3.1 Spectrum at each equilibrium

We explore the spectrum about every equilibria in $\mathbb {E}$ as the spectrum is crucial in identifying the existence and properties of invariant manifolds/subspaces. Since the cell PDE (3.1) is linear, the perturbation problem is identical at every U, namely (3.1) itself.

For general heterogeneity $\kappa $ satisfying Assumption 3.1, we here establish that the cell eigenvalue problem associated with (3.1) is self-adjoint, and hence has only real eigenvalues. Denote the right-hand side operator as ${{\mathcal L}_0{\kern-1pt}:={\kern-1pt}(\partial _{x_1}{\kern-1pt}+{\kern-1pt}\partial _{x_2})\{\kappa (x_1,x_2) (\partial _{x_1}{\kern-1pt}+{\kern-1pt}\partial _{x_2})\}}$ to be solved with $\ell _i$ -periodic boundary conditions in ${x_i}$ . Also, we use the inner product $\langle {\mathfrak {u}},{\mathfrak {v}}\rangle :=\iint _{{\mathcal C}} {\mathfrak {u}}\bar {\mathfrak {v}} \,d{x_1}\,d{x_2}$ over the rectangular cross-section $\mathcal {C}:=[0,\ell _1]\times [0,\ell _2]$ , where an overbar denotes complex conjugation. Then, for every pair of functions ${\mathfrak {u}},{\mathfrak {v}}\in \mathbb {H}_{\mathcal C}$ , consider

$$ \begin{align*} \langle{\mathcal L}_0{\mathfrak{u}},{\mathfrak{v}}\rangle& =\iint_{{\mathcal C}} \bar{\mathfrak{v}}(\partial_{x_1}+\partial_{x_2})\{\kappa ({\mathfrak{u}}_{x_1}+{\mathfrak{u}}_{x_2})\} \,d{x_1}\,d{x_2} \\[5pt]& =\iint_{{\mathcal C}} \bar{\mathfrak{v}}\partial_{x_1}\{\kappa ({\mathfrak{u}}_{x_1}+{\mathfrak{u}}_{x_2})\} + \bar{\mathfrak{v}}\partial_{x_2}\{\kappa ({\mathfrak{u}}_{x_1}+{\mathfrak{u}}_{x_2})\} \,d{x_1}\,d{x_2} \\[5pt]& =\int_0^{\ell_2} \bigg\{ [\bar{\mathfrak{v}}\kappa ({\mathfrak{u}}_{x_1}+{\mathfrak{u}}_{x_2})]_0^{\ell_1} -\int_0^{\ell_1} \bar{\mathfrak{v}}_{x_1}\kappa ({\mathfrak{u}}_{x_1}+{\mathfrak{u}}_{x_2}) \,d{x_1} \bigg\}\,d{x_2} \\[5pt]&\quad{} + \int_0^{\ell_1} \bigg\{ [{\mathfrak{v}}\kappa ({\mathfrak{u}}_{x_1}+{\mathfrak{u}}_{x_2})]_0^{\ell_2} -\int_0^{\ell_2} \bar{\mathfrak{v}}_{x_2}\kappa ({\mathfrak{u}}_{x_1}+{\mathfrak{u}}_{x_2}) \,d{x_2} \bigg\}\,d{x_1} \\[5pt]& =-\iint_{{\mathcal C}} (\bar{\mathfrak{v}}_{x_1}+\bar{\mathfrak{v}}_{x_2})\kappa ({\mathfrak{u}}_{x_1}+{\mathfrak{u}}_{x_2}) \,d{x_1}\,d{x_2}, \end{align*} $$

as the boundary contributions vanish due to the $\ell _i$ -periodicity. Reverse the above steps with the roles of ${\mathfrak {u}}$ and ${\mathfrak {v}}$ swapped, to then deduce $\langle {\mathcal L}_0{\mathfrak {u}},{\mathfrak {v}}\rangle =\langle {\mathfrak {u}},{\mathcal L}_0{\mathfrak {v}}\rangle $ . Thus, the operator ${\mathcal L}_0$ is self-adjoint.

