2 Governing equations

Our mathematical study is based on the following four equations taken from [Reference Gray, Sexton, Halliburton and Macaskill7],

(2.1) $$ \begin{align} ({\rho}_bc_b + m_w c_w W) {\frac{\partial T}{\partial t}} & = k {\frac{\partial^2 T}{\partial {x}^2}} + q_d{\rho}_bz_dX \exp\bigg(-\frac{E_d}{RT}\bigg) + q_w{\rho}_bz_wWX \exp\bigg(-\frac{E_w}{RT}\bigg) g(T) \nonumber\\ & \hspace{0.4cm} + L_v\bigg[z_cV - z_eW \exp\bigg(-\frac{L_v}{RT}\bigg)\bigg],\ \ \end{align} $$

(2.2) $$ \begin{align}\ {\frac{\partial V}{\partial t}} & = D_V {\frac{\partial^2 V}{\partial {x}^2}} + z_eW \exp\bigg(-\frac{L_v}{RT}\bigg) - z_cV,\qquad\qquad \end{align} $$

(2.3) $$ \begin{align} {\frac{\partial W}{\partial t}} & = - z_eW \exp\bigg(-\frac{L_v}{RT}\bigg) + z_cV,\qquad\qquad\qquad\quad\ \ \end{align} $$

(2.4) $$ \begin{align} \ \ \qquad\qquad\qquad{\frac{\partial X}{\partial t}} & = D_X {\frac{\partial^2 X}{\partial {x}^2}} -f{\rho}_bz_dX \exp\bigg(-\frac{E_d}{RT}\bigg)- f{\rho}_bz_wWX \exp\bigg(-\frac{E_w}{RT}\bigg) g(T), \end{align} $$

which represent the evolution of temperature T (K), water vapour V (mol/m) $^3$ , liquid water content W (mol/m $^3$ ) and oxygen X (mol/m $^3$ ) (note that we use a more natural notation for the variables than that prescribed in [Reference Gray, Sexton, Halliburton and Macaskill7]). The notation is defined in Table 1. Equation (2.1) represents conservation of energy where the exponential terms correspond to heat sources caused by the different reactions taking place. The first exponential corresponds to a dry oxidation reaction, the second represents hydrolysis and requires both water and oxygen, while the term multiplied by $L_v$ represents the energy difference between vaporisation and condensation. A more detailed discussion of these terms and relevant assumptions is provided in [Reference Gray, Sexton, Halliburton and Macaskill7, Reference Sisson, Swift, Wake and Gray18]. The function $g(T)$ is a switch that reflects the fact that the wet reaction turns off at temperature $T=T_s$ , that is,

$$ \begin{align*} g(T)=\tfrac{1}{2} [\tanh(0.6(T_s-T))+1 ] , \end{align*} $$

where $T_s$ is known through previous experimental work. Equations (2.2) and (2.3) are simple mass balances representing the temperature-driven exchange between vapour and liquid water. Theoretically, both should include diffusion but, since the vapour moves more easily, the diffusion term is only retained in (2.2). According to equations (2.2) and (2.3), vapour and water are exchanged through condensation and evaporation, where evaporation is strongly temperature dependent. Equation (2.4) shows that oxygen diffuses through the system and a significant amount is removed by oxidation and hydrolysis (it is assumed that the corresponding quantity of water is small and hence it is neglected in the mass balance (2.3), although the energy generated is nonnegligible). The many constants and typical values, taken from [Reference Gray, Sexton, Halliburton and Macaskill7], are described in Table 1.

Table 1 Variables and parameter values for computations taken from [Reference Gray, Sexton, Halliburton and Macaskill7].

The system is subject to the following boundary conditions. At the top surface, $x=L$ , we impose Newton cooling conditions, stating that the exchange of heat, vapour and oxygen are driven by the difference between the value in the surrounding air and the top of the pile,

(2.5) $$ \begin{align} - k {\frac{\partial T}{\partial x}} = h (T - T_a), \quad - D_V {\frac{\partial V}{\partial x}} = h_V (V - V_a), \quad - D_X {\frac{\partial X}{\partial x}} = h_X (X - X_a). \end{align} $$

Assuming that the bagasse is placed on an impermeable surface, we impose the following at $x=0$ ,

(2.6) $$ \begin{align} T = T_a, \quad {\frac{\partial V}{\partial x}} = 0, \quad {\frac{\partial X}{\partial x}} = 0. \end{align} $$

The final two conditions in (2.6) are based on the assumption that the substrate prevents vapour and water from passing through, and hence there is zero flux. The first condition assumes that, since the temperature variation is slow (of the order of days), it does not significantly affect the (infinitely large) substrate temperature and the temperatures match there. Obviously, these conditions could be altered if more precise details of the storage area were provided.

