2.2.1 Melting

As direct coupling of ice-sheet models with ocean-circulation models is computationally expensive (e.g. Jordan and others, Reference Jordan2018), a multitude of submarine melt rate parameterizations exist which attempt to capture the relevant processes with either location-dependent parameterizations (e.g. Gagliardini and others, Reference Gagliardini, Durand, Zwinger, Hindmarsh and Le Meur2010), ice-thickness-dependent parameterizations (e.g. Joughin and others, Reference Joughin, Smith and Holland2010; Favier and others, Reference Favier2014) or parameterizations which include a dependence on the ice-shelf slope (e.g. Little and others, Reference Little, Goldberg, Gnanadesikan and Oppenheimer2012; Lazeroms and others, Reference Lazeroms, Jenkins, Gudmundsson and van de Wal2018, Reference Lazeroms, Jenkins, Rienstra and van de Wal2019; Favier and others, Reference Favier2019).

The focus of this study is to gain insights into the qualitative differences in the grounding-line dynamics resulting from the use of different melt rate parameterizations. We therefore consider a limited subset of idealized parameterizations representative of typical choices:

(5)$$\dot m = \left\{\matrix{ & \hskip-10pt f( x) \hfill \cr & \hskip-12pt \gamma_2 h^{2} \hfill \cr & \hskip-12pt \gamma_3 ( h_{\rm g}-h) \left\vert {{\rm d} {h}\over {\rm d} {x}}\right\vert {1\over \sqrt{1 + \epsilon^{2} ( {{\rm d} {h}}/{{\rm d} {x}}) ^{2}}},\; \quad \epsilon\ll 1. }\right.$$

The first parameterization assumes a dependence on the downstream coordinate x only, that is, we assume melting to be independent of the ice-shelf thickness h or slope dh/dx. The second parameterization (5) ₂ depends on the ice-shelf draft (depth of the ice-shelf base below sea level) and is similar to two parameterizations that have been used in studies of Pine Island (Joughin and others, Reference Joughin, Smith and Holland2010; Favier and others, Reference Favier2014). The important assumption underlying this parameterization is that melting increases with depth; consequently, melt rates are largest directly at the grounding line.

The slope-dependent parameterization (5) ₃ is a strong simplification of the melt rate derived by Lazeroms and others (Reference Lazeroms, Jenkins, Gudmundsson and van de Wal2018), who derive a general parameterization of the melt rates obtained with a plume model (Jenkins, Reference Jenkins1991). In their parameterization, the melt rate is proportional to sinα where α is the slope of the ice draft, and an 11th-order polynomial in the distance from the grounding line. We include the former dependence through an explicit slope-dependent term dh/dx, and the latter through the dependence on (h _g − h). The term $1/\sqrt {1 + \epsilon ^{2} ( {{\rm d} {h}}/{{\rm d} {x}}) ^{2}}$ with $0< {\epsilon}\ll 1$ is included as regularization of the melt rate in the limit of dh/dx → ∞.

2.2.2. Calving

Unless all ice-shelf mass is removed through melting, solution of the ice-flow model (1)–(4) additionally requires a condition that determines the position of the calving front x _c. This is generally done through a calving law, and similarly to melt rate parameterizations, a large range of options exist (e.g. Van der Veen, Reference Van der Veen1998; Dupont and Alley, Reference Dupont and Alley2005; Benn and others, Reference Benn, Warren and Mottram2007b; Goldberg and others, Reference Goldberg, Holland and Schoof2009; Nick and others, Reference Nick, Van Der Veen, Vieli and Benn2010; Gagliardini and others, Reference Gagliardini, Durand, Zwinger, Hindmarsh and Le Meur2010; Jamieson and others, Reference Jamieson2012; Gudmundsson and others, Reference Gudmundsson, Krug, Durand, Favier and Gagliardini2012).

