumption that firn viscosity increases through time. However, we do not have reliable data that could be used to identify the specific physical mechanisms that stiffen the firn as it ages (or to develop an expression to describe those mechanisms in a numerical model). Therefore, we chose to simply let f(τ) = τ. That is, we use the firn's age explicitly as a model parameter because it is a measurable quantity.

Equation (5) implies that the viscosity of the firn is:

(6)$$\eta = {K( \rho) \tau\over 2 ( \rho_{i}-\rho) {\rm e}^{( -Q/RT) }}.$$

The quantities σ, ρ and τ are known from our data. They did increase throughout the period of observation, but we assume those changes were small enough over the duration of our experiment to consider them constant. However, Eqns (5) and (6) include the viscosity, whereas our data allowed us to calculate the parcel viscosity. For the development of our densification equation, we assume that the parcel viscosity for each depth interval and each week is equal to the viscosity of a firn parcel with homogenous properties. Specifically, we assign these theoretical parcels the mean density, maximum age and weekly mean temperature for each depth interval. We then use Eqn (6) to calculate values of K(ρ) for each depth interval for each week of the measurements. Those values are shown as blue dots in Figure 6. We exclude values outside the interquartile range of K(ρ) in order to exclude outliers, which are likely due to spatial variability, as the parcel viscosity in depth intervals is based on differencing compaction rates in boreholes several meters apart.

Figure 6. Values of the prefactor K (blue dots) derived from parcel viscosity data in Figure 5 and modeled fit to those K values (red line).

Our use of a prefactor K(ρ) follows previous work (e.g. Herron and Langway, Reference Herron and Langway1980; Arthern and others, Reference Arthern, Vaughan, Rankin, Mulvaney and Thomas2010) that used coefficients to tune densification models to observations. Although Herron and Langway (Reference Herron and Langway1980) and Arthern and others (Reference Arthern, Vaughan, Rankin, Mulvaney and Thomas2010) used constant values of K for each densification stage (thereby implying an abrupt transition from stage 1 to stage 2), we use the suggestion from Morris (Reference Morris2018) that there should be a smooth transition from stage 1 to stage 2 densification. We assume that K is a logistic function of density with the following form:

(7)$$K( \rho) = {L\over 1 + {\rm e}^{-a( \rho-\rho_{\rm c}) }} + b.$$

We use the curve_fit function in SciPy's Optimize package to fit Eqn (7) to the K(ρ) values derived from our parcel viscosity data. The optimal values for the variables are L = 9.52 × 10⁻⁷ kg² m⁻⁴ s⁻², a = 4.11 × 10⁻² m³ kg⁻¹, b = 2.82 × 10⁻⁷ kg² m⁻⁴ s⁻² and ρ _c = 515.6 kg m⁻³. The red line in Figure 6 shows the modeled fit to K(ρ).

We perform the same tuning procedure using different values for Q to test the assumption that Q = 60 kJ mol⁻¹ (Section 5.4).

5.2 Simulations using the Community Firn Model

We used the Community Firn Model (CFM; Stevens and others, Reference Stevens2020) to simulate firn compaction using our new equation. Additionally, we ran the CFM using five previously published firn-densification equations (with abbreviations): Herron and Langway (Reference Herron and Langway1980, HL), Ligtenberg and others (Reference Ligtenberg, Helsen and van den Broeke2011, LIG), Li and Zwally (Reference Li and Zwally2015, LZ), CROCUS (Vionnet and others, Reference Vionnet2012, CRO) and Medley and others (Reference Medley, Neumann, Zwally, Smith and Stevens2022, GSFC). Note that each of these equations use globally, rather than locally, tuned parameters. Each model run simulated firn compaction from February 2017 to December 2018 with daily time steps. We used our measured depth–density profile as an initial condition and our daily observations of the firn–temperature profile to set the firn temperature in the model at each time step.

We did not measure accumulation rate continuously at our site. Our only accumulation measurements occurred during site visits when we measured the previous year's total accumulation. The CFM requires accumulation at each time step (daily in this case) as a model input. We estimated this by scaling the accumulation measured at South Pole station to match our annual snow-accumulation observations at USP50. This scaled accumulation rate likely has significant uncertainty. However, this uncertainty does not significantly affect the model results because the firn-densification equations we used are dependent on either the stress or the long-term accumulation rate, neither of which vary significantly on a 2 year timescale.

