1. Introduction

In Part I (Reference Kamb and EchelmeyerKamb and Echelmeyer, 1986[b]) we showed that an approximate treatment of the role of longitudinal stress gradients in glacier flow gives a semi-quantitative description of how the influences of local thickness and surface slope of an ice mass are effectively averaged longitudinally to drive the actual flow. This treatment, based on a perturbation approach that linearizes the basic flow-coupling equation (Part 1, equation (8), hereafter referenced as equation (1–8)) so as to give simple, comprehensible results, is developed into a general description of the flow of ice masses, under the approximation that longitudinal variations in flow are calculable as perturbations from an overall average flow.

The perturbation approach can be used with greater exactness and rigor to treat small perturbations in flow that are caused by small changes in ice thickness and surface slope of the sort that develop in a glacier as a result of climatic change or during the gradual recovery and build-up after a surge. A manifestation of the effect of longitudinal stress gradients in this context is seen in the conclusions that Reference EchelmeyerEchelmeyer (unpublished) reached concerning observed perturbations in the flow of Blue Glacier (Washington) due to a secular change in the ice surface: the flow perturbations correlate much better with longitudinally averaged thickness and slope changes than with local values. Longitudinal coupling theory is needed to provide a proper framework for interpreting perturbation-response measurements of this type so as to yield information on glacier-flow rheology.

In this paper (Part II), which is based on Reference EchelmeyerEchelmeyer (unpublished, p. 133–50), we develop a perturbation treatment that shows how longitudinal stress gradients affect the flow response of a glacier or ice sheet to small thickness and slope changes from an original datum state in which longitudinal variations in flow are already present. The differential equation for the longitudinally coupled perturbations, obtained in section 2, is solved in section 3, and the result is applied to field data from Blue Glacier in section 4.

2. Longitudinal Coupling of Perturbations in Ice Thickness and Surface Slope

To obtain a differential equation for longitudinally coupled flow perturbations, we begin with the exact longitudinal equilibrium equation derived in Part III (Reference KambKamb, 1986), equation (III-21), for the plane-strain flow of a limitlessly wide glacier or ice sheet. The flow geometry and the definitions of the thickness and slope variables are given in Figure 1. We choose an x-coordinate axis parallel to the mean slope of the glacier surface, and assume that the longitudinally fluctuating angle δ between the x-axis and the local surface slope can in this way be made small enough that terms of order δ² and higher in equation (III-21) can be neglected. We further assume that the longitudinal surface curvature is small enough that hdα/dx ~ δ so that the curvature term in equation (III-21) can be neglected, and that there is no basal sliding, so that σ_B′ = 0 in equation (III-21). The equilibrium equation then reduces to

(1)

where τ_B is basal shear stress, h is ice thickness, α is local surface slope, θ is local bed slope relative to the x-axis, is the “vertically” averaged longitudinal stress deviator in equation (III-2), and T is as defined in equation (III-3).

Fig. 1. Coordinate system and flow geometry assumed in analysis of effects of longitudinal coupling on the flow response to perturbations in ice thickness h(x) and surface slope α(x). The flow is two-dimensional (plane strain), and the diagram is drawn in the plane of strain, containing the local flow vectors. The x-axis has inclination angle γ in the flow plane: γ is chosen to minimize the departure angle δ(x). ū(x) is the mean flow velocity in the x direction, averaged over the local ice thickness.

Following the approach in Part I, section 2, we introduce two basic relationships between the y-averaged flow velocity ū and the stresses: 1. , where η is the y-averaged effective longitudinal viscosity defined in equation (1–6). 2. A relation between τ _B and ū, for which we here take, in place of equation (1–1), the more general form in equation (1–31), involving the effective shear viscosity defined in equation (1–30): Both η and are in general complicated functions of both ū/h and dū/dx, although in limiting cases they reduce to the simple forms represented by equations (1–1) and (1–7). Putting the above relationships into Equation (1), we obtain the basic flow-coupling equation

(2)

We now introduce small perturbations about an original datum state that satisfies Equation (2): h = h ₀ + h ₁, ū = ū ₀ + u ₁, α = α₀ + α₁, θ = θ₀ + β₁, η = η ₀ + η ₁, and T = T ₀ + T ₁, where subscript 0 designates the datum state and 1 the perturbations. The perturbation in θ is designated β₁ because γ is held fixed, so that a change in θ is the same as a change in bed slope β; such a change would come into consideration if we wanted to compare the flows expected over two beds that differed slightly from one another.