Consequently, every eigenvalue is real and the eigenvectors are pairwise orthogonal (or may be chosen to be so).

The next step is to establish that all the nonzero eigenvalues of ${\mathcal L}_0$ are negative and bounded away from zero. Consider the eigen-problem ${\mathcal L}_0{\mathfrak {v}}=\lambda {\mathfrak {v}}$ for cross-sectional structures ${\mathfrak {v}}\in \mathbb {H}_{\mathcal C}$ . Apply $\langle \cdot ,{\mathfrak {v}}\rangle $ to the eigen-problem to see that

$$ \begin{align*} \lambda\langle{\mathfrak{v}},{\mathfrak{v}}\rangle &=\iint_{\mathcal C} \bar{\mathfrak{v}}(\partial_{x_1}+\partial_{x_2})\{\kappa ({\mathfrak{v}}_{x_1}+{\mathfrak{v}}_{x_2})\}\,d{x_1}\,d{x_2} \\& =\cdots=-\iint_{\mathcal C} \kappa |{\mathfrak{v}}_{x_1}+{\mathfrak{v}}_{x_2}|^2\,d{x_1}\,d{x_2} \\& \leq-\kappa_{\min}\iint_{\mathcal C} |{\mathfrak{v}}_{x_1}+{\mathfrak{v}}_{x_2}|^2\,d{x_1}\,d{x_2} \,, \end{align*} $$

via integration by parts and the $\ell _i$ -periodic conditions in $x_i$ . To deduce an upper bound on the nonzero eigenvalues $\lambda $ , let us minimize $\iint _{\mathcal C} |{\mathfrak {v}}_{x_1}+{\mathfrak {v}}_{x_2}|^2\,d{x_1}\,d{x_2}$ in $\mathbb {H}_{\mathcal C}$ subject to $\langle {\mathfrak {v}},{\mathfrak {v}}\rangle =\iint _{\mathcal C}|{\mathfrak {v}}|^2\,d{x_1}\,d{x_2}=1$ and that ${\mathfrak {v}}({x_1},x_2)$ has zero mean (being orthogonal to the constant eigenvector corresponding to $\lambda =0$ ). Introduce a Lagrange multiplier $\mu $ , and use calculus of variations to minimize $\iint _{{\mathcal C}} |{\mathfrak {v}}_{x_1}+{\mathfrak {v}}_{x_2}|^2 \,d{x_1}\,d{x_2} +\mu ( \iint _{{\mathcal C}}|{\mathfrak {v}}|^2 \,d{x_1}\,d{x_2}-1 )$ . Via integration by parts, it follows that a minimizer must satisfy $(\partial _{x_1}+\partial _{x_2})^2{\mathfrak {v}}=-\mu {\mathfrak {v}}$ over ${\mathfrak {v}}\in \mathbb {H}_{{\mathcal C}}$ . This is the problem Example 3.2 solves, giving potential minimizers as $\mathrm{e}^{\mathrm{i}(m k_1 x_1+n k_2 x_2)}$ for multiplier $\mu =(mk_1+nk_2)^2$ . The zero mean condition requires at least one of $m,n$ nonzero, and since $\ell _1>\ell _2$ , so minima are thus linear combinations of $\mathrm{e}^{\mathrm{i} m k_1 x_1}$ for $m=\pm 1$ . These give $\iint _{{\mathcal C}} |{\mathfrak {v}}_{x_1}+{\mathfrak {v}}_{x_2}|^2\,d{x_1}\,d{x_2}/\langle {\mathfrak {v}},{\mathfrak {v}}\rangle =k_1^2=4\pi ^2/\ell _1^2$ . Hence, we obtain the upper bound on the nonzero eigenvalues of $\lambda \leq -\beta _1$ for $\beta _1=4\pi ^2\kappa _{\min }/\ell _1^2$ .