We assume that the pile is initially well mixed so that all values are constant: that is,

(2.7) $$ \begin{align} T(x,0) = T_{in},\quad V(x,0) = V_{a},\quad W(x,0) = W_{in},\quad X(x,0) = X_{a} , \end{align} $$

where subscript a refers to the ambient value. All except $W_{in}$ are known; we find this final value from the water equation below. The initial temperature differs from the ambient, since it comes from the process used to remove sugar from the bagasse and the time between processing and piling.

To simplify the problem, the equations are now written in nondimensional form. The scaling is

$$ \begin{align*} x' = \frac{x}{L}, \quad t' = \frac{t}{\Delta t} , \quad T' = \frac{T}{T_{in}}, \quad V' = \frac{V}{V_a},\quad W' = \frac{W}{\Delta W}, \quad X' = \frac{X}{X_a}, \end{align*} $$

where the time and water scales are the only ones not yet specified; we determine these below. Note that, in [Reference Sisson, Swift, Wake and Gray18], the temperature scale is chosen from the dry reaction, ${\Delta T = E_d/R}$ . With the values provided in Table 1, this leads to $\Delta T \approx 13,000\,$ K. As this is more than twice the temperature of the Sun, we conclude that this is not representative of the process and, consequently, prefer the switch value $T_{in}$ (which is of the order of the ambient temperature). It must be the correct order of the pile temperature for most of the process. This choice also allows us to focus on the range where thermal reactions are important.

Writing equation (2.1) in nondimensional form, and immediately dropping the primes, gives

$$ \begin{align*} ({\rho}_bc_b + m_w c_w \Delta W W) \frac{T_{in}}{\Delta t} {\frac{\partial T}{\partial t}} &= \frac{kT_{in}}{L^2} {\frac{\partial^2 T}{\partial {x}^2}} + q_d{\rho}_bz_d X_aX \exp\bigg(-\frac{E_d}{RT_{in} T}\bigg) \nonumber \\ & \quad + q_w{\rho}_bz_w \Delta W X_a W X \exp\bigg(-\frac{E_w}{RT_s T}\bigg) g(T_{in} T) \nonumber \\ & \quad + L_v\bigg[z_cV_a V - z_e\Delta W W \exp\bigg(-\frac{L_v}{RT_{in} T}\bigg)\bigg]. \end{align*} $$

The quantity of primary interest in this study is the temperature, so we will work on the timescale of thermal diffusion. Balancing the left-hand side with the first term on the right-hand side leads to

$$ \begin{align*}\Delta t = \frac{L^2 \rho_b c_b }{k} = \frac{L^2}{D_T} , \end{align*} $$

where $D_{T}={k}/{\rho _b c_b }$ . Taking values from Table 1 and a $3\,$ m pile, we obtain ${\Delta t = 3.15 \times 10^6}$ s, which is approximately 36 days.

The water equation is

(2.8) $$ \begin{align} \frac{\Delta W}{\Delta t}{\frac{\partial W}{\partial t}} &= - z_e\Delta W W\exp\bigg(-\frac{L_v}{RT_{in} T}\bigg) + z_c V_a V , \end{align} $$

which makes it clear that the water scale is linked to the vapour scale, and we set

$$ \begin{align*} \Delta W = \frac{z_c V_a}{z_e} \exp\bigg(\frac{L_v}{RT_{in}}\bigg). \end{align*} $$

Again taking values from Table 1, we find $\Delta W \approx 748\,$ mol/m $^3$ . Assuming that the water concentration in the material before being placed in the pile is based on the initial temperature and vapour concentration, we choose $W_{in}=\Delta W$ . Equation (2.8) may now be written as

$$ \begin{align*} \exp\bigg(\frac{L_v}{RT_{in}}\bigg) \frac{1}{z_e\Delta t}{\frac{\partial W}{\partial t}} = - W \exp\bigg[ -\frac{L_{v}}{RT_{in}}\bigg(\frac{1}{T}-1\bigg) \bigg] + V. \end{align*} $$

With the time and water scales fixed, we may now write the full nondimensional system

(2.9) $$ \begin{align} (1+{A}_0 W) {\frac{\partial T}{\partial t}} &= {\frac{\partial^2 T}{\partial {x}^2}} + A_1 X \exp\bigg[ - \gamma _d \bigg(\frac{1}{T}-1\bigg) \bigg] + A_2 W X \exp\bigg[ - \gamma _w\bigg(\frac{1}{T}-1\bigg) \bigg] g(T) \nonumber\\ & \quad + A_3 \bigg\{ V - W \exp\bigg[ - \gamma _v \bigg(\frac{1}{T}-1\bigg) \bigg] \bigg\}, \end{align} $$