In carrying out the perturbation of the function , we write

(3a)

where τ ₀ is the unperturbed basal shear stress. Equation (3a) is a generalization of equation (1–9), in which the derivative ∂lnτ _B/∂ln(ū/h), the slope of the logarithmic relation between ū/h and τ _B under the conditions of the datum state (represented by the symbol |_Q in Equation (3a)), takes the place of the 1/n in Equation (1–9). The representation of τ _B in Equation (3a) as a function of the velocity-thickness ratio ū/h is consistent with the form of equations (1–30) and (1–31) as well as with equation (1–1), and it also has an empirical basis (Reference Raymond and VoightRaymond, 1978, p. 812). We will here putFootnote ^*

(3b)

recognizing that the n′ so defined is not necessarily the exponent n in the flow law, because of the complicated functional form of involving its dependence on dū/dx as well as on ū/h. Because of this dependence, n′ in Equation (3b) can be a function of x. We nevertheless expect that in normal glacier-flow situations the n′ defined by Equation (3b) wilt not depart greatly from the flow-law exponent.

The partial derivative symbols in Equations (3a) and (3b) give recognition that in principle, as noted above, depends not only on τ _B but also on dū/dx. With this recognized, in principle there should be added to Equation (3a) a “cross term” containing the effect of the perturbation du ₁/dx on the quantity . We have, however, omitted this term, in the spirit of equations (1–1) and (1–9), which assume that the shear flow is so strongly dominated by the shear stresses (measured by τ _B) that the effect of a small perturbation in longitudinal strain-rate can be neglected. The inclusion of the “cross term” leads to numerous small complications and also to an interesting effect that is, however, not due to stress-gradient coupling per se and is therefore beyond the scope of the treatment here; it will be developed in a separate paper.

To lowest order in the perturbations, we obtain from Equation (2), after cancelling the datum-state terms that separately satisfy Equation (2) exactly.

(4)

The way in which the viscosity perturbation η ₁ is coupled to the flow perturbation u ₁ can in principle be calculated from equations (1–6) and (1-22). In the limiting case where η is dominated by the longitudinal strain-rate and the relationship in equation (1–6) simplifies to equation (1–7), it follows by differentiating equation (1–7) that

(5a)

and thus

(5b)

The dependence of η on dū/dx is weakened, relative to that indicated by equation (1–7), when the effects of shear stresses, related to non-zero τ _B, are brought into consideration. This weakening is seen, for example, in the fact that as τ _B increases, the magnitude of the slope of the curves of η versus du/dx in figure 3 of Part I decreases. We will allow the weakening to be represented by replacing n in Equation (5a) by a quantity n″ smaller than n, in the range 1 ⩽ n″ ⩽ n. (When n″ = 1, η₁ = 0 in Equation (5a), which is the limiting case where du ₁/dx has a negligible effect on η .) The n″ so introduced is analogous to the n’ in Equation (3b) in that it represents the slope of the differential relation between perturbations in longitudinal strain-rate and stress deviator under the conditions of the datum state. In fact.

(5c)

which shows formally the analogy with n′ in Equation (3b).Footnote ^* Although n” can thus be a function of x, we assume that it is slowly enough varying that its x-derivative can be ignored.

Fig. 3. Flow perturbation data for Blue Glacier. (a) Perturbations in flow velocity u₁/u₀ (expressed as percentage change) are plotted against the corresponding local perturbations in ice thickness h₁/h₀. The associated local perturbations in surface slope α₁/α₀, in per cent (measured over a longitudinal interval of 350–500(m centered on each data location), are given alongside each data point. The perturbation quantities are calculated logarithmically from the observed flow and surface profile in 1957–58 and 1977–78 as explained in the text. Data are from Reference EchelmeyerEchelmeyer (unpublished). (b) Plot of perturbation data after performing symmetric longitudinal averaging of thickness and slope perturbations according to Equation (24), with averaging length 4ℓ = 1.6(km in Equation (A-21). The averaged values <α₁/α₀> are given, in per cent, alongside each data point.

The partial derivative symbols in Equation (5c) are written in recognition that in general η is a function not only of dū/dx but also of τ _B. In writing the perturbation in the form of Equation (5b), we make the assumption, analogous to what is done in Equation (3a), that the main perturbing effect on the longitudinal stress is the change in longitudinal strain-rate du ₁/dx, and we omit the effect of perturbations in τ _B on the longitudinal stress, which would in principle appear as a “cross term” in addition. Inclusion of this term leads to numerous small complications that will be treated in the subsequent paper mentioned above.