The most numerically convenient of these choices is the assumption of a fixed calving front position x _c = const. (e.g. Gudmundsson and others, Reference Gudmundsson, Krug, Durand, Favier and Gagliardini2012; Arthern and Williams, Reference Arthern and Williams2017) as this does not require explicitly tracking the movement of the calving front. An alternative class of calving laws is based on stress or ice thickness criteria, effectively prescribing a certain ice thickness at the calving front as extensional stress and ice thickness there are linked through (4c) (e.g. Vieli and others, Reference Vieli, Funk and Blatter2000; Benn and others, Reference Benn, Hulton and Mottram2007a; Nick and others, Reference Nick, Van Der Veen, Vieli and Benn2010; Choi and others, Reference Choi, Morlighem, Rignot and Wood2021). A third calving choice we will consider assumes a fixed ice-shelf length, i.e. assuming x _c = x _g + L ₀ with L ₀ = const. While this choice would be computationally difficult to implement in laterally extended numerical ice-sheet models, it is particularly suitable for our investigation of the roles of melting and calving on grounding-line dynamics through a simplified flowline model as it does not introduce dynamical feedbacks through a varying ice-shelf length.

To summarize, the position of the calving front is here set through:

(6)$$x_{\rm c} =\left\{ \matrix{x_g + L_0 \hfill& {\rm where}\ L_0={\rm const.} \hfill\cr {\rm const.}\hfill & \cr x^{{\dagger}} \hfill&{\rm where}\ h(x^{{\dagger}}) = h_{c} = {\rm const. }\hfill }\right.$$

with the first option describing a constant ice-shelf length L ₀, the second option describing a constant calving front position x _c, and the third option describing a constant ice thickness at the calving front h _c. Note however that in the case of strong melting it is possible for the ice thickness to go to zero before this location in which case the ice-shelf length is set by the location where h goes to zero. The length of the ice shelf is thus given by

(7)$$L_{\rm s} = \min( x_{\rm c}-x_{\rm g},\; x^{\ast }-x_{\rm g}) \quad {\rm with}\quad h( x^{\ast }) = 0.$$

2.3.1 Grounding-line flux

If the longitudinal stress gradient is small at the grounding line, an expression for the ice flux can be derived from the continuity condition of the stress at the grounding line (see e.g. Hindmarsh, Reference Hindmarsh2012; Sergienko and Wingham, Reference Sergienko and Wingham2022), i.e.

(11a)$$\tau_{{\rm stream}} = \tau_{{\rm shelf}} \quad {\rm at }\quad x = x_{\rm g},\; $$

where

(11b)$$\tau_{{\rm stream}} = {2\over A^{1/n}} h\left\vert {{\rm d} {u}\over {\rm d} {x}} \right\vert ^{{1}/{n}-1}{{\rm d} {u}\over {\rm d} {x}}$$

and

(11c)$$\tau_{{\rm shelf}} = \tau_0\times \Theta\quad {\rm with }\quad \tau_0 = {1\over 2} \, \rho_{\rm i} g \left(1-{\rho_{\rm i}\over \rho_{\rm w}}\right)h_{\rm g}^{2}.$$

Θ is the ratio between the backstress at the grounding line and the unbuttressed backstress; we discuss its calculation in detail in Section 2.3.2.

From (8a), and reasonably assuming u > 0 (i.e. ice flows towards the calving front) and du/dx > 0

(12)$${{\rm d} {h}\over {\rm d} {x}} = -\left[{C_{\rm w}\over A^{{1}/{n}}W^{1/n + 1}\rho_{\rm i} g} u^{{1}/{n}} + {C\over \rho_{\rm i} g} {u^{m}\over h} + {{\rm d} {b}\over {\rm d} {x}}\right].$$

Substituting this expression into (11a) and rearranging terms leads to an implicit expression for the ice flux at the grounding line

(13)$$\eqalign{& {{\rm d} {q}\over {\rm d} {x}}h^{1/n + m + 2} + {C_{\rm w}\over A^{{1}/{n}}W^{1/n + 1}\rho_{\rm i} g} q^{1/n + 1}h^{m + 1} \cr & \quad+ {C\over \rho_{\rm i} g}q^{m + 1}h^{1/n} + q h^{1/n + m + 1}{{\rm d} {b}\over {\rm d} {x}} \cr & \quad = \left[{A^{1/n}\over 4}\rho_{\rm i} g\left(1-{\rho_{\rm i}\over \rho_{\rm w}}\right)\right]^{n} h^{1/n + m + 3+n}\Theta^{n}}$$

where dq/dx is determined by (8b) at x = x _g; for steady-states ${{\rm d} {q}}/{{\rm d} {x}} = \dot a$. Note that we only used the momentum balance to determine (13), therefore it is valid for both steady-state and time-evolving problems.