In the case of the heterogeneous wave propagation problem, $u_{tt}=\partial _x\{\kappa (x)u_x\}$ , this subsection’s eigenvalue analysis establishes that for the cross-sectional dynamics, there exists a zero eigenvalue separated from pure imaginary eigenvalues of magnitude at least $\sqrt {\beta _1}=2\pi \sqrt {\kappa _{\min }}/\ell _1$ .

3.2 Results of slowly varying theory

Let us comment on the preconditions for the next Proposition 3.3 as listed in [Reference Roberts52, Assumption 2]. First, Section 3.1 establishes that the spectrum of ${\mathcal L}_0$ is as required for the Hilbert space $\mathbb {H}_{\mathcal C}$ . Hence, we decompose the space into two closed ${\mathcal L}_0$ -invariant subspaces, the (slow) centre $\mathbb {E}_c^0$ and the stable $\mathbb {E}_s^0$ . Since the operator ${\mathcal L}_0$ is self-adjoint, it generates the required strongly continuous semigroups in the Sobolev space $\mathbb {H}_{\mathcal C}$ [Reference Carr13, Ch. 6]. Hence, the following result holds for homogenization.

Proposition 3.3 (Homogenization exists and emerges).

By [Reference Roberts52, Proposition 6], for every chosen truncation order N, in a domain $\mathbb {X}$ of ‘slowly varying solutions’ and after the decay of transients for $\beta '\approx \beta _1$ , the mean field $U(t,x):=(\ell _1\ell _2)^{-1} \iint _{\mathcal C} {\mathfrak {u}}(t,x,x_1,x_2) \,d{x_1}\,d{x_2}$ satisfies a generalized homogeneous PDE

(3.2)

in terms of some deterministic constants $K_n$ , to a quantifiable error [Reference Roberts52, (9)–(10) and (23)].

The above mentioned error [Reference Roberts52, (23)] involves too many new parameters to meaningfully detail here—but typically, the most important factor at each and every location $x=x_0$ is the $(N+1)$ th spatial derivative of the field ${\mathfrak {u}}$ in a spatial neighbourhood of $x_0$ . The open subset $\mathbb {X}$ of the domain $[0,L]$ is then that part of the domain where the error in (3.2) [Reference Roberts52, (23)], dominantly $\partial _x^{N+1}{\mathfrak {u}}$ , is small enough for the modelling purposes at hand.

Also, using the specific mean field defined in Proposition 3.3—the usual “cell average”—is optional: one may instead parametrize the macroscale slow manifold in terms of any reasonable alternative amplitude [Reference Roberts53, Section 5.3.3].

A generating function argument [Reference Roberts52, Corollaries 12 and 13] establishes that classic, formal, ‘slowly varying’ analyses of the embedding PDE (2.1) are valid. One just needs to formally treat derivatives in the ‘large’ direction, , as ‘small’ in a consistent asymptotic sense [Reference Roberts50, Reference Roberts46].

3.3 Wave propagation in heterogeneous media

In the case of the heterogeneous wave propagation problem, $u_{tt}=\partial _x\{\kappa (x)u_x\}$ , I conjecture that a backwards approach [Reference Hochs and Roberts32, Reference Roberts54] to the slowly varying theory here would support a cognate version of Proposition 3.3 about the generalized homogeneous wave PDE $U_{tt}=\sum _{n=0}^N K_n\partial _x^nU$ describing its dispersive macroscale waves.

However, in this case of heterogeneous wave propagation in heterogeneous media, the slow manifold is no longer attractive/emergent (unless there is some significant perturbing dissipative mechanism not included in the ideal wave PDE). Instead, we expect that the slow manifold acts as a ‘centre’ for any fast oscillations arising from the initial conditions. Indeed, conjectured backwards theory [Reference Roberts54, Section 2.5] would more precisely assert that there is a system ‘close’ to the given physical PDE $u_{tt}=\partial _x\{\kappa (x)u_x\}$ (close to some specified order in some sense) that precisely possesses the constructed homogeneous slow manifold for the macroscale, and that precisely acts as a centre for all nearby dynamics. In this way, the backwards theory would straightforwardly establish accurate modelling over “time scales ” [Reference Abdulle and Pouchon1, Reference Duerinckx and Gloria24], typically for exponent $\alpha =N$ , the order of truncation.