The formulation of the perturbations in Equations (3) and (5) frees the treatment here of the approximations that would be introduced by assuming the simple flow relationships in Equations (1–1) and (1–7). This can be done because in the small-perturbation treatment we need only the derivatives, at datum-state conditions, of the flow relationships. The cost of doing it is the appearance of the parameters n′ and n″, which are not necessarily the same as the flow-law exponent n, and which may give the treatment an empirical flavor, although n′ and n″ could in principle be calculated from Equations (3b) and (5c). In addition, this approach brings out explicitly a limitation on the theory that is involved in omitting the “cross terms” in Equations (3b) and (4a) as discussed above.

If now we introduce Equation (5a) into Equation (4), and collect terms, re-arrange, multiply through by n′ /τ ₀ and by 1/(1 + 2sin²θ₀), and utilize the relations dh ₁/dx = −α₁ + β₁ and τ ₀ = ρgh _Qsinα₀* (which simply represents the local shear stress τ ₀ in terms of an effective slope α₀*, as in Part I, section 7), we obtain

(6)

where

(7)

(8)

(9)

(10)

These relations are valid for all angles >α₀ and θ₀.

The “influence coefficients” ϕ_h’ ϕ_α and ϕ _β in Equations (8)–(10) govern the effects of the perturbations h _1’ α_1’ and β₁ on the flow via their contributions to the right-hand side of Equation (6). Their values depend on the local stress and flow conditions in the datum state, as well as on n′, and they are thus functions of x.

The influence coefficients ϕ_h and ϕ_α reduce to ϕ_h = 1 + n′ and ϕ _α = n′ for the datum state of the perturbation treatment in Part I (the inclined slab), for which α₀ and θ₀ are small, all longitudinal derivatives are zero, and α₀* = α ₀ . In that treatment we replace n′ with n, because we use equation (1–1) instead of Equations (3a) and (3b). In that treatment also, the analog of the perturbed flow-coupling Equation (6) lacks the n″ in the denominator of the term on the far left, and has η instead of η _o there. This reflects a key difference between the two perturbation treatments, in Part I the perturbation being treated in such a way that an unperturbed quantity η₀ never appears. Except for this non-trivial difference, and except for the possible difference between n′ and n, the present treatment of longitudinally coupled flow perturbations from a general datum state reduces exactly to the treatment in Part I under the conditions stated above.

With the definitions

(11)

and

(12)

which are similar to equations (1–11) and (1-12), and with neglect of the effects of the T ₁ term (see Part IV; (Reference Kamb and EchelmeyerKamb and Echelmeyer, 1986[a]), Equation (6) can be written

(13)

This differential equation has the same basic form as equation (1–13). The meaning of the parameters ℓ and σ is the same as discussed in Part I, sections 3 and 5. Because the factor n″ in the denominator of Equation (11) may be in the range 1 to n, as noted above, the averaging length scale given by Equation (11) can be somewhat shorter than that from equation (1–11), evaluated in Part I, section 5.

3. Solution of Differential Equation for Longitudinally Coupled Flow Perturbations: Role of Asymmetric Longitudinal Averaging

The solution of Equation (13) by the Green’s function method used to solve equation (1–13) in Part I reveals some distinct differences that arise because of the fact that while u₀ and τ ₀ in equation (1–11) are constants at the rough level of approximation used in Part I, in Equation (11) they (and also b and possible n′ and n″) are here functions of x, being features of a datum state that in general involves longitudinal variations in flow and stresses. Because of this, the parameter σ, from Equation (12), is no longer equal to the parameter µ defined by

(14)

where Detailed features of the solution for σ = µ, obtained in the Appendix to Part I, are modified when σ ≠ µ.

The modified solutions, for σ ≠ µ, are developed in the Appendix to this paper, following an initial section in which the relationship between σ and µ for situations of interest is established. The results of the Appendix are summarized below, and their implications discussed.