The implicit flux expression (13) contains the flux expression proposed by Schoof (Reference Schoof2007a, Reference Schoofb)

(14)$$q_{\rm g} = q_0 \times \Theta^{{n}/{( m + 1) }} \quad {\rm with } \quad q_0 = \left({A ( \rho_{\rm i} g) ^{n + 1} ( 1-\rho_{\rm i}/\rho_{\rm w}) ^{n}\over 4^{n} C} \right)^{{1}/{( m + 1) }} h_{\rm g}^{{( 3 + m + n) }/{( m + 1) }}$$

as a limiting case. Writing (13) in similar form, one can obtain

(15)$$q_g= \frac{q_0}{\left(1+\Gamma\right)^{1/(m+1)}} \times \Theta^{{n}/{(m+1)}} \quad\text{ with }\quad \Gamma= q_x\frac{\rho_i g}{C} h_g^{m+2}q_g^{-m-1} + \frac{\rho_i g}{C}\frac{\text{d}b}{\text{d}x}h_g^{m+1}q_g^{-m} + \frac{C_w A^{-1/n}}{C W^{1/n+1}}h_g^{m+1-1/n}q_g^{1/n-m} \quad $$

with the non-unity parameters in the denominator accounting for the effects of flux gradients (first term in Γ), bed gradients (second term) and lateral shear (third term) on the grounded part, upstream of the grounding line.

We have specifically chosen our model configuration and parameters to satisfy the original assumptions underlying Schoof's asymptotic theory, so that the two expressions (14) and (13) yield almost indistinguishable results in most of the domain. We point out that at the far downstream side of the bed, past ≈ 300 km, the solutions of (13) cease to exist as the bed slope becomes too large. Mathematically, this is the result of the bracketed term in the denominator of (15) becoming negative in this regime. Consequently, we do not consider configurations with grounding-line positions past this point.

By adopting the grounding-line flux expression (13), we neglect a wide range of dynamic behaviour that is caused by varying basal boundary conditions on the grounded part of the ice sheet (e.g. Tsai and others, Reference Tsai, Stewart and Thompson2015; Brondex and others, Reference Brondex, Gagliardini, Gillet-Chaulet and Durand2017; Sergienko and Wingham, Reference Sergienko and Wingham2019). We also restrict ourselves to the simplest possible geometry of a laterally confined parallel-sided outlet glacier, as the model considered here is only suitable under such conditions (e.g. Reese and others, Reference Reese, Winkelmann and Gudmundsson2018b). While this is a clear limitation of our model, neglecting the influence of the basal ice-sheet properties in particular facilitates the interpretation of our results considerably.

2.3.2. Backstress at the grounding line

In either of the flux expressions above Θ must be determined from the ice-shelf equations. In some cases this is possible analytically, through construction of asymptotic solutions of the ice-shelf equations (1b) and (3) ₂ with (10) and (4c), see Appendix B. There we find that the steady-state grounding-line stress for a spatially variable melt rate $\dot m = f( x)$ is:

(16)$${\Theta = 1 {-} \left[{( 4^{n} C_{\rm w}) ^{1/( 1 + n) } [ q( x_{\rm c}) ] ^{1/n} + {n + 1 \over n}{C_{\rm w} \over W}\int_{x_{\rm g}}^{x_{\rm c}}[ q( x') ] ^{1/n}{\rm d} x'\over \rho_{\rm i} g ( 1-\rho_{\rm i}/\rho_{\rm w}) A^{1/n}W^{1/n}h_{\rm g}^{1/n + 1}} \right]^{2n/( n + 1) }}$$

with q(x) the steady-state flux on the ice shelf $q( x) = q_{\rm g} + \int _{x_{\rm g}}^{x} f( x')\; {\rm d} x'.$ We discuss this expression in detail in Section 4.2.

As it is not always possible to construct analytical solutions, we also calculate Θ numerically with Matlab ODE solvers. In this case we use a Newton method to determine the backstress τ _shelf that simultaneously satisfies the ice-shelf momentum balance (1b) and mass balance condition (3), with boundary conditions (10) and (4c). We refer to this approach as semi-analytical.