Although this article addresses homogenization of linear systems, a comment about homogenizing nonlinear wave systems is appropriate here. As geophysical fluid dynamists have understood for decades, for any given wave system, it is common that a nonlinear slow manifold, such as homogenization seeks, cannot actually exist [Reference Lorenz and Krishnamurthy36]. Nonetheless, backwards theory [Reference Hochs and Roberts32, Reference Roberts54] potentially applies to establish that there exists a wave system ‘close’ to the specified nonlinear wave system, where the ‘close’ systems precisely possess the constructed nonlinear slow manifold and the constructed evolution thereon. Thus, the dynamical systems approach developed here provides a methodology to prevail over subtleties in homogenizing nonlinear wave problems.

4.1 Iteration systematically constructs approximations

To construct approximations systematically, we repeatedly compute the residual, which then drives corrections, until the residual is zero to any specified order of error. Theory then assures us that the slow manifold is approximated to the same order of error [Reference Roberts52]. For example, the cas iteratively constructs the improved homogenization (the so-called ‘fourth-order’ case $N=6$ ) that

(4.3)

The code of Appendix A.2 constructs this ‘fourth-order’ homogenization (4.3), and executes in approximately 26 seconds. In the case of the heterogeneous wave propagation problem, $u_{tt}=\partial _x\{\kappa (x)u_x\}$ , we expect the macroscale homogenized dispersive wave PDE to have $U_{tt}$ equal to the same right-hand side as the above. Most other rigorous homogenizations invoke a limit ‘ $\epsilon \to 0$ ’ for some defined scale separation parameter such as $\epsilon =\ell _1/L$ . Here such a limit corresponds to the scale separation limit $k_1, k_2\to \infty $ , in which case, the homogenization (4.3) reduces to the classic, simple, diffusion PDE $U_t=U_{xx}$ . However, I emphasize that our homogenized PDEs like (4.3) are established for the finite scale separation of real physical materials: finite $\epsilon ,k_1,k_2$ .

In use, any specific truncation of higher-order homogenization, such as (4.3), may need some asymptotically consistent regularization [Reference Benjamin, Bona and Mahony7, Section 2]. For an example of regularization, let us suppose we decide on the $N=4$ truncation ${U_t=U_{xx}+\alpha ^2U_{xxxx}}$ with derived parameter . The fourth derivative term, $+\alpha ^2U_{xxxx}$ is undesirably destabilizing. However, to the same order of error, namely , the chosen truncation is asymptotically equivalent to the regularized equation ${U_t= (1-\alpha ^2\partial _x^2)^{-1} U_{xx}}$ . This regularization may be alternatively written as

$$ \begin{align*} (1-\alpha^2\partial_x^2)U_t=U_{xx}\,, \quad\text{or}\quad U_t =\frac1{2\alpha} \mathrm{e}^{-|x|/\alpha}\star U_{xx}\,. \end{align*} $$

The spatially nonlocal convolution $\mathrm{e}^{-|x/\alpha |}\star $ , whether explicit or implicit, stabilizes the regularized chosen truncation while preserving asymptotic consistency [Reference Mercer and Roberts41, cf. Section 2.2]. Such nonlocal PDEs have previously been found desirable in various homogenizations of heterogeneous systems [Reference Cooper17, pp. 2–3].

Optional high-order construction. We may set $a_2=0$ to get simpler results for a single periodic component in the heterogeneity, namely ${\kappa (x_1)=1/[1+a_1\cos k_1x_1]}$ . In this case, it becomes feasible to construct the homogenization to high-order, $N=34$ , in spatial derivatives. To construct expressions that are exact in heterogeneity amplitude $a_1$ , we also need to construct to the same order in $a_1$ because the evidence is that here, the expansions in heterogeneity amplitude $a_1$ truncate at just less than the same order as the order of derivatives. For this option (Appendix A.2), the algebra of order $N=34$ takes roughly one minute of compute time.