The Green’s functions G(x\x′), obtained in the Appendix (section A.2) and discussed in sections A.3–A.6, serve to generate the solution of Equation (13) by means of the “longitudinal averaging integral”

(15)

where x ₁ and x ₂ locate the head and terminus of the glacier, and where, from Equation (13),

(16)

(In Equation (15) we replace the “source point” coordinate ξ of the Appendix by x′, following the notation of Part I, section 3.) The Green’s function thus acts as a weighting function in the longitudinal average of the effects of the perturbation h _1’ α_1’ and β₁ on the flow response. In general, the Green’s function for longitudinally varying ℓ and non-zero σ can be approximated by an asymmetric exponential as in Equation (A-23)

(17a)

where

(17b)

and where the ‒ sign applies for x′ < x, the + sign for x′ ⩾ x. This is an exponential with different scale lengths (or coupling lengths) up-stream (x′ < x) and down-stream (x′ > x) from the “point of observation” at x. Since the amount and type of asymmetry are controlled by µ and σ, we may call these the “asymmetry parameters”. For µ = σ = 0, Equation (17) is the exact Green’s function and is the simple symmetric exponential, with coupling length ℓ, used in Part I (equation (1–15)). The parameter v in Equation (17) can be chosen to make Equation (17) represent as well as possible the exact Green’s functions for µ ≠ 0, σ ≠ 0. For linearly varying ℓ(x) with σ/µ = 1, the case treated in the Appendix to Part I, the Green’s function is approximately symmetric, and v ≈ 0 is a good choice, so that ℓ₊ = ℓ₋ = ℓ(x). For σ/µ = 3/2, which is thought to be the condition most generally applicable to flow perturbations, there is distinct asymmetry (ℓ₊ ≠ ℓ₋), and v ≈ +0.7 is a good choice. From Equation (17b), and in agreement with intuition, the down-stream coupling length ℓ₊ is longer than the up-stream coupling length ℓ_{_} if µ > 0 (ℓ increasing down-stream), and vice versa if µ < 0. For σ/µ > 3/2, the amount of asymmetry increases; thus for σ/µ = 9/4, the choice v ≈ +1.2 in Equation (17) is good. For µ = 0, with σ = 0, Equation (17) becomes the exact Green’s function, with vµ replaced by σ.

The ratio σ/µ = 3/2 applies for flow perturbations of a wide ice sheet under conditions where the ice flux in the datum state is longitudinally constant (or nearly enough so), and in which longitudinal variations in ℓ are not predominantly controlled by longitudinal variations in η_o , For flow in a channel of finite width, of parabolic cross-section, the constant ice-flow condition corresponds to σ/µ = 9/4, hence the asymmetry in the Green’s function tends to be greater for valley glaciers than for wide ice sheets, for a given value of µ.

In asymmetric longitudinal averaging, with the use of Equation (17) in the integral in Equation (15), the practical range of integration (the “averaging interval”) can reasonably be taken to be x − 2ℓ₋ ⩽ x′ ⩽ x + 2ℓ_+’ in accordance with the form of the exponential, as illustrated in Figure 2 (“averaging length” 2ℓ₊ + 2ℓ₋ ≈ 4ℓ). (To do this, the right side of Equation (17a) should be multiplied by the additional scaling factor (1 ‒ e⁻²)⁻¹.) Although ℓ_± in Equation (17b) is a function of x via ℓ(x) in Equation (17), in the integration in Equation (15) it is a constant, except for the switch from ℓ₋ to ℓ₊ as x′ passes through x.

Fig. 2. Schematic representation of asymmetric weighting functions for longitudinal averaging of the effects of perturbations in ice thickness and slope on the flow response. The scheme used is explained by the upper diagram, which shows a plot of the asymmetric weighting function in Equation (17) (here designated as W _ℓ in Figure 12) as a function of x′ around a particular “point of observation” x, for a particular choice of vµ (= 0.55). In the lower diagram, such plots of W_ℓ(x′) are shown schematically around five points x₁ … x_δ. The weighting for averaging around x₄ is approximately symmetrical, while for the other points it is distinctly asymmetrical: the diagram shows the sense of asymmetry expected near the head and terminus, and near an ice fall.

Fig. 12. Comparison of Green’s functions for σ/µ = 9/4. as in Figure 9. The dotted curves are the exact Green’s functions, the dashed curves are asymmetric exponentials with v = 1, from Equation (A-24). and the solid curves are symmetric exponentials. Scaling and other details are as explained in figure 13 of Part 1.

Fig. 9. Comparison of exact Green’s functions (dotted curves) for σ/µ = 3/2 with symmetric exponentials (solid curves) and asymmetric exponentials with ν = ; (dashed curves). These curves are calculated from Equations (A-20), (A-21). and (A-24). respectively, with ℓ taken equal to µz. Detailed explanation as in figure 13 of Part

Fig. 13. Green’s function for σ/µ = 9/4, µ = 1/4, as in Figure 10. The dotted curves give the exact Green’s function as in Equation (A-26), and the solid curves the asymmetric exponential representation for v = 1, from Equation (A-24).