Finally, verification of our solutions with full numerical solutions of (1)–(7) is obtained with Comsol and an adapted version of the time-dependent grounding-line code described in Schoof (Reference Schoof2007a) and Robel and others (Reference Robel, Schoof and Tziperman2014), which has been extended with an ice-shelf solver to account for buttressing; these solutions are referred to as numerical solutions. To summarize, we use three different ways to determine grounding-line position:

1. (1) analytical solution of (10) and (13) with suitably constructed Θ (e.g. (16), (18) and (25))

2. (2) semi-analytical solution of (10) and (13) with numerically determined Θ

3. (3) numerical solution of the full system of equations ((1)–(7)). In this case, the time-dependent mass balance equation

   $${\partial {h}\over \partial {t}} + {\partial {( uh) }\over \partial {x}} = \dot a \quad {\rm if }\, 0\leq x \leq x_{\rm g}$$
   is solved instead of (3) ₁, and the model is run into steady state.

We compare the different approaches in Appendix A and Section 4.2, where we show good agreement between them.

4.1.1. Steady-state configurations

In steady state, two conditions are simultaneously satisfied at the grounding line: the ice flux matches the accumulation integrated over the grounded part of the ice sheet (10), and the ice thickness is at floatation (9b). To determine grounding-line positions analytically, we use the asymptotic solutions of Θ for constant melt rates derived in Haseloff and Sergienko (Reference Haseloff and Sergienko2018):

(18)$$\eqalign{ \Theta &= 1-{1\over h_{\rm g}^{2}} \left({q_{\rm g}\over \left[\rho_{\rm i} g ( 1-\rho_{\rm i}/\rho_{\rm w}) \right]^{n} A W}\right)^{2/( n + 1) } \cr &\quad \times \left[\left(4^{n} C_{\rm w}\right)^{1/( n + 1) } + {1 + n\over n}C_{\rm w} {L_{\rm s}\over W}\right]^{2n/( n + 1) }.}$$

For a fixed ice thickness at the calving front (6) ₃, we additionally need a relation between the ice thickness at the calving front and the ice-shelf length, which we approximate with (Haseloff and Sergienko, Reference Haseloff and Sergienko2018)

(19a)$$\eqalign{& h_{\rm c} = \left[ h_{{\rm c}, {\rm unconf}}^{{( n + 1) ^{2}}/{n}}\, {\rm erfc}\left({C_{\rm w}\over 2}{L_{\rm s}^{1 + 1/n}\over W^{1 + 1/n}}\right)\right. \cr & \quad\quad\left. +\; h_{{\rm c}, {\rm conf}}^{{( n + 1) ^{2}}/{n}}{\rm erf}\left({C_{\rm w}\over 2}{L_{\rm s}^{1 + 1/n}\over W^{1 + 1/n}}\right)\right] ^{{n}/{( n + 1) ^{2}}}.}$$

h _c,unconf is the ice thickness at the calving front of unconfined ice shelves

(19b)$$h_{{\rm c}, {\rm unconf}} = {2^{2n/( n + 1) }h_{\rm g} q_{\rm g}^{1/( n + 1) }\over \left[2^{2n}q_{\rm g} + ( n + 1) [ \rho_{\rm i} g ( 1-\rho_{\rm i}/\rho_{\rm w}) ] ^{n} h_{\rm g}^{1 + n} A L_{\rm s}\right]^{1/( n + 1) }}$$

and h _c,conf is the ice thickness at the calving front of strongly buttressed ice shelves

(19c)$$h_{{\rm c}, {\rm conf}} = \left[{ 4^{n} C_{\rm w} q_{\rm g}^{1/n + 1}\over \left[\rho_{\rm i} g( 1-\rho_{\rm i}/\rho_{\rm w}) \right]^{1 + n}A^{1/n + 1} W^{1/n + 1}} \right]^{n/( n + 1) ^{2}}.$$

For illustrative purposes, we solve (8)–(9) numerically with Matlab ODE solvers to obtain the ice-sheet profiles, and (1b) and (3) ₂ with (10) and (4c) to obtain the ice-shelf profiles.