In general. The code of Appendix A.2 assumes the heterogeneity $\kappa \approx 1$ , specifically, $\kappa =1/[1+\kappa ']$ for some $\kappa '\propto a$ . Then multiplication by $\kappa $ is realized as multiplication by $\sum _{n=0}^{N-1}(-\kappa ')^n$ .

The method [Reference Roberts50] is to start the iteration with the leading ‘trivial’ approximation for the field and its evolution: that is, $u\approx u^{(1)}: = U$ such that . Then the nth iteration is given approximations $u^{(n)}$ and $g^{(n)}$ , and starts by evaluating, via the flux $f^{(n)}: =-\kappa (u^{(n)}_x+u^{(n)}_{x_1}+u^{(n)}_{x_2})$ , and then the residual of the embedding PDE (2.1):

$$ \begin{align*} {\operatorname{Res}}^{(n)}:=u^{(n)}_t+f^{(n)}_x+f^{(n)}_{x_1}+f^{(n)}_{x_2}. \end{align*} $$

First update the evolution via the solvability integral that here is the mean over $x_1,x_2$ : $g^{(n+1)}:=g^{(n)}+g'$ , where $g' :=\overline {{\operatorname {Res}}^{(n)}}$ . Second, update the field by a correction $u'$ through using two steps to solve $(\partial _{x_1} +\partial _{x_2}) [ \kappa (u^{\prime }_{x_1} +u^{\prime }_{x_2}) ] ={\operatorname {Res}}^{(n)} +g'$ : step 1 integrates to solve $v_{x_1}+v_{x_2}={\operatorname {Res}}^{(n)} +g'$ with zero mean to avoid unbounded updates; and step 2 integrates again to solve $u^{\prime }_{x_1}+u^{\prime }_{x_2}=v/\kappa $ with zero mean. This second “zero mean” ensures preservation of our free choice that the macroscale field parameter U is to be the local mean of the microscale field u. Then update the field approximation with $u^{(n+1)}: =u^{(n)}+u'$ .

The iterative loop terminates when the PDE residual ${\operatorname {Res}}^{(n)}$ is zero to the specified orders of error. Then the constructed homogenization, such as (4.2) and (4.3), is correct to the same order [Reference Roberts52, Proposition 6].

Analogy with machine learning. The recursive iteration used in the above construction was originally developed nearly 30 years ago [Reference Roberts50]. Let us draw an analogy between this iteration and machine learning algorithms where an ai learns the generic form of the macroscale evolution from many thousands of simulations [Reference Frank, Drikakis and Charissis28, Reference González-Garcia, Rico-Martinez and Kevrekidis29, Reference Linot and Graham35]. In the algorithm here, each recursive iteration is analogous to a layer in a deep neural network, evaluating residuals is analogous to a nonlinear neuronal function, and the linear update corrections are analogous to using weighted linear combination of outputs of one layer as the inputs of the next layer. However here, the recursion is a ‘smart neural network’ in that both the neurons and the ‘linear weights’ are crafted to the problem at hand using the physics encoded in the PDE operator—they are ‘physics-informed’. Further, being analytic, a single analysis encompasses all ‘data points’ in the state space’s domain (here all ‘slowly varying’ functions in $\mathbb {H}_{{\mathcal D}}$ ), not just a finite sample as in machine learning (possibly a biased sample). Consequently, via such algorithms, I contend that mathematicians have for decades been using such recursive iteration for implementing smart analogues of machine learning. Such analytic learning empowers the physical interpretation, validation and verification required by modern science [Reference Brenner and Koumoutsakos10].

4.2 Numerics verify these homogenizations

For a computational verification, let us use the specific instance of the heterogeneity (4.1) with $a_1=a_2=0.4$ , and wavenumbers $k_1=21$ and $k_2=34$ , that is, microscale lengths are $\ell _1=2\pi /k_1\approx 0.30$ and $\ell _2=2\pi /k_2\approx 0.18$ (all nondimensional). Consequently, let the macroscale then refer to lengths ${}\gtrsim 2\ell _1\approx 0.6$ (Section 5), that is, wavenumbers $|k|\lesssim 10$ . We compare the macroscale characteristics of the right-hand side of the homogenized (4.3) with the right-hand side of the original heterogeneous PDE (1.1).