Fig. 10. Green’s function for σ /µ = 3/2. µ = 1/4. shown in terms of functions of ξ for four separate values of x. The dotted curves are the exact Green’s function as in Equation (A-23). and the solid curves are its approximation by asymmetric exponentials from (Equation ma24a). scaled to the same peak heights. Detailed explanation as in figure 14 of Part I.

Figure 2 shows qualitatively the anticipated pattern of weighting-function asymmetry along the length of a glacier, based on the expectation that ℓ will decrease as the terminus and head of the glacier are approached and also on going into ice falls.

From Equation (A-23b), the exact Green’s function for the case where ℓ(x) in Equation (13) is a linear function of x and where σ = constant = (3/2)µ is

(18)

in which the + sign applies for x′ ⩽ x, the − sign for x′ ⩾ x. (The actual sign of the exponent depends also on the sign of µ, as Equation (18) indicates.) The range of x′ in Equation (18) is limited to µx′ ⩾ µx − ℓ(x). Since the approximate representation of Equation (18) by Equation (17) (with v = +0.7) becomes somewhat poor for μ ≳ 1, Equation (18) should be used in Equation (15) under those conditions of rapid longitudinal variation of ℓ and high asymmetry.

The function in Equation (18) is actually symmetric for x′ in the immediate vicinity of x; asymmetry as in Equation (17) develops progressively outward. The detailed features of the asymmetry are shown in Figures 8, 9, and 10. Figures 9 and 10 also show how well Equation (18) is approximated by the asymmetric exponential in Equation (17) with v taken as 1.

Fig. 8. Exact Green’s functions for linearly varying ℓ(x) with σ/µ = 3/2, from Equation (A-20), for several different values of µ. Detailed explanation as in Figure 12 of Part I.

The expectable extent of overall asymmetry, as measured by the ratios ℓ₊/ℓ and ℓ₋/ℓ, is shown by the values in Table I. They are calculated from Equation (17b), with v = 1, for several values of µ, which are based on glacier geometry in terms of the “convergence angle” (α − β) = −tan⁻¹(dh ₀/dx). For a given value of the ratio σ/µ, the longitudinal gradient of ice thickness dh ₀ /dx is related to µ by

(19)

which is obtained form Equation (12) with neglect of the contribution to o from dη₀/dx. The values in Table I are based on σ/µ = 3/2. For ℓ/h = 2, the practical upper limit of µ is about 0.3, whereas for ℓ/h = 6 (which seems possible on the basis of Part I, table I), we might encounter µ ~ 1.

Table 1. Asymmetrical Averaging Lengths ℓ₋and ℓ₊

There are indications that the form of Green’s function is only moderately sensitive to non-linearities in ℓ(x), so that the weighting functions in Equations (18) or (17) are applicable in a practical way to actual situations where the longitudinal variations in ℓ(x) are not strictly linear but do not depart too wildly from linearity. The effect of longitudinal variation in µ can, on the basis of equation (1A-22), be taken into account in a rough way by replacing ℓ in Equations (17) or (18) by

(20)

The practical approximate solution of Equation (13), obtained by combining Equations (15), (16), and (17) into a single formula based on the above discussion is

(21)

where ℓ_± is given by Equation (17b) and F(x) by Equation (16). In these formulae µ = dℓ/dx.

The effects of the asymmetry in longitudinal averaging on the flow response u ₁(x) are likely to be small in general, first because µ is probably in general small as noted above, and secondly because u ₁, is not in general very sensitive to modest changes in the shape of the weighting function in Equation (15). However, an exception occurs in places where h ₀ decreases to low values so that F(x) has an exaggerated sensitivity to thickness perturbations via the h ₁ /h ₀ term in Equation (16). Such places are near the ends of a glacier and near ice falls. The inordinate influence that such places would tend to exert via longitudinal coupling on the flow response of adjacent, more “normal” parts of the glacier will tend to be suppressed and mitigated by the effects of asymmetric averaging, because the decrease in h ₀ toward these places will in general be reflected in a decrease in ℓ toward them. The asymmetry of the weighting function in such situations, suggested in Figure 2, will tend to shield the flow response in adjacent parts of the glacier from the influence of these places where the extreme response conditions arise. However, very near the terminus the treatment here tends to fail for other reasons.