In our example, the grounding-line flux obtained with a fixed ice-shelf length mirrors the shape of the bed and the analytical and semi-analytical solutions predict three possible steady states (Fig. 3a₁–a₃), two on the downwards sloping sections of the bed, and one on the upwards sloping part of the bed. Conversely, for a fixed calving front position x _c = const., we find only one steady-state grounding-line position, located on the retrograde section of the bed (Fig. 3b₁), as the flux appears to be monotonically increasing over the entire domain (Fig. 3b₄). Finally, for a fixed ice thickness at the calving front, the ice flux at the grounding line appears independent of the bed shape over most of the domain, with the upstream branch of the flux closely following the shape of the unbuttressed flux (not shown), and the downstream branch of the ice flux being constant. This leads to the existence of two equilibrium grounding-line positions (Fig. 3c₁–c₂), one close to the unbuttressed grounding-line solution with a very short ice shelf (Fig. 3c₁) and one on the retrograde part of the bed (Fig. 3c₂). Note that the analytical flux for a constant thickness at the calving front peaks at x ≈ 100 km. This is due to the approximation of the calving-front ice thickness with (19a), which is an ad-hoc approximation of the ice thickness at the calving front and only formally correct in the two limits of no and strong buttressing (see Haseloff and Sergienko, Reference Haseloff and Sergienko2018).

For all three calving laws, we do not compute the flux at the grounding line q _g past $x\,\raise2pt{{\mathop{>}\limits_{\raise1pt{\approx} }}}\, 300\,{\rm km}$. As mentioned above, the slope of the bed db/dx has a large magnitude there, resulting in the bracketed term in the denominator of (13) being negative; such steep bedrock slopes also violate the assumptions of the shallow shelf approximation, which our model is based on (MacAyeal, Reference MacAyeal1989).

To provide more than one or two points of comparison per calving law, we compare the semi-analytical and analytical results with numerical results for a range of different widths in the appendix (see Fig. 7); there we generally find good agreement between semi-analytical solutions and the numerical solutions.

4.1.2. Stability of steady states

To determine the stability of these steady states, we perform a linear stability analysis described in Appendix C. It shows that the stability of these steady states cannot be determined from comparison of the flux gradient with the accumulation rate alone. Instead, the stability condition depends on the chosen calving law, melt rate parameterization (if we additionally take melting into account) and strength of the bed slope.

In the absence of melting, and assuming that the calving law can be expressed through a calving front position x _c(x _g,  h _g,  q _g) which is a function of grounding-line position x _g, ice thickness at the grounding line h _g, and ice flux at the grounding line q _g, the general stability condition (C20) can be written in terms of the flux gradient dq _g/dx _g and the accumulation rate $\dot a$ (see (C26))

(20)$$\eqalign{& {\rm if }\, \left(A_1 + B {q_{\rm g}^{1/n-1}\over n} \left(( 4^{n} C_{\rm w}) ^{{1}/{( n + 1) }} W + C_{\rm w} ( x_{\rm c}-x_{\rm g}) \right) \right.\cr & \left.\quad+ B C_{\rm w} q_{\rm g}^{1/n} {\partial {x_{\rm c}}\over \partial {q_{\rm g}}}\right)> 0,\; \, \zeta> 0,\; \left(h_x-{{\rm d} {h_{\rm g}}\over {\rm d} {x_{\rm g}}} \right)< 0 \cr & {\rm then\; for}\quad \left\{\matrix{ \displaystyle\dot a < {{\rm d} {q_{\rm g}}\over {\rm d} {x_{\rm g}}} \quad {\rm stable} \cr \displaystyle\dot a > {{\rm d} {q_{\rm g}}\over {\rm d} {x_{\rm g}}} \quad {\rm unstable.} }\right.}$$

We point out that the flux gradient depends not only on the bed slope (through dh _g/dx _g), but also on the accumulation gradient (${{\rm d} {\dot a}}/{{\rm d} {x_{\rm g}}}$), bed curvature (${{\rm d} {{}^{2} b}}/{{\rm d} {x_{\rm g}^{2}}}$) and buttressing; it is (C23)