(2.10) $$ \begin{align} \quad\,\, B_0 {\frac{\partial V}{\partial t}} &= {\frac{\partial^2 V}{\partial {x}^2}} + B_1 \bigg\{ W \exp\bigg[ - \gamma _v \bigg(\frac{1}{T}-1\bigg) \bigg] - V\bigg\} ,\qquad\qquad\qquad\end{align} $$

(2.11) $$ \begin{align} \quad C_0 {\frac{\partial W}{\partial t}} &= - W \exp\bigg[ - \gamma _v\bigg(\frac{1}{T}-1\bigg) \bigg] + V,\qquad\qquad\qquad\qquad\qquad\end{align} $$

(2.12) $$ \begin{align}\qquad\quad\ \ D_0 {\frac{\partial X}{\partial t}} &= {\frac{\partial^2 X}{\partial {x}^2}} - D_1 X \exp\bigg[ - \gamma _d \bigg(\frac{1}{T}-1\bigg) \bigg]- D_2 W X \exp\bigg[ - \gamma _w \bigg(\frac{1}{T}-1\bigg) \bigg] g(T), \end{align} $$

where

$$ \begin{align*} {A}_0 &= \frac{m_w c_w W_{in}}{\rho_b c_b } , \quad A_1 = \frac{q_d{\rho}_bz_d X_aL^2}{k T_{in}} \,\exp(- \gamma _d) , \\A_2 &= \frac{q_w{\rho}_b z_w W_{in} X_a L^2}{k T_{in}}\, \exp(- \gamma _w), \quad A_3 = \frac{L_v z_c V_a L^2}{k T_{in}}, \\ B_0 &= \frac{L^2}{\Delta t D_V}, \quad B_1 = \frac{z_c L^2}{D_V} ,\quad C_0 = \frac{\exp\bigg( \gamma _v\bigg)}{z_e\Delta t} ,\\ D_0 &= \frac{L^2}{\Delta t D_X} , \quad D_1 = \frac{f{\rho}_b z_d L^2}{D_X}\,\exp(- \gamma _d) , \quad D_2 = \frac{f{\rho}_b z_w W_{in} L^2}{D_X} \,\exp(- \gamma _w), \\ \gamma _d &= \frac{E_d}{R T_{in}}, \quad \gamma _w = \frac{E_w}{R T_{in}}, \quad \gamma _v = \frac{L_v}{R T_{in}} , \end{align*} $$

and

$$ \begin{align*} g(T)=\tfrac{1}{2} [\tanh(0.6 T_{in}(T_s/T_{in}-T))+1 ]. \end{align*} $$

The boundary conditions from (2.5) become

(2.13) $$ \begin{align} - {\frac{\partial T}{\partial x}} = \alpha_T (T - T_a/T_{in}), \quad - {\frac{\partial V}{\partial x}} = \alpha_V (V - 1), \quad - {\frac{\partial X}{\partial x}} = \alpha_X (X - 1) , \end{align} $$

on $x = 1$ , where

$$ \begin{align*} \alpha_T = \frac{h L}{k}, \quad \alpha_V = \frac{h_V L}{D_V}, \quad \alpha_X = \frac{h_X L}{D_X}. \end{align*} $$

On $x = 0$ , the boundary conditions (2.6) are simply

(2.14) $$ \begin{align} T = \frac{T_a}{T_{in}}, \quad {\frac{\partial V}{\partial x}} = 0, \quad {\frac{\partial X}{\partial x}} = 0 , \end{align} $$

and the initial conditions (2.7) are

(2.15) $$ \begin{align} T(x,0) = V(x,0) = W(x,0) = X(x,0) = 1. \end{align} $$

Using values from Table 1, all coefficients from the equations and conditions may be calculated. Taking $L = 3\,$ m leads to the values presented in Table 2.

Table 2 Values of the nondimensional coefficients when $L=3\,$ m.

The high value of $A_3$ could indicate a poor balance; however, it multiplies the term representing the exchange between water and vapour. According to equation (2.3), this is of order $10^{-5}$ and so the final term of (2.1) is of order $A_3 C_0 \approx 0.6$ and the heat equation is well balanced. Similarly, although $B_1$ in (2.2) is high it also multiplies a term of order $C_0$ . The value of $B_1 C_0$ is approximately equal to $50$ , whereas $B_0 \approx 0.1$ suggests the existence of a boundary layer in V. We will discuss this later.