4. Application to an Observed Perturbation in Glacier Flow

From 1957 to 1977, Blue Glacier (Washington) increased in thickness by a few tens of meters. At the same time, there was a general decrease in surface slope, corresponding to a longitudinal gradient (a down-glacier increase) in the thickening. The combined effect of these changes was a marked increase, up to 40%, in the flow velocity. The changes have been documented by (Reference EchelmeyerEchelmeyer (unpublished), building upon the basis laid in 1957‒59 by Reference Meier, Meier, Kamb, Allen and SharpMeier and others (1974). From the measured perturbations, a comparison can be made between the observed flow response and the response expected from the slope and thickness perturbations with and without longitudinal averaging.

Figure 3a shows a plot of the observed u ₁ /h ₀ values in relation to the corresponding local perturbation h ₁ /h ₀ without longitudinal averaging. The values of the local perturbations, α₁/α₀ are given alongside the plotted points in the figure. Throughout this discussion and in Figures 3–7 we use as our numerical measure of the perturbations u ₁ /u ₀, α ₁/α ₀, and h ₁/h ₀ the quantities In(u _II/u _I ) In(_II/α_I), and In(h _II/h _I), where subscripts I and II refer to values measured in 1957–58 and 1977–79, respectively. We consider this to be the optimum way to handle perturbations that are not truly infinitesimal (see Echelmeyer, unpublished, section 5.1), and it avoids the ambiguity in the choice of u₀ that arises if linear quantities such as (u _II - u _I)/u ₀ are used. The logarithmic pert urbation values are expressed in per cent.

Fig. 7. Flow perturbation u₁/u₀ for Blue Glacier plotted as a function of thickness perturbation ĥ₁/h₀ given by the linear trend in Figure 6 evaluated at the points of observation. The open circle is for the B-profile point, re-plotted at the local value of h₁/h₀. The regression line has slope 4.35 and ordinate intercept −14%.

In Figure 3a there is considerable scatter of the data points about a bi-linear regression line of the type

(22)

that would be expected for the response to small changes in thickness and slope for flow in a cylindrical channel without effects of longitudinal stress gradients (Reference EchelmeyerEchelmeyer, unpublished, p. 258). Here Ψ is a response factor whose value depends on the shape of the channel cross-section and for Blue Glacier is approximately 0.85 (Reference EchelmeyerEchelmeyer, unpublished, p. 284). The scatter in Figure 3a is not so great as to obscure the existence of the expected regression of u ₁/u₀ against h ₁ /h ₀, but there is no detectable correlation of u ₁/u₀ with the α₁/α₀ values, which scatter widely.

The expected effect of longitudinal stress-gradient coupling in modifying Equation (22) is obtained by application of Equation (21). It can be written, for small α₀*,

(23)

where the angular brackets represent the weighted longitudinal averaging specified by the integral in Equation (21) and where the influence coefficients ϕh and ϕ _α are given by Equations (8) and (9). The response factor Ψ in Equation (23), which is not present in Equation (16), is introduced on the basis of the reasoning developed by Echelmeyer (unpublished, sections 9.2–9.4) for channels of finite width, leading to Equation (22). Inasmuch as Equation (21) describes perturbations u ₁ in the mean velocity ū, in applying Equation (23) to observed perturbations in the surface velocity u we assume that the two perturbations at any point are the same, or are proportional as they are theoretically in simple-shear flow.

If, as a first step, we were to assume that the influence coefficients had the approximate values ϕh ≈ 1 + n and ϕ_α ≈ n (as in the treatment in Part I) and for consistency were also to omit the distinction between α₀* and α ₀ (see section 2), then the expected relation in Equation (23), with Ψ taken as constant, would be

(24)

Figure 3b shows accordingly the result of replotting the data points after applying longitudinal averaging to the h ₁ /h ₀ and α ₁ /α ₀ values. The averaging is done with a symmetric exponential weighting function (Equation (17) with µ = 0), for simplicity; the expected decrease in ℓ near the terminus is represented by taking the averaging length to vary with x as follows: for x < 0.6 km, 4ℓ = 1.6 km; 0.6 < x < 1.2 km, 4ℓ = 1.2 km; x > 1.2 km, 4ℓ = 0.8 km. The variation in u ₀ under the integral sign in Equation (21) is ignored. The averaged values <α₁/α₀>, in per cent, are given alongside the data points in Figure 3b.

