Processing of hybrid laminates integrating ZrB<sub>2</sub>/SiC and SiC layers

Elisa Padovano; Francesco Trevisan; Sara Biamino; Claudio Badini; Elisa Padovano; Francesco Trevisan; Sara Biamino; Claudio Badini

doi:10.3934/matersci.2020.5.552

AIMS Materials Science

2020, Volume 7, Issue 5: 552-564. doi: 10.3934/matersci.2020.5.552

Previous Article Next Article

Research article Topical Sections

Processing of hybrid laminates integrating ZrB₂/SiC and SiC layers

1.
Department of Applied Science and Technology, Politecnico di Torino, Torino, Italy
2.
National Interuniversity Consortium of Materials Science and Technology, Firenze, Italy

Received: 04 May 2020 Accepted: 17 August 2020 Published: 24 August 2020

Tape casting technique was used to develop hybrid laminates constituting by SiC and ZrB₂–SiC layers; the main aim is obtaining a structure which integrate the unique properties of these materials and potentially extent their application temperature range. Multilayer with ZrB₂–SiC layers stacked in between SiC ones were successfully processed. Thin cracks propagated in the composite layers without affecting SiC ones; their formation was due to residual stresses developed in the two materials because of the differences in their shrinkage and coefficients of thermal expansion. However, these cracks did not significantly affect the material properties: relative density, elastic modulus and flexural strength of hybrid laminates was indeed only slightly lower than those of laminates made up of layers with the same composition.

Keywords:

Citation: Elisa Padovano, Francesco Trevisan, Sara Biamino, Claudio Badini. Processing of hybrid laminates integrating ZrB2/SiC and SiC layers[J]. AIMS Materials Science, 2020, 7(5): 552-564. doi: 10.3934/matersci.2020.5.552

Related Papers:

[1]	Shumoua F. Alrzqi, Fatimah A. Alrawajeh, Hany N. Hassan . An efficient numerical technique for investigating the generalized Rosenau–KDV–RLW equation by using the Fourier spectral method. AIMS Mathematics, 2024, 9(4): 8661-8688. doi: 10.3934/math.2024420
[2]	Xiaoli Wang, Lizhen Wang . Traveling wave solutions of conformable time fractional Burgers type equations. AIMS Mathematics, 2021, 6(7): 7266-7284. doi: 10.3934/math.2021426
[3]	Zhengang Zhao, Yunying Zheng, Xianglin Zeng . Finite element approximation of fractional hyperbolic integro-differential equation. AIMS Mathematics, 2022, 7(8): 15348-15369. doi: 10.3934/math.2022841
[4]	Ailing Zhu, Yixin Wang, Qiang Xu . A weak Galerkin finite element approximation of two-dimensional sub-diffusion equation with time-fractional derivative. AIMS Mathematics, 2020, 5(5): 4297-4310. doi: 10.3934/math.2020274
[5]	Jian-Gen Liu, Jian Zhang . A new approximate method to the time fractional damped Burger equation. AIMS Mathematics, 2023, 8(6): 13317-13324. doi: 10.3934/math.2023674
[6]	Weiwen Wan, Rong An . Convergence analysis of Euler and BDF2 grad-div stabilization methods for the time-dependent penetrative convection model. AIMS Mathematics, 2024, 9(1): 453-480. doi: 10.3934/math.2024025
[7]	Shanhao Yuan, Yanqin Liu, Yibin Xu, Qiuping Li, Chao Guo, Yanfeng Shen . Gradient-enhanced fractional physics-informed neural networks for solving forward and inverse problems of the multiterm time-fractional Burger-type equation. AIMS Mathematics, 2024, 9(10): 27418-27437. doi: 10.3934/math.20241332
[8]	Xin Zhao, Xin Liu, Jian Li . Convergence analysis and error estimate of finite element method of a nonlinear fluid-structure interaction problem. AIMS Mathematics, 2020, 5(5): 5240-5260. doi: 10.3934/math.2020337
[9]	Zhichao Fang, Ruixia Du, Hong Li, Yang Liu . A two-grid mixed finite volume element method for nonlinear time fractional reaction-diffusion equations. AIMS Mathematics, 2022, 7(2): 1941-1970. doi: 10.3934/math.2022112
[10]	Muhammad Asim Khan, Norma Alias, Umair Ali . A new fourth-order grouping iterative method for the time fractional sub-diffusion equation having a weak singularity at initial time. AIMS Mathematics, 2023, 8(6): 13725-13746. doi: 10.3934/math.2023697