(21)$${{{\rm d} {q_{\rm g}}\over {\rm d} {x_{\rm g}}} \!=\! { ( B_1-A_2 - B C_{\rm w} q_{\rm g}^{1/n}{\partial {x_{\rm c}} \over \partial {h_{\rm g}}}) {{\rm d} {h_{\rm g}} \over {\rm d} {x_{\rm g}}} - A_3{{\rm d} {\dot a} \over {\rm d} {x_{\rm g}}} - A_4{{\rm d} {{}^{2} b} \over {\rm d} {x_{\rm g}^{2}}} + B C_{\rm w} q_{\rm g}^{1/n}\left(1 - {\partial {x_{\rm c}} \over \partial {x_{\rm g}}} \right)\over A_1 + q_{\rm g}^{1/n-1} B \left[{1 \over n}( 4^{n} C_{\rm w}) ^{1/( n + 1) }W + {1 \over n}C_{\rm w} ( x_{\rm c}-x_{\rm g}) + q_{\rm g} {\partial {x_{\rm c}} \over \partial {q_{\rm g}}}\right]}.}$$

The parameters A ₁–A ₄ are defined in (C12), the parameters B and B ₁ are defined in (C14) and ζ is given by (C11).

This condition is significantly more complex than the stability conditions derived in Schoof (Reference Schoof2012) and Sergienko and Wingham (Reference Sergienko and Wingham2022), as it takes into account not only accumulation and bed gradients, but also the lateral confinement of the grounded ice sheet and buttressing by the ice shelf. The requirement $A_1 + B {q_{\rm g}^{1/n-1}\over n} ( ( 4^{n} C_{\rm w}) ^{{1}/{( n + 1) }} W\; +\; C_{\rm w} ( x_{\rm c}-x_{\rm g}) )\; +\; B C_{\rm w} q_{\rm g}^{1/n}{\partial {x_{\rm c}}}/{\partial {q_{\rm g}}} > 0$ is a necessary condition to make statements about stability with a linear stability analysis, i.e. without using a full numerical model. ζ > 0 is required for steady states to exist; otherwise the denominator in (13) is complex. The condition h _x − dh _g/dx _g is the requirement that the ice upstream of the grounding line remains grounded (Schoof, Reference Schoof2012). Provided these conditions are satisfied, the difference between the accumulation rate and the flux gradient can indeed be used to determine the stability of a steady state, in the same manner as in the case of Schoof's flux formula (Schoof, Reference Schoof2007b, Reference Schoof2012).

The terms $B{q_{\rm g}^{1/n-1}\over n} ( ( 4^{n} C_{\rm w}) ^{{1}/{( n + 1) }} W + C_{\rm w} ( x_{\rm c}-x_{\rm g}) )$ and $BC_{\rm w} q_{\rm g}^{1/n}$ are positive by definition, and we have explicitly chosen our geometry to ensure A ₁ > 0. For a constant calving front position (x _c = constant) or a constant ice-shelf length (x _c = x _g + L _s, L _s = constant), the partial derivative ∂x _c/∂q _g vanishes, and we can use a visible comparison between the flux and integrated accumulation to determine the stability of steady states in Figures 3a, b. For the solutions with a constant ice-shelf length, we can identify the two steady states on the prograde bed (a₁ and a₃) as stable grounding-line positions, while the steady-state grounding-line position on the retrograde part of the bed (a₂) is unstable. However, if the same steady state is obtained with a fixed calving front position, then the steady-state position on the retrograde bed (b₁) becomes stable. The position and stability of these steady states is also confirmed by numerical calculations, see Appendix A.

The flux gradient can be determined from (21), but this expression is complex and does not allow for a straightforward identification of the leading-order processes. To understand the role of the calving law better, we therefore use the limit of strong buttressing (formally when L _s ≫ W) to obtain a simplified analytic expression for the grounding-line flux from setting Θ = 0 in (18) (see Haseloff and Sergienko, Reference Haseloff and Sergienko2018, for details):

(22a)$$q_{{\rm g}, L_{\rm s}} = {[ \rho_{\rm i} g ( 1-\rho_{\rm i}/\rho_{\rm w}) ] ^{n} A W^{n + 1}\over ( 4^{n} C_{\rm w}) ^{1/( n + 1) }W + {1 + n \over n}C_{\rm w} L_{\rm s}}h_{\rm g}^{n + 1} \quad {\rm if }\, L_{\rm s} = {\rm const.},\; \, W\ll L_{\rm s}.$$

Equation (22a) is plotted as a dashed yellow line in Figures 3a₄. As it qualitatively agrees with the other solutions, we can use (22a) to better understand the behaviour shown in Figure 3a₁–a₃: (22a) predicts that all spatial variability in the ice flux is due to changes in the ice thickness at the grounding line h _g = −ρ _w/ρ _i b(x _g). This is qualitative similar to the ice-flux expression for unconfined ice sheets by Schoof (Reference Schoof2007b) (14), and therefore explains why this calving law reproduces the instability of grounding lines on upwards sloping beds: ${{\rm d} {q_{{\rm g}, L_{\rm s}}}}/{{\rm d} {x_{\rm g}}}$ is negative for all areas where the bed slopes upwards (db/dx _g > 0), so that the grounding line is always unstable on retrograde beds for a constant, positive accumulation rate $\dot a$.