The replotting of the data in Figure 3b, with application of longitudinal averaging, reduces the scatter in the regression of u ₁ /u ₀ against <h ₁/h _o>, by comparison with Figure 3a. The remaining scatter, other than that from observational error, should according to Equation (24) be due to variations in <α₁/α₀>. As a result of the longitudinal averaging, the variations in α ₁ /α ₀ are greatly reduced from the variations in the local values α₁/α₀, as the numbers in Figure 3 indicate. In Figure 3b, some correlation can be seen between the <α ₁ /α ₀> values and the departures of the data points from the regression line drawn, the points with the algebraically larger <α ₁ /α ₀> values tending to fall above the line and those with more negative <α ₁ /α ₀> values below it, as expected from Equation (24). However, the extent of departure is only about one-third of what would be expected from Equation (24) with n = 3. The non-zero intercept of the regression line on the <u ₁ /u ₀> axis in Figure 3b is a separate indication of the effect of slope change on the flow. If the regression line is not biased by a correlation between <α ₁ /α ₀> and, <h ₁ /h ₀> the intercept can be interpreted as the flow perturbation resulting from the mean of the perturbations <α ₁ /α ₀> for all of the available data points, which is –6.7%, from the numbers in Figure 3b. On this basis, the intercept value of –8.5% (Fig. 3b) corresponds to an n value (1.3) in Equation (24) that is again about one-third as large as what we would expect if n is the normal flow-law exponent. On the other hand, the slope of the regression line in Figure 3b corresponds to a “normal” value n = 2,7 if interpreted by Equation (24) with Ψ = 0.85.

A more refined level of consideration of the perturbation data is attained by using the actual values of the influence coefficients ϕ_h and ϕ _α in Equation (13), which take into account the dependence on effects of longitudinal stress gradients in the datum state. From Equations (8) and (9) they can be written (for small α)

(25)

(26)

where

(27)

and

(28)

In Equations (25)–(28), the quantities cos α₀ and b that appear in Equations (8) and (9) have been taken to be 1 for practical purposes. As in Part I, section 7, in Equation (25) is the effective slope that relates to the unperturbed local basal shear stress via the relation As indicated in equation (1–24), is essentially a weighted longitudinal average of α₀

To evaluate the effects of the datum state on the influence coefficients, we list in Table II the values of Ψ, j _h’ and j _α for each of the data Points for Blue Glacier (the center-line point of each transverse profile where u, h, and α were measured in 1957–58 and 1977–78). The quantities j_h and j_α in Equations (27) and (28) are calculated from a curve u ₀(x) based on the velocity values listed (which are for 1977–78). and with η _o taken constant at 5 bar a, which is about as low a value as seems possible, consistent with ℓ/h ≈ 2 (see Part I, table I). From the numbers in Table II, it appears that j_α is commonly small enough to be disregarded. In contrast, the values of j_h are generally large enough to have a definite effect on the flow response to thickness perturbations. The variations in are also large enough to affect the response appreciably via Equation (25).

Table 2. Datum-State Effects on Influence Coefficients for Blue Glacier

If we define two variables U and π as follows

(29)

(30)

we can restate the relationship in Equation (23) in the simple form

(31)

To evaluate the perturbation data from Blue Glacier on the basis of Equation (31), the indicated longitudinal averages in Equations (29) and (30) are carried out with the , j_h , and Ψ values in Table II, and the resulting pairs of perturbation quantities U and П, from Equations (29) and (30), are plotted as points in Figure 4b. The averaging is exponentially weighted, with both longitudinal variation and (near the terminus) asymmetry in coupling lengths ℓ₋, ℓ₊ as indicated in Table II. For comparison, U _L, and П _L based on local values of the perturbations and influence coefficients, without longitudinal averaging, are plotted in Figure 4A. The application of longitudinal averaging greatly improves the relationship among the data points in Figure 4b, converting a complete scatter into a tolerable regression between П and U values. However, the regression is not well fitted by a straight line. Moreover, it does not pass through the origin, which violates a requirement of Equation (31). The cause of this anomaly can be traced, at least formally, to a relatively suppressed flow response to slope perturbations in relation to the response to thickness perturbations, a feature already discernible in the data in Figure 3b as discussed earlier. If we modify the perturbation quantity П in Equation (30) as follows

(32)

by introducing, ad hoc, a second response factor Φ, for the effect of slope perturbations, then we find that the choice Φ = 0.35 yields a reasonable regression line between U and П′ (Fig. 5), passing through the origin. Its slope corresponds to n′ = 2.5. However, since we think, on a theoretical basis (Reference EchelmeyerEchelmeyer, unpublished, section 9.1), that Φ = 1, we are reluctant to accept the above interpretation, with drastically reduced Φ, as more than a formal explanation of the data.