Here the microscale heterogeneity (4.1) (see Figure 2), is near-quasi-periodic with $k_2/k_1=1.6190\approx (\sqrt (5)+1)/2$ , although this heterogeneity does have a large macroscale period $2\pi $ (as plotted). Consequently, numerically, we solve heterogeneous PDE (1.1) on the domain of length $L=2\pi $ with a microgrid of $714$ points, . The “numeric” column of Table 1 gives the resultant eigenvalues of the full heterogeneous PDE (1.1) for macroscale wavenumbers k, $|k|<10$ . These eigenvalues reflect either the decay rate of the diffusion problem (1.1) or the square of frequencies for the corresponding wave problem (1.3). The homogenization (4.3) of this quasi-periodic heterogeneity may be truncated at any chosen order in $\partial _x$ , so we compare its predictions for three truncations: the usual leading order homogenization with truncation to errors ; the ‘second-order’ homogenization with errors ; and the ‘fourth-order’ homogenization with errors . We simply substitute the mode $U=\mathrm{e}^{\lambda t+\mathrm{i}kx}$ into the truncated right-hand side of (4.3) to obtain rates to compare with that of the full problem. Table 1 shows the two expected results: first, for each wavenumber, the accuracy increases with order of truncation; and second, for each order, as the macroscale wavenumber becomes larger (the macroscale length of the mode decreases), the error increases. These expected trends in the errors are shown clearly in Figure 3 that plots the relative errors on log–log axesFootnote ² . Table 1 and Figure 3 verify our approach to modelling the homogenized dynamics of quasi-periodic heterogeneous problems.

Figure 2

Example (near) quasi-periodic microscale heterogeneous coefficient (4.1) for the case of ${a_1=a_2=0.4}$ and wavenumbers $k_1=21$ and $k_2=34$ .

Figure 3

Relative errors in the macroscale predictions by the three truncations of the homogenized PDE (4.3). Table 1 gives the data underlying this plot of errors. These are for the quasi-periodic heterogeneity (4.1) with $a_1=a_2=0.4$ and wavenumbers $k_1=21$ and $k_2=34$ .

Figure 3 indicates that the homogenization errors become large for wavenumbers $|k|\gtrsim 10\approx k_1/2$ . This apparent limit of the resolvable wavenumbers matches the estimate obtained in Section 5, the lower bound (5.1), that the macroscale lengths resolved by the homogenization are longer than roughly twice $\ell _1$ .

Table 1

Macroscale eigenvalues as a function of macroscale wavenumber k: the “numeric” column lists the computed eigenvalues of (1.1) for spatial discretization ; the last three columns are the rates predicted for $U=\mathrm{e}^{\mathrm{i} kx}$ by the homogenization (4.3) truncated to errors for orders $n=2,4,6$ , respectively.

6.1 Meso-slow homogenization

To analyse the heterogeneous PDEs (1.1) and (2.2) as a three-scale system, we first establish and create the ‘meso-slow’ manifold homogenization. That is, we use that the domain ${\mathcal D}$ , Figure 1, is thin in $x_2$ , that is, $\ell _2\ll \ell _1,L$ . Consequently, we consider the embedding PDE (2.1) by assuming the spatial variations in both $x_0$ and $x_1$ are on a relatively large length scale. That is, the derivatives of ${\mathfrak {u}}$ and $\kappa $ in both $x_0$ and $x_1$ are treated as small.