Abstract

1. Introduction

In this article, we consider the following time-fractional generalized Rosenau-RLW-Burgers equation:

$\begin{equation} u_t-_{0}^{C}\!\!D_t^\alpha u_{xx}+_{0}^{C}\!\!D_t^\beta u_{xxxx}+u_x-u_{xx} +f(u)_x = g(x,t),\ (x,t)\in\Omega\times J, \end{equation}$

(1.1)

with boundary conditions

$\begin{equation} u(x,t) = u_{xx}(x,t) = 0,\ (x,t)\in\partial\Omega\times\bar{J}, \end{equation}$

(1.2)

and initial condition

$\begin{equation} u(x,0) = u_0(x),\ x\in\Omega, \end{equation}$

(1.3)

where $\Omega = (a, b)$ is the spatial domain, $J = (0, T]$ is the time interval with $T\in (0, \infty)$ , and $g(x, t)$ is a known source term function. The nonlinear term $f(u)$ satisfies the assumption condition $|f(u)|\le c_f(u)|u|$ , where $c_f(u)$ is a positive constant on $u$ . $_{0}^{C}\!D_t^\alpha u$ and $_{0}^{C}\!D_t^\beta u$ are both Caputo fractional derivatives with $0 < \alpha, \beta < 1$ . Since $_{0}^{C}\!D_t^\gamma u = \frac{\partial^{\gamma}(u-u_0)}{\partial t^{\gamma}}$ , all of the above Caputo fractional derivatives can be converted into the Riemann-Liouville fractional derivative, note that

$\begin{equation} \frac{\partial^{\gamma} u}{\partial t^{\gamma}} = \frac{1}{\Gamma(1-\gamma)}\frac{\partial}{\partial t}\displaystyle {\int}_0^t\frac{u(x,s)}{(t-s)^{\gamma}}\mathrm{d}s,\; 0 < \gamma < 1. \end{equation}$

(1.4)

Specifically, when $\alpha = 1$ , $\beta = 1$ , (1.1) degenerates into the generalized Rosenau-RLW-Burgers equation which can be seen as the combined system between the generalized Rosenau-RLW equation and the generalized Rosenau-Burgers equation.

The RLW equation, the Rosenau equation, and their combined systems with other equations are significant mathematical and physical equations that effectively describe nonlinear wave behaviors. These equations have become interesting topics in the study of nonlinear dispersion dynamics. Since obtaining analytical solutions for these equations is challenging, studying their numerical methods is paramount. Over the years, there has been extensive research on numerical methods for solving this type of equation. In ^[1], Atouani and Omrani discussed the numerical solution of the Rosenau-RLW (RRLW) equation based on the Galerkin finite element method. In ^[2], He and Pan developed a three-level, linearly implicit finite difference method for solving the generalized Rosenau-Kawahara-RLW equation. In ^[3], Wongsaijai and Poochinapan developed a pseudo-compact finite difference scheme for solving the generalized Rosenau-RLW-Burgers equation. In ^[4], Mouktonglang et al. analyzed a generalized Rosenau-RLW-Burgers equation with periodic initial-boundary value. For more papers on related equations, please refer to ^[5,6,7,8]. It is worth noting that the literature on the fractional generalized Rosenau-RLW-Burgers equation is relatively scarce, and its analytical solution is difficult to obtain. Therefore, we have to consider effective numerical methods such as finite element methods ^[9,10,11,12], finite difference methods ^[13,14,15], finite volume methods ^[16], spectral methods ^[17,18,19], and mixed finite element methods ^[20,21,22]. In addition, the existence of time-fractional derivatives increases the difficulty of studying numerical methods. Therefore, it is crucial to choose an appropriate high-order approximation formula for the fractional derivative to establish a stable numerical scheme for (1.1).

In 1986, Lubich ^[23] proposed the convolution quadrature (CQ) formula for Riemann Liouville fractional operators using the discrete convolution. In ^[24], Chen et al. developed an alternating direction implicit fractional trapezoidal rule type to solve a two-dimensional fractional evolution equation. In ^[25], Jin et al. proposed a corrected approximation formula for high-order BDFs through appropriate initial modifications to discretize fractional evolution equations. Based on the CQ formula, in ^[26], Liu et al. developed the shifted convolution quadrature (SCQ) theory, which extended the CQ formula at $x_{n-\theta}$ and discussed the constraints of parameter $\theta$ . In ^[27], Yin et al. studied the generalized BDF2- $\theta$ with the finite element method for solving the fractional mobile/immobile transport model, and also developed a correction scheme by adding the starting part to restore convergence order. For more related papers, please refer to ^{[28,29,30,31,32,33]}.