The CFM uses a Lagrangian (layer-following) grid scheme, which mimics our experimental setup exactly. In the model, we track the compaction predicted between a layer near the surface (the platform) and another layer at some depth (the anchor) as that system is advected downward. We calculated the firn-compaction rate in the model by tracking the distance between the model grid layers that were closest to our field measurements; for example, to compare model predictions with measurements from instrument 4a, we found the model grid layers nearest 0.25 and 4.4 m depth and tracked the distance between those layers for the duration of the model run.

5.3 Model outputs and compaction-rate data

We compare our measurements of compaction rates against values predicted by the CFM. We consider both the variation of the compaction rates throughout the year and the cumulative compaction over the course of the measurements.

5.3.1 Weekly to seasonal compaction rates

Figure 7 shows compaction rates predicted by the six firn-densification equations and the measured compaction rates for each borehole.

Figure 7. Measured and modeled compaction rates for each borehole.

The models show a range of responses and vary in their ability to predict the compaction rates. We calculated the root mean square deviation (RMSD) and normalized RMSD (NRMSD; calculated by dividing the RMSD by the mean compaction rate in each borehole over the period of observation) between each borehole's observed compaction rate and the models’ predictions. The RMSD and NRMSD for each model and each borehole are shown in Table 1. The RMSD for each model is roughly constant regardless of borehole depth, which means that the NRMSD decreases with increasing borehole depth (because compaction rates are greater in those boreholes). This suggests that the greatest model uncertainty is in predicting compaction rates in the near surface where there is higher density variability due to variable surface properties and processes. These results can be used to inform future ‘coffee-can’ experiments: installing multiple instruments to shallow depths would improve our ability to quantify the spatial variability and predict the near-surface compaction rate. Fortunately, shallow installations are logistically easier.

Table 1. RMSD (m a⁻¹) (NRMSD, %) for each of the models compared to the compaction data

Our new firn-densification equation has the lowest NRMSD (~20 and $\sim \!10\%$ in the 4 and 10 m boreholes respectively, and ~7–8% in the 40, 80 and 106 m boreholes), which is expected because it was tuned to the data to which we are comparing it. In developing the equation we found that no single set of parameters could fit the data perfectly. For example, adjusting parameters to improve the fit to data from one borehole had the tradeoff of worsening the fit to data from another borehole. We note also that the equation tuning is independent of the CFM runs (the equation is tuned entirely using the field measurements and then used in the CFM to predict compaction).

Among the previously published models, GSFC has the lowest NRMSD (~20% in the 4 and 10 m boreholes and $\sim \!10\%$ in the deeper boreholes). LIG has slightly higher (30%) NRMSD in the shallow holes, but NRMSD is lower than GSFC in the deepest boreholes. In the 106 m borehole, the model misfits occur during opposite times of the year: GFSC predicts the summer compaction rate well but predicts too-fast compaction in the winter; LIG predicts the winter rate well but has too little compaction in the summer. The other three models (HL, CRO, LZ) have larger RMSDs: LZ and HL do not predict the temperature-driven seasonal cycle. These findings mirror those of Arthern and others (Reference Arthern, Vaughan, Rankin, Mulvaney and Thomas2010), who also compared measured compaction rates with outputs from HL and an earlier generation of LZ (Li and Zwally, Reference Li and Zwally2004). CRO predicts too little compaction at greater depths and does not reproduce the seasonal cycle. This is consistent with results from Stevens and others (Reference Stevens2020), who showed that CRO predicts compaction rates that are too slow at Summit, Greenland, possibly due to the fact that CRO was originally designed for mountain snowpacks and not deep firn (Brun and others, Reference Brun, David, Sudul and Brunot1992).