This homogenization is an example of that of a functionally graded material [Reference Anthoine5], because the mesoscale variations in heterogeneity in $x_1$ are on a length scale $\ell _1\gg \ell _2$ . Our slow manifold approach systematically incorporates all such variations within the analysis: for example, giving the fourth-order homogenization (6.3)–(6.4). At orders higher than the leading order, we systematically find higher-order derivatives of the larger scale material structure: for example, the fourth-order coefficient in the upcoming PDE (6.4) involves the third derivative ${\mathfrak {K}}"'(x_1)$ of the mesoscale variations. This approach automatically incorporates effects obtained by the “second-order homogenization” of Anthoine [Reference Anthoine5].

Akin to Section 3, we here establish the basis of a slow manifold. Consider PDE (2.1), with and neglected, and in the Sobolov space $\mathbb {H}_{[0,\ell _2]}$ with $\ell _2$ -periodic boundary conditions in ${x_2}$ :

(6.1)

The basis established here applies at each and every $x_0,x_1$ .

Equilibria. For the cell PDE (6.1), and for every $x_0,x_1$ , in $\mathbb {H}_{[0,\ell _2]}$ , clearly ${\mathfrak {u}}(t,x_2)={\mathfrak {U}}$ , constant in $x_2$ , forms a subspace of equilibria $\mathbb {E}$ .

Spectrum identifies invariant manifolds. Since the cell PDE (6.1) is linear, the perturbation problem is identical at every equilibria in $\mathbb {E}$ , namely (6.1) itself. We need to characterize the right-hand side operator in (6.1), with $\ell _2$ -periodic boundary conditions, in $\mathbb {H}_{[0,\ell _2]}$ .

For example, in the case where the heterogeneity is constant with respect to $x_2$ , a complete set of linearly independent eigenfunctions of ${\mathfrak {L}}_0$ are $\mathrm{e}^{\mathrm{i} n k_2 x_2}$ for every integer n. The spectrum of eigenvalues at $(x_0,x_1)$ is then $\lambda _{n}(x_1):=-\kappa (x_1)k_2^2n^2$ . This spectrum has one zero-eigenvalue and the rest are negative: $\lambda _{n}(x_1)\leq -\kappa (x_1) k_2^2 <0$ . Hence, for every $x_0,x_1$ , the nonzero eigenvalues satisfy $\lambda _n(x_1)\leq -\kappa _{\min }k_2^2<0$ .

For general heterogeneity, similar deductions to those of Section 3.1 establish that the operator ${\mathfrak {L}}_0$ is self-adjoint. Hence, the eigenvalues are real and eigenfunctions orthogonal. By a similar argument to that of Section 3.1, it follows that the nonzero eigenvalues of the operator are bounded above by $\lambda \leq -\beta _2$ for ${\beta _2:=\kappa _{\min }k_2^2=4\pi ^2\kappa _{\min }/\ell _2^2}$ .

Slowly varying theory. We proceed analogously to Section 3.2, but now with two space dimensions ( $x_0$ and $x_1$ ) in which solutions are slowly varying. Roberts and Bunder [Reference Roberts and Bunder55] developed rigorous slow manifold theory for spatio-temporal systems that have slow variations in multiple space dimensions. The operator ${\mathfrak {L}}_0$ satisfies the preconditions in [Reference Roberts and Bunder55, Assumption 3] with one zero eigenvalue ( $m=1,\alpha =0$ ) and the rest negative. By [Reference Roberts and Bunder55, Proposition 1], and analogous to Proposition 3.3, we are assured that in a regime of slowly varying solutions, the mesoscale field ${\mathfrak {U}}(t,x_0,x_1)$ satisfies a PDE akin to (3.2), but in 2D space, to a quantified error [Reference Roberts and Bunder55, (52)], and upon neglecting exponentially decaying transients (decaying faster than $\mathrm{e}^{-\beta 't}$ for $\beta '\approx \beta _2$ ).

A generating function argument [Reference Roberts and Bunder55, Sections 3.2–3.3] establishes the validity of formal ‘slowly varying’ analysis of the embedding PDE (2.1).