In this article, we develop the generalized BDF2- $\theta$ in time combined with the mixed finite element method in space to solve (1.1). The focuses of this article are as follows:

● It is noted that the time-fractional generalized Rosenau-RLW-Burgers equation containing two time-fractional operators is studied.

● The stability of the time-fractional generalized Rosenau-RLW-Burgers equation (1.1) based on the mixed finite element method is given.

● Based on a comprehensive analysis of some numerical examples, the numerical method's feasibility and effectiveness have been extensively validated. Specifically, the issue of decreasing the convergence rate of nonsmooth solutions is solved by adding correction terms.

The structure of this article is as follows: In Section 2, the generalized BDF2- $\theta$ is introduced, and the fully discrete mixed finite element scheme is provided. In Section 3, the existence and uniqueness theorem for the fully discrete mixed finite element scheme is given. In Section 4, the stability of the scheme is proved. In Section 5, some numerical examples with smooth and nonsmooth solutions based on the discrete scheme are presented. In Section 6, some conclusions are given.

2. Numerical scheme

In this section, we present the fully discrete mixed finite element scheme for (1.1) in space, which combines the generalized BDF2- $\theta$ in time. The generalized BDF2- $\theta$ with the starting part is introduced in ^[27]. Further, we divide the time interval $[0, T]$ into $0 = t_0 < t_1 < \cdots < t_{N-1} < t_{N} = T$ , and let $t_{n} = n\tau\; (n = 1, 2, \cdots, N)$ , where $\tau$ is time step length size and $N$ is a positive integer.

For the convenience of research, set $\hat{u}: = u-u_0$ , and assume that $\hat{u}$ has the following form:

$\begin{equation} \hat{u}(x,t) = \hat{u}_1(x,t)+\hat{u}_2(x,t): = \sum\limits_{j = 1}^{\kappa}c_jt^{\sigma_j}+t^{\sigma_{\kappa+1}}\phi(x,t), \end{equation}$

(2.1)

where $c_j = c(x)$ , $1 < \sigma_1 < \sigma_2 < \cdots < \sigma_{\kappa} < \sigma_{\kappa+1}$ and $\phi(x, t)$ is sufficiently differentiable with respect to $t$ .

Using $\hat{u}: = u-u_0$ , we can write (1.1)–(1.3) as

$\begin{equation} \hat{u}_t-\frac{\partial^{\alpha} \hat{u}_{xx}}{\partial t^{\alpha}}+\frac{\partial^{\beta} \hat{u}_{xxxx}}{\partial t^{\beta}}+\hat{u}_x-\hat{u}_{xx} +f(\hat{u})_x = \hat{g}(x,t),\; (x,t)\in\Omega\times J, \end{equation}$

(2.2)

with boundary conditions

$\begin{equation} \hat{u}(x,t) = \hat{u}_{xx}(x,t) = 0,\; (x,t)\in\partial\Omega\times\bar{J}, \end{equation}$

(2.3)

and initial condition

$\begin{equation} \hat{u}(x,0) = 0,\; x\in\Omega, \end{equation}$

(2.4)

where $\hat{g}(x, t) = g(x, t)+(u_0)_x-(u_0)_{xx}$ .

Now, we introduce an auxiliary variable $q = \hat{u}_{xx}$ to obtain the following coupled system:

$\begin{equation} \hat{u}_t-\frac{\partial^{\alpha} \hat{u}_{xx}}{\partial t^{\alpha}}+\frac{\partial^{\beta} q_{xx}}{\partial t^{\beta}}+\hat{u}_x-\hat{u}_{xx} +f(\hat{u})_x = \hat{g}(x,t), \end{equation}$

(2.5)

and

$\begin{equation} q = \hat{u}_{xx}. \end{equation}$

(2.6)

Multiplying (2.5) and (2.6) by $v \in H_0^1$ and $w \in H_0^1$ , respectively, integrating the result equations, and using integration by parts, we obtain the following weak form:

$\begin{equation} (\hat{u}_t,v)+(\frac{\partial^{\alpha} \hat{u}_{x}}{\partial t^{\alpha}},v_x)-(\frac{\partial^{\beta} q_{x}}{\partial t^{\beta}},v_x)-(\hat{u},v_x)+(\hat{u}_{x},v_x)-(f(\hat{u}),v_x) = (\hat{g},v), \; \forall v\in H_0^1, \end{equation}$

(2.7)

and

$\begin{equation} (q,w)+(\hat{u}_{x},w_x) = 0,\; \forall w\in H_0^1. \end{equation}$

(2.8)

To provide the fully discrete numerical scheme, we first introduce the relevant formulas and lemmas for the generalized BDF2- $\theta$ .