For a constant calving front position, the general stability condition (20) predicts that the sole steady state on the retrograde section of the bed is stable. The stability of this grounding line is also confirmed by the numerical solutions in Appendix A. As for the constant ice-shelf length, an explicit flux expression can be obtained in the limit of strong buttressing:

(22b)$$q_{{\rm g}, x_{\rm c}} = {[ \rho_{\rm i} g ( 1-\rho_{\rm i}/\rho_{\rm w}) ] ^{n} A W^{n + 1}\over ( 4^{n} C_{\rm w}) ^{1/( n + 1) }W + {1 + n \over n}C_{\rm w} ( x_{\rm c}-x_{\rm g}) }h_{\rm g}^{n + 1} \quad {\rm if }\, x_{\rm c} = {\rm const.},\; \, W\ll L_{\rm s}.$$

Now, even as the depth of the seafloor decreases with increasing x _g (db/dx _g > 0) on upwards sloping parts of the bed, it is possible for the flux to increase due to the second term in the denominator, which decreases with increasing x _g. Physically, this corresponds to the fact that the length of the ice shelf and hence the amount of buttressing decreases as the grounding line advances. Less buttressing leads to an increase in the ice flux, and this increase in ice flux can exceed the reduction in ice flux due to a smaller ice thickness at the grounding line, as shown in Figure 3b₄.

When the ice thickness at the calving front is prescribed, Figure 3 shows that we have two branches, the upstream branch where the ice thickness at the calving front is set by (19b) and one where it is set by (19c). For the upstream branch, we can use (19b) to determine ∂x _c/∂q _g as

$${\partial {x_{\rm c}}\over \partial {q_{\rm g}}} = {4^{n} \left[1- ( h_{\rm c}/h_{\rm g}) ^{n + 1}\right]\over ( n + 1) [ \rho_{\rm i} g ( 1-\rho_{\rm i}/\rho_{\rm w}) ] h_{\rm g}^{n + 1}A}> 0 \quad {\rm if }\, h_{\rm c} = h_{{\rm c}, {\rm unconf.}}$$

ensuring $A_1 + B {q_{\rm g}^{1/n-1}\over n} ( ( 4^{n} C_{\rm w}) ^{{1}/{( n + 1) }} W + C_{\rm w} ( x_{\rm c} -x_{\rm g}) )+ B C_{\rm w} q_{\rm g}^{1/n} $ ${\partial {x_{\rm c}}\over \partial {q_{\rm g}}} > 0) $. Consequently, we can determine from equation (20) that these configurations are stable.

The stability condition (20) does not extend to the case where the ice thickness at the calving front is set by (19c), as this ice thickness directly sets the flux at the grounding line (which one can obtain from rearranging (19c)):

(22c)$$q_{{\rm g}, h_{\rm c}} = {[ \rho_{\rm i} g ( 1-\rho_{\rm i}/\rho_{\rm w}) ] ^{n}\over ( 4^{n} C_{\rm w}) ^{n/( n + 1) }} A W h_{\rm c}^{n + 1}.$$

For a simplified flux condition of this form the Sturm–Liouville problem considered in Appendix C reduces to the regular Sturm–Liouville problem considered in Schoof (Reference Schoof2012), and his stability conditions remain valid. As ${{\rm d} {q_{{\rm g}, h_{\rm c}}}}/{{\rm d} {x_{\rm g}}} = 0$, this branch is always unstable for positive accumulation rates.

These examples illustrate that different calving laws produce very different grounding-line positions for buttressed marine ice sheets and that the choice of calving law can change the stability of the grounding line from stable to unstable and vice versa. This suggests that the grounding-line response of buttressed marine ice sheets to different melt forcings will depend on the calving law as well.