An example mesoscale homogenization. Appendix B lists and documents cas code to construct the mesoscale homogenization for the example case of heterogeneous diffusivity

(6.2) $$ \begin{align} \kappa(x_1,x_2):=1/[1/{\mathfrak{K}}(x_1)+a_2\cos k_2x_2] \quad\text{for }k_2:=2\pi/\ell_2\,, \end{align} $$

and some given mesoscale heterogeneity function ${\mathfrak {K}}(x_1)$ . The code derives that in terms of the mesoscale mean ${\mathfrak {U}}(t,x_0,x_1)$ , and in terms of ${\mathfrak {D}}_x:=\partial _{x_0}+\partial _{x_1}$ , the microscale field (cf. (4.2a)) is

(6.3)

Simultaneously, the code derives that the mesoscale mean field evolves according to the quasi-diffusion PDE

(6.4)

As to be expected, the leading-order effective diffusivity on the mesoscale, ${\mathfrak {K}}(x_1)$ , is the harmonic mean over $x_2$ of the microscale diffusivity (6.2). The theory of this subsection assures us that a truncation of the PDE (6.4) models the dynamics of the embedded PDE (2.1) whenever and wherever the spatial gradients in $x_0$ and $x_1$ are ‘small’ enough on the microscale $\ell _2$ . That is, PDE (6.4) is a mesoscale model.

6.2 Homogenization of the mesoscale model

The mesoscale PDE (6.4) is heterogeneous on the spatial length scale $\ell _1$ of variations in the coefficient ${\mathfrak {K}}(x_1)$ . For the case $\ell _1\ll L$ , we here derive the macroscale homogenization of this mesoscale model. We have to choose some truncation of PDE (6.4) to analyse further, so let us choose the leading order truncation ${\mathfrak {U}}_t={\mathfrak {D}}_x\{ {\mathfrak {K}}(x_1) {\mathfrak {D}}_x{\mathfrak {U}} \}$ as the mesoscale model.

To compare with the one-step homogenization, let us consider PDE (6.4) in the case where the mesoscale diffusivity is

$$ \begin{align*} {\mathfrak{K}}(x_1):=1/[ 1+a_1\cos k_1x_1] \quad\text{for }k_1:=2\pi/\ell_1\,. \end{align*} $$

The theory and construction of the homogenization follow the same procedure as detailed before, so let us just summarize here. First, we treat derivatives as ‘small’. Then the cross-sectional cell PDE is

(6.5)

to be solved with $\ell _1$ -periodic boundary conditions in $x_1$ , and in space ${\mathcal H}_{[0,\ell _1]}$ .

Second, a subspace of equilibria of (6.5) is ${\mathfrak {U}}(t,x_1)=U$ , constant in $x_1$ . The spectrum of the linear operator can be straightforwardly shown to be self-adjoint with one zero eigenvalue, and the rest negative and bounded away from zero, $\lambda \leq -\beta _1$ , for $\beta _1:=k_1^2{{\mathfrak {K}}}_{\min }=4\pi ^2{{\mathfrak {K}}}_{\min }/\ell _1^2$ .

Third, slowly varying theory for cylindrical domains, akin to Section 3.2, applies to assure us there exists a slow manifold homogenization of the mesoscale model in terms of a macroscale mean field $U(t,x_0)$ . Further, the slow manifold emerges exponentially quickly on a time scale of $1/\beta _1$ , and we may approximate the slow manifold via formal ‘slowly varying’ analysis of the mesoscale PDE (6.4).

Fourth, the construction from the mesoscale PDE ${{\mathfrak {U}}}_t={\mathfrak {D}}_x\{ {\mathfrak {K}}(x_1) {{\mathfrak {D}}}_x{\mathfrak {U}} \}$ to the macroscale homogenization is the specific case of Section 4 with $a_2=0$ and no variable $x_2$ . Consequently, corresponding results follow immediately, such as the slow manifold is (4.2a) with $a_2=0$ , and the macroscale homogenization is $U_t=U_{xx}$ to errors .

Here there is no point proceeding to higher order error in $\partial _x$ , because we chose the leading order mesoscale PDE at the start of this subsection. To obtain correct higher-order macroscale homogenizations, we would chose a correspondingly higher-order mesoscale homogenization.