For smooth functions $\hat{u}$ and $q$ in $[0, T]$ , we let $\hat{u}^n = \hat{u}(\cdot, t_n)$ , $q^n = (\cdot, t_n)$ . The approximation formula for the Riemann-Liouville fractional derivative at time $t_{n-\theta}$ with the generalized BDF2- $\theta$ is

$\begin{equation} \begin{split} \frac{\partial^{\gamma} \hat{u}^{n-\theta}}{\partial t^{\gamma}}& = \tau^{-\gamma}\sum\limits_{j = 0}^{n}\omega^{(\gamma)}_j \hat{u}^{n-j}+\tau^{-\gamma}\sum\limits_{j = 1}^{\kappa}\omega^{(\gamma)}_{n,j} \hat{u}^{j}+R^{n-\theta}_\gamma\\ &: = \Psi_\tau^{\gamma,n}\hat{u}+S_{\tau,\kappa}^{\gamma,n}\hat{u}+R^{n-\theta}_\gamma, \end{split} \end{equation}$

(2.9)

where $|R^{n-\theta}_\gamma|\leq C\tau^2$ .

The discrete convolution part is denoted as

$\begin{equation} \Psi_\tau^{\gamma,n}\hat{u}: = \tau^{-\gamma}\sum\limits_{j = 0}^{n}\omega^{(\gamma)}_j \hat{u}^{n-j}, \end{equation}$

(2.10)

and the starting part is

$\begin{equation} S_{\tau,\kappa}^{\gamma,n}\hat{u}: = \tau^{-\gamma}\sum\limits_{j = 1}^{\kappa}\omega^{(\gamma)}_{n,j} \hat{u}^{j}. \end{equation}$

(2.11)

The convolution weights $\{\omega^{(\gamma)}_{j}\}^{\infty}_{j = 0}$ in (2.10) are generated by the following generating function:

$\begin{equation} \omega^{(\gamma)}(\xi ) = \left(\frac{3\gamma-2\theta}{2\gamma} -\frac{2\gamma-2\theta}{\gamma}\xi+\frac{\gamma-2\theta}{2\gamma}\xi^2 \right)^\gamma. \end{equation}$

(2.12)

Lemma 2.1. ^[27] We give the convolution weights $\{\omega^{(\gamma)}_j\}_{j = 0}^{\infty}$ of the generalized BDF2- $\theta$ as follows:

$\begin{equation} \begin{split} &\omega_0^{(\gamma)} = \left(\frac{3\gamma-2\theta}{2\gamma}\right)^{\gamma},\quad \omega_1^{(\gamma)} = 2(\theta-\gamma)\left(\frac{2\gamma}{3\gamma-2\theta}\right)^{1-\gamma},\\ &\omega_j^{(\gamma)} = \frac{2\gamma}{j(3\gamma-2\theta)}\left[2(\gamma-\theta)\left(\frac{j-1}{\gamma}-1\right)\omega_{j-1}^{(\gamma)}+(\gamma-2\theta)\left(1-\frac{j-2}{2\gamma}\right)\omega_{j-2}^{(\gamma)}\right],\quad j\geq2. \end{split} \end{equation}$

(2.13)

Lemma 2.2. ^[27] The starting weights $\{\omega^{(\gamma)}_{n, j}\}_{j = 1}^{\kappa}$ of the generalized BDF2- $\theta$ are given as the following:

$\begin{equation} \begin{split} \sum\limits_{j = 1}^{\kappa}\omega^{(\gamma)}_{n,j}j^{\ell} = \frac{\Gamma(\ell+1)}{\Gamma(\ell-\gamma+1)}(n-\theta)^{\ell-\gamma}-\sum\limits_{j = 1}^{n}\omega^{(\gamma)}_{n-j}j^{\ell},\quad \ell = \sigma_1,\sigma_2,\cdots,\sigma_{\kappa}. \end{split} \end{equation}$

(2.14)

Lemma 2.3. ^[12,15] For $\hat{u}\in C^4[0, \pi]$ , the following two approximate formulas at $t_{n-\theta}$ hold:

$\begin{equation} \begin{split} g(t_{n-\theta})& = g^{n-\theta}+O(\tau^2),\\ f(\hat{u}(t_{n-\theta}))& = f(\hat{u}^{n-\theta})+O(\tau^2), \end{split} \end{equation}$

(2.15)

where $g^{n-\theta}: = (1-\theta)g^{n}+\theta g^{n-1}$ and $f(\hat{u}^{n-\theta}): = (2-\theta)f(\hat{u}^{n-1})-(1-\theta)f(\hat{u}^{n-2})$ .