Fig. 4. Flow perturbation data for Blue Glacier plotted in terms of the perturbation variables U and П(in per cent) according to the framework provided by longitudinal coupling theory in Equations (29)–(31). The quantities U_L and П_L plotted in (a) are calculated according to the format of Equations (29) and (30) but without longitudinal averaging, while in (b). U and П are calculated with longitudinal averaging as specified in Equations (29) and (30). The local values of and v_h used in calculating П for the data points are listed in Table II. The longitudinal averaging parameters ℓ_± are given in the text. The open circle is the result of a symmetric longitudinal average with 4ℓ = 1.0 km for the B-profile point, showing the sensitivity of this result to the choice of averaging parameters.

Fig. 5. Blue Glacier perturbation data in terms of the modified variable П’ in Equation (32). with a slope-response factor Φ = 0.35.

An alternative formal explanation would be that for some unknown reason j_α in Equation (30) consistently assumes a value of about −2/3; however, we see no way that this large, consistent value could arise from Equation (28), or from effects of the T ₁ term in Equation (6) (see Part IV).

Probably a better conclusion is that the proper averaging length is longer than that used in the longitudinal averaging in Figures 3 and 4, so that the variations in <α ₁ /α ₀> are further suppressed. We cannot test this idea directly with averaging calculations, because the limited x range of the data set prevents meaningful averages with longer ℓ.

However, the following considerations suggest that the idea has merit. Over the range of observation (−0.3 ⩽ x ⩽ 1.3 km) the h ₁/h ₀ values scatter around a linear trend in x (Fig. 6). If this trend were to continue outside the range of observation, symmetric longitudinal averages would give h ₁ /h₀ values following this linear trend better and better as the averaging length is increased. At the same time, since α₁/α ₀ is approximately proportional to the longitudinal gradient of h ₁ /h₀ (as Figure 6 shows), longitudinal averaging will give <α ₁ /α ₀> values tending to a constant as the averaging length is increased. For a long enough averaging length, therefore, the u ₁ /u₀ values should show a response to h ₁ /h₀ varying linearly along the length of the glacier, while the response to α ₁ /α ₀ should appear only as a constant shift, resulting from the constant value of the longitudinally averaged <α ₁ /α ₀>. In conformity with this expectation, a plot of u ₁ /u₀ against ĥ ₁ /h₀ (where ĥ ₁ /h₀ is the value given by the linear trend in Figure 6 for each observation point x) shows a good linear regression (Fig. 7).Footnote ^* The slope of the line in Figure 7 (ignoring the point for profile B) corresponds to n = 4.1 (assuming Ψ = 0.85), and the intercept value (u ₁ /u₀ = −14% at ĥ ₁ /h₀ = 0) corresponds to n = 3.0 if for the constant average value <α ₁ /α ₀> we take the actually measured average value <α ₁ /α ₀> = −4.6% over the interval of observation −0.33 ⩽ x ⩽ 1.34 km. These reasonable n values differ from those implied by Figure 3b, as discussed above, perhaps because of effects entering the longitudinal averaging integrals from outside the interval of direct observation. The outside data have to be based on estimates from topographic maps of relatively modest accuracy and are therefore much less reliable than the data from inside the interval. This is especially the case for B, the lowermost profile.

Fig. 6. Variation of the perturbations h₁/h₀ and α₁/α₀, with longitudinal coordinate x in Blue Glacier. The dashed line is a linear regression fitted to the h₁/h₀ values. Data from Reference EchelmeyerEchelmeyer (unpublished).

The rather reasonable behavior of the perturbation data in the treatment of Figure 7 might be interpreted as an indication that in Figure 6 the fluctuations of the α ₁ /α ₀ values from a constant value and of the h ₁/h ₀ values from a line of constant slope represent only observational error, except perhaps for the B-profile point. Although the assessment of observational error in relation to this possibility is too complicated and extensive an issue to enter into here, this points up the fact that longitudinal (as well as lateral) averaging of the h ₁ /h₀ and α₁/α₀ data is helpful in suppressing noise due to observational error, as well as in taking into account the actual effects of stress gradients.

Because this paper is concerned with the framework for evaluating flow-perturbation data under the influence of effects of longitudinal stress gradients rather than with the interpretation of the results themselves, we shall defer a full discussion of the data and their interpretation to a separate paper. It is, however, clear from the foregoing discussion that in interpreting such data it is helpful to use longitudinal coupling theory, and that, indeed, without bringing in the effects of longitudinal averaging, especially its damping of longitudinal variations in the local surface-slope perturbation α_1″ it would not be possible to make good sense out of the data for Blue Glacier.