3 Numerical solution

We now describe the numerical solution used to provide the qualitative and approximate results. We begin by writing (2.9)–(2.12) as

(3.1) $$ \begin{align} (1 + {A}_0 W) {\frac{\partial T}{\partial t}} &= {\frac{\partial^2 T}{\partial {x}^2}} + F_T (T,V,W,X),\qquad\quad \end{align} $$

(3.2) $$ \begin{align} B_0 {\frac{\partial V}{\partial t}} &= {\frac{\partial^2 V}{\partial {x}^2}} + F_V(T,V,W),\quad\end{align} $$

(3.3) $$ \begin{align} C_0 {\frac{\partial W}{\partial t}} &= F_W(T,V,W),\qquad\qquad \end{align} $$

(3.4) $$ \begin{align} D_0 {\frac{\partial X}{\partial t}} &= {\frac{\partial^2 X}{\partial {x}^2}} + F_X(T,V,W,X), \end{align} $$

respectively, and solve this system using the method of lines of Schiesser [Reference Schiesser17]. We define the spatial mesh $x_i = i\Delta x$ for $i = 0,\,1,\,\ldots ,\,I$ , where $\Delta x = 1/I$ and let $T_i = T(x_i,t)$ ; similarly for $V_i$ , $W_i$ and $X_i$ . Then we discretize the diffusion terms in (3.1)–(3.2) and (3.4) as

$$ \begin{align*} (1 + {A}_0 W_i) \frac{d T_i}{d t} &= \frac{T_{i+1} - 2 T_i + T_{i-1}}{\Delta x^2} + F_T (T_i,V_i,W_i,X_i), \\ B_0 \frac{d V_i}{d t} &= \frac{V_{i+1} - 2 V_i + V_{i-1}}{\Delta x^2} + F_V(T_i,V_i,W_i) , \\ D_0 \frac{d X_i}{d t} &= \frac{X_{i+1} - 2 X_i + X_{i-1}}{\Delta x^2} + F_X(T_i,V_i,W_i,X_i), \end{align*} $$

for $i = 1,\,2,\,\ldots ,\,I-1$ . Equation (3.3) is simply

$$ \begin{align*} C_0 \frac{d W_i}{d t} = F_W(T_i,V_i,W_i),\end{align*} $$

which holds for $i= 0,\,1,\,\ldots ,\,I$ . The first boundary condition in (2.14) on $x = 0$ immediately gives $T_0 = T_{in}/T_s$ . For the other remaining conditions in (2.14) and for those in (2.13) on $x = 1$ , we obtain further ordinary differential equations (ODEs) involving $V_0$ , $X_0$ , $T_{I}$ , $V_{I}$ and $X_{I}$ . These are

$$ \begin{align*} B_0 \frac{d V_0}{d t} &= \frac{2(V_{1} - V_0)}{\Delta x^2} + F_V(T_0,V_0,W_0), \\[2.5pt]D_0 \frac{d X_0}{d t} &= \frac{2(X_{1} - X_0) }{\Delta x^2} + F_X(T_0,V_0,W_0,X_0),\\[2.5pt](1 + {A}_0 W_I) \frac{d T_I}{d t} &= \frac{2\big( T_{I-1} - T_I - \Delta x \,\alpha_T (T_I-T_a/T_s)\big)}{\Delta x^2} + F_T (T_I,V_I,W_I,X_I), \\[2.5pt]B_0 \frac{d V_I}{d t} &= \frac{2\big(V_{I-1} - V_I - \Delta x\,\alpha_V (V_I - 1)\big)}{\Delta x^2} + F_V(T_I,V_I,W_I), \\[2.5pt]D_0 \frac{d X_I}{d t} &= \frac{2\big(X_{I-1} - X_I - \Delta x\,\alpha_X (X_I -1)\big)}{\Delta x^2} + F_X(T_I,V_I,W_I,X_I). \end{align*} $$

This system of ODEs is solved, with the initial conditions in (2.15), using ode23s in Matlab.

3.1 Reduced model

Based on the size of certain coefficients involved in the model, we also analyse a reduced system where W is taken as steady state (this is clearly justifiable since $C_0 = 2.9 \times 10^{-5}$ ). Thus, we set

$$ \begin{align*}W = V \exp(\gamma_v (1/T-1)) .\end{align*} $$

Consistent with this steady-state solution, the vapour equation indicates $V_{xx} \approx 0$ which leads to $V = 1$ .

The numerical solution now depends purely on equations (3.1) and (3.4) where, in keeping with the steady-state W solution, we neglect the $A_3$ term in (3.1) and replace $W = \exp (\gamma _v (1/T-1)) $ in (3.4). This two-equation system is compared with the four-equation system in the following section.