Next, we have the following approximate formula:

$\begin{equation} \begin{split} \hat{u}(t_{n-\theta})& = \hat{u}^{n-\theta}+S_{\tau,\kappa}^{0,n}\hat{u}+O(\tau^2)\\ &: = (1-\theta)\hat{u}^{n}+\theta \hat{u}^{n-1}+S_{\tau,\kappa}^{0,n}\hat{u}+O(\tau^2). \end{split} \end{equation}$

(2.16)

Without considering the starting part, we can obtain the weak form of (2.5) and (2.6) at $t_{n-\theta}$ :

$\begin{equation} \begin{split} &(\Psi_{\tau}^{1,n} \hat{u},v)+(\Psi_{\tau}^{\alpha,n} \hat{u}_{x},v_x)-(\Psi_{\tau}^{\beta,n}q_{x},v_x)-(\hat{u}^{n-\theta},v_x)+(\hat{u}^{n-\theta}_{x},v_x) \\ = &(f(\hat{u}^{n-\theta}),v_x)+(\hat{g}^{n-\theta},v)-(R_1^{n-\theta},v), \end{split} \end{equation}$

(2.17)

and

$\begin{equation} (q^{n-\theta},w)+(\hat{u}^{n-\theta}_{x},w_x) = -(R_2^{n-\theta},w), \end{equation}$

(2.18)

where $R_1^{n-\theta} = O(\tau^2)$ and $R_2^{n-\theta} = O(\tau^2)$ .

To establish the fully discrete mixed finite element scheme, we introduce the following finite element space:

$V_h = \{v_h|v_h\in H_0^1,v_h|_{I_i}\in P_k(I_i), \; \forall I_i\in \mathcal{T} _h,k\geq 1 \},$

where $\mathcal{T}_h$ is a subdivision of $\bar{\Omega} = [a, b]$ into $M$ subintervals $I_i = [x_{i-1}, x_{i}]$ , with $h_i = x_{i}-x_{i-1}$ , $h = \mathop{\max}\limits_{1\leq i\leq M}h_i$ , and $P_k(I_i)$ represent the polynomials with a degree less than or equal to $k$ in $I_i$ .

Next, we provide linear basis functions $\{\varphi_i\}_{i = 1}^{M}$ of finite element space $V_h$ as follows:

$\begin{equation} \begin{aligned} \varphi_i(x) = \left\{\begin{matrix} 1+\frac{x-x_i}{h_i},& x\in I_i,\\ 1-\frac{x-x_i}{h_{i+1}}, & x\in I_{i+1},\\ 0, & \text{others}, \end{matrix}\right. \end{aligned} \end{equation}$

(2.19)

$\begin{equation} \begin{aligned} \varphi_M(x) = \left\{\begin{matrix} 1+\frac{x-x_M}{h_M},& x\in I_M,\\ 0, & \text{others}. \end{matrix}\right. \end{aligned} \end{equation}$

(2.20)

Based on the above finite element space, we find $\{U^{n-\theta}, Q^{n-\theta}\}\in V_h\times V_h$ satisfying

$\begin{equation} \begin{split} &(\Psi_{\tau}^{1,n} U,V)+(\Psi_{\tau}^{\alpha,n} U_{x},V_x)-(\Psi_{\tau}^{\beta,n}Q_{x},V_x)-(U^{n-\theta},V_x)+(U_{x}^{n-\theta },V_x)\\ = &(f(U^{n-\theta}),V_x) +(\hat{g}^{n-\theta},V),\; \forall V\in V_h, \end{split} \end{equation}$

(2.21)

and

$\begin{equation} (Q^{n-\theta},W)+(U_{x}^{n-\theta},W_x) = 0,\; \forall W\in V_h . \end{equation}$

(2.22)

3. Existence and uniqueness of numerical solution

Theorem 3.1. The solution of the fully discrete mixed finite element scheme (2.21) and (2.22) is uniquely solvable.