5.4 Activation energy

The temperature sensitivity of firn has been debated in the literature. Most firn-densification models (including all in this study except for CRO) use an Arrhenius relationship to represent the temperature sensitivity. Herron and Langway (Reference Herron and Langway1980) proposed activation energies in the Arrhenius term of 10.16 and 21.4 kJ mol⁻¹ in stages 1 and 2, respectively. Arthern and others (Reference Arthern, Vaughan, Rankin, Mulvaney and Thomas2010), which the LIG and GSFC models are based on, found optimum activation energies of 70, 80 and 120 kJ mol⁻¹ for three different sites. For their firn-densification equation, they used two activation energies based on theoretical values representing two different processes: 60 kJ mol⁻¹ for self-diffusion of water molecules through the ice lattice, and 42.2 kJ mol⁻¹ for the grain-growth activation energy. The Arthern and others (Reference Arthern, Vaughan, Rankin, Mulvaney and Thomas2010) equation is formulated so that the self-diffusion activation energy is sensitive to the firn temperature and the grain-growth energy is sensitive to the mean annual site temperature. This dual-energy method highlights the fact that densification is likely an amalgam of microstructural processes, each of which likely has its own temperature sensitivity. The dominant mechanism (and thus activation energy) may change with temperature and/or microstructure, which means that the correct activation energy to use in a macroscale firn-densification equation could change based on temperature or location. The LZ model uses a temperature-dependent activation energy based on ice crystal growth and deformation measurements, which is 27.7 kJ mol⁻¹ at $-50^\circ$C. Morris and Wingham (Reference Morris and Wingham2014) used near surface, summer densification observations in Greenland to derive a densification equation (not included in this study) and found an optimal activation energy of 110 kJ mol⁻¹.

The amplitude of the compaction-rate seasonality we measured is best replicated by the equations with activation energy near 60 kJ mol⁻¹ (LIG, GSFC and our proposed equation). HL and LZ, with their lower activation energies, show only a small compaction-rate increase during the warmer months. CRO does show a compaction-rate increase in the warmer months, but its amplitude is lower than the measurements.

We investigated the assumption that the activation energy in the densification equation (Eqn (5)) is 60 kJ mol⁻¹ by repeating our model tuning procedure (Section 5.1) with assumed activation energies of 40, 50, 55, 65 and 70 kJ mol⁻¹. Each activation energy yielded its own set of optimized parameters L,  a,  b and ρ _c for Eqn (7), which we used to run the CFM. Figure 8 shows model results compared with the observations, and Table 2 shows the NRMSD using each of the activation energies. For all of the boreholes, the seasonal amplitude predicted with Q = 70 kJ mol⁻¹ is too large, and it is too little with Q = 40 and Q = 50 kJ mol⁻¹. The NRMSD is similar for Q = 55,  60 and 65 kJ mol⁻¹, and no one of those values predicts the best fit at all borehole depths. The best fit for the 106 m borehole uses Q = 60 kJ mol⁻¹, and as such we choose it to be our optimal value.

Figure 8. Compaction rates predicted by Eqn (5) using a range of values for the Arrhenius activation energy Q compared to the compaction-rate data. Each instance of Eqn (5) with the various values of Q is tuned to have its own prefactor K(ρ).

Table 2. NRMSD (%) of compaction rates predicted by Eqn (5) using a range of values for the Arrhenius activation energy Q compared to the compaction-rate data

Each instance of Eqn (5) with the various values of Q is tuned to have its own prefactor K(ρ).

5.4.1 Cumulative compaction

It is also informative to consider the cumulative compaction for 2 years of observation. Figure 9 shows this for the 106 m borehole. The gray shaded area shows the estimated ±6% measurement uncertainty (Section 3.4). Our proposed model matches the observations to within a millimeter, because it was tuned to the data. Of the previously published models, LZ and GFSC over-predict, and HL and LIG under-predict, the cumulative compaction. The misfits are on the order of 1–2 cm, and fall within or nearly within the ±6% uncertainty bounds. CRO significantly underestimates the cumulative compaction. The effects of the temperature sensitivity can also be seen in this figure: HL and LZ are nearly linear, whereas the other models have a distinct curve. This results in a seasonality in model-data misfit.

Figure 9. Cumulative measured and modeled shortening of the 106 m borehole from February 2017 to December 2018. The gray shaded region is a ±6% uncertainty bound on the measurements. The legend includes the value at the end of observations/model runs.