Proof. Taking basis functions $\{\varphi_i\}_{i = 1}^{M}$ of finite element space $V_h$ , we have

$\begin{equation} \begin{split} U^{n} = \sum\limits_{i = 1}^{M}u_i^{n}\varphi_i,\quad Q^{n} = \sum\limits_{i = 1}^{M}q_i^{n}\varphi_i. \end{split} \end{equation}$

(3.1)

Taking $V = \varphi_j$ and $W = \varphi_j$ from (2.21) and (2.22), we have

$\begin{equation} \begin{split} &\tau^{-1}\omega_0^{(1)}A \mathbf{U^n}+\tau^{-\alpha}\omega_0^{(\alpha)}B \mathbf{U^n}+(1-\theta)B\mathbf{U^n}-(1-\theta)C\mathbf{U^n}-\tau^{-\beta}\omega_0^{(\beta)}B\mathbf{Q^n}\\ = &\mathbf{F}^{n-\theta}+\mathbf{G}^{n-\theta}-\tau^{-1}\sum\limits_{k = 1}^{n} \omega_{k}^{(1)}A \mathbf{U^{n-k}}-\tau^{-\alpha}\sum\limits_{k = 1}^{n} \omega_{k}^{(\alpha)}B \mathbf{U^{n-k}}\\ &-\theta B \mathbf{U^{n-1}}+\theta C \mathbf{U^{n-1}}+\tau^{-\beta}\sum\limits_{k = 1}^{n} \omega_{k}^{(\beta)}B \mathbf{Q^{n-k}}, \end{split} \end{equation}$

(3.2)

and

$\begin{equation} \begin{split} &(1-\theta)B\mathbf{U^{n}}+(1-\theta)A\mathbf{Q^{n}} = -\theta B\mathbf{U^{n}}-\theta A\mathbf{Q^{n}}, \end{split} \end{equation}$

(3.3)

where

$\begin{align*} &A = \left[(\varphi_i,\varphi_j)\right]^T_{1\le i,j\le M},\; B = \left[(\varphi_{ix},\varphi_{jx})\right]^T_{1\le i,j\le M},\; C = \left[(\varphi_{i},\varphi_{jx})\right]^T_{1\le i,j\le M},\\ &\mathbf{F^{n-\theta}} = \left[\left(f(U^{n-\theta}),\varphi_{1x}\right),\cdots,\left(f(U^{n-\theta}),\varphi_{Mx}\right)\right]^T,\; \mathbf{G^{n-\theta}} = \left[\left(g^{n-\theta},\varphi_{1}\right),\cdots,\left(g^{n-\theta},\varphi_{M}\right)\right]^T. \end{align*}$

Obviously, $A$ and $B$ are symmetric and positive definite. Further, processing the boundary and simplifying the right-hand term, we have

$\begin{equation} \left(\tau^{-1}\omega_0^{(1)}\widetilde{A}+\tau^{-\alpha}\omega_{0}^{(\alpha)}\widetilde{B}+(1-\theta)\widetilde{B}-(1-\theta)\widetilde{C}\right)\mathbf{U}^{n}-\tau^{-\beta}\omega_0^{(\beta)}\widetilde{B}\mathbf{Q}^{n} = \mathbf{H}_1^n, \end{equation}$

(3.4)

and

$\begin{equation} (1-\theta)\widetilde{B}\mathbf{U}^n+(1-\theta)\widetilde{A}\mathbf{Q}^n = \mathbf{H}_2^n, \end{equation}$

(3.5)

where

$\begin{align*} \mathbf{H}_1^n = &\mathbf{F}^{n-\theta}+\mathbf{G}^{n-\theta}-\tau^{-1}\sum\limits_{k = 1}^{n} \omega_{k}^{(1)}A \mathbf{U^{n-k}}-\tau^{-\alpha}\sum\limits_{k = 1}^{n} \omega_{k}^{(\alpha)}B \mathbf{U^{n-k}}-\theta B \mathbf{U^{n-1}}\\ &+\theta C \mathbf{U^{n-1}}+\tau^{-\beta}\sum\limits_{k = 1}^{n} \omega_{k}^{(\beta)}B \mathbf{Q^{n-k}},\\ \mathbf{H}_2^n = &-\theta B\mathbf{U^{n}}-\theta A\mathbf{Q^{n}}. \end{align*}$

Multiplying (3.4) by $\tau \widetilde{A}^{-1}$ , we have

$\begin{equation} \begin{split} \left(\omega_0^{(1)}E+\tau^{1-\alpha}\omega_{0}^{(\alpha)}\widetilde{A}^{-1}\widetilde{B}+\tau(1-\theta)\widetilde{A}^{-1}\widetilde{B}-\tau(1-\theta)\widetilde{A}^{-1}\widetilde{C}\right)\mathbf{U}^{n} -\tau^{1-\beta}\omega_0^{(\beta)}\widetilde{A}^{-1}\widetilde{B}\mathbf{Q}^{n} = \tau\widetilde{A}^{-1}\mathbf{H}_1^n. \end{split} \end{equation}$

(3.6)

Further, rewrite (3.5) as

$\begin{equation} \begin{split} \mathbf{Q}^{n} = \mathbf{H}_3^n, \end{split} \end{equation}$

(3.7)

where $\mathbf{H}_3^n = (1-\theta)^{-1}\widetilde{A}^{-1}\mathbf{H}_2^n-\widetilde{A}^{-1}\widetilde{B}\mathbf{U}^{n}$ .

Substitute (3.7) into (3.6) to obtain

$\begin{equation} \begin{split} &\mathbf{K}\mathbf{U}^{n} = \mathbf{H}_4^n, \end{split} \end{equation}$

(3.8)

where

$\mathbf{K} = \omega_0^{(1)}E+\tau^{1-\alpha}\omega_{0}^{(\alpha)}\widetilde{A}^{-1}\widetilde{B}+\tau(1-\theta)\widetilde{A}^{-1}\widetilde{B} -\tau(1-\theta)\widetilde{A}^{-1}\widetilde{C}+\tau^{1-\beta}\omega_0^{(\beta)}\widetilde{A}^{-1}\widetilde{B}\widetilde{A}^{-1}\widetilde{B},$

$\mathbf{H}_4^n = \tau \widetilde{A}^{-1}\mathbf{H}_1^n+\tau^{1-\beta}(1-\theta)^{-1}\omega_0^{(\beta)}\widetilde{A}^{-1}\widetilde{B}\widetilde{A}^{-1}\mathbf{H}_2^n.$

It is easy to see that (3.7) and (3.8) are equivalent to (3.4) and (3.5). Due to $\tau$ being small enough and $E$ being an identity matrix, the matrix $\mathbf{K}$ is invertible. Additionally, since $U^k\; (k = 0, 1, \cdots, n-1)$ is known, after multiple iterations, (3.7) and (3.8) have a unique solution. □

Remark 3.1. Since we introduce the auxiliary variable $q = \hat{u}_{xx}$ to transform (2.2) into a first-order system (2.5) and (2.6), according to ^[34,35], the mixed finite element scheme (2.21) and (2.22) do not need to satisfy the LBB condition. In ^[36], the LBB condition is a condition for the problem to be well posed. From this perspective, typically satisfying the LBB condition is to obtain the existence and uniqueness of a solution. Although the mixed finite element scheme in this article does not need to satisfy the LBB condition, it still satisfies the existence and uniqueness of a solution.

4. Stability

Lemma 4.1. ^[12,14] For $\forall U^m\in V_h$ , satisfying $U^m = 0\; (m < 0)$ , we have

$(\Psi_t^{1,m} U,U^{m-\theta})\ge \frac{1}{4\tau}(\mathbb{H}[U^m]-\mathbb{H}[U^{m-1}]),\ m\ge 1,$

where

$\mathbb{H}[U^m] = (3-2\theta)\|U^{m}\|^2-(1-2\theta)\|U^{m-1}\|^2+(2-\theta)(1-2\theta)\|U^m-U^{m-1}\|^2,$

and

$\mathbb{H}[U^m]\ge\frac{1}{1-\theta}\|U^m\|^2,\ m\ge1.$

Lemma 4.2. ^[27] } {For any vector $(v^0, v^1, \cdots, v^{n-1})\in \mathbb{R}^n$ , defining $\{\omega_k^{(\gamma)}\}_{k = 0}^{\infty}\; (0 < \gamma < 1)$ be a sequence of coefficients of the generating function $\omega^{(\gamma)}(\xi)$ in (2.12) and $0\le\theta\le\min\{\gamma, \frac{1}{2}\}$ , we have

$\sum\limits_{m = 1}^{n-1}v^m\sum\limits_{k = 1}^{m}\omega_{m-k}^{(\gamma)} v^k\ge0,\ n\ge1.$

Theorem 4.1. Let $u^n_h = U^n+\bar{u}_h^0$ , where $\bar{u}_h^0$ is an approximation of $u_0$ , the following stability of the fully discrete scheme (2.21) and (2.22) holds:

$\begin{equation} \|u_h^L\|^2\ \le\ C\left(\|\bar{u}_h^0 \|^2+\tau\sum\limits_{n = 1}^{L}\|g^{n-\theta} \|^2\right),\ 1\le L \le N, \end{equation}$

(4.1)

where $C$ is a positive constant independent of $h$ and $\tau$ .

Proof. Taking $V = U^{n-\theta}$ , $W = \Psi_{\tau}^{\beta, n}Q$ , (2.21) and (2.22) can be written as

$\begin{equation} \begin{split} &(\Psi_{\tau}^{1,n} U,U^{n-\theta})+(\Psi_{\tau}^{\alpha,n} U_{x},U^{n-\theta}_x)-(\Psi_{\tau}^{\beta,n}Q_{x},U^{n-\theta}_x)+\|U_{x}^{n-\theta }\|^2\\ = &(U^{n-\theta},U^{n-\theta}_x)+(f(U^{n-\theta}),U^{n-\theta}_x)+(\hat{g}^{n-\theta},U^{n-\theta}), \end{split} \end{equation}$

(4.2)

and

$\begin{equation} (Q^{n-\theta},\Psi_{\tau}^{\beta,n}Q)+(U^{n-\theta}_{x},\Psi_{\tau}^{\beta,n}Q_x) = 0. \end{equation}$

(4.3)

Adding (4.2) and (4.3), we have

$\begin{equation} \begin{split} &(\Psi_{\tau}^{1,n} U,U^{n-\theta})+(\Psi_{\tau}^{\alpha,n} U_{x},U^{n-\theta}_x)+(Q^{n-\theta},\Psi_{\tau}^{\beta,n}Q)+\|U_{x}^{n-\theta }\|^2\\ = &(U^{n-\theta},U^{n-\theta}_x)+(f(U^{n-\theta}),U^{n-\theta}_x)+(\hat{g}^{n-\theta},U^{n-\theta}). \end{split} \end{equation}$

(4.4)

Using Lemma 4.1, we obtain

$\begin{equation} \begin{split} &\frac{1}{4\tau}(\mathbb{H}[U^n]-\mathbb{H}[U^{n-1}])+(\Psi_{\tau}^{\alpha,n} U_{x},U^{n-\theta}_x)+(Q^{n-\theta},\Psi_{\tau}^{\beta,n}Q)+\|U_{x}^{n-\theta }\|^2\\ \le&(U^{n-\theta},U^{n-\theta}_x)+(f(U^{n-\theta}),U^{n-\theta}_x)+(\hat{g}^{n-\theta},U^{n-\theta}). \end{split} \end{equation}$

(4.5)

Multiply (4.5) by $4\tau$ and sum it with respect to $n$ from $1$ to $L$ to get

$\begin{equation} \begin{split} &\mathbb{H}[U^L]-\mathbb{H}[U^{0}]+ 4\tau\sum\limits_{n = 1}^{L}(\Psi_t^{\alpha,n} U_{x},U^{n-\theta}_x)+ 4\tau\sum\limits_{n = 1}^{L}(Q^{n-\theta},\Psi_{\tau}^{\beta,n}Q)+ 4\tau\sum\limits_{n = 1}^{L}\|U_{x}^{n-\theta }\|^2\\ \le&4\tau\left(\sum\limits_{n = 1}^{L}(U^{n-\theta},U^{n-\theta}_x)+\sum\limits_{n = 1}^{L}(f(U^{n-\theta}),U^{n-\theta}_x)+\sum\limits_{n = 1}^{L}(\hat{g}^{n-\theta},U^{n-\theta})\right). \end{split} \end{equation}$

(4.6)

By the Hölder inequality and Young inequality, the three terms on the right-hand side of (4.6) can be expanded to

$\begin{equation} \sum\limits_{n = 1}^{L}(U^{n-\theta},U^{n-\theta}_x)\le\frac{1}{2}\sum\limits_{n = 1}^{L}\|U^{n-\theta}\|^2+\frac{1}{2}\sum\limits_{n = 1}^{L}\|U_{x}^{n-\theta }\|^2, \end{equation}$

(4.7)

$\begin{equation} \begin{split} \sum\limits_{n = 1}^{L}(f(U^{n-\theta}),U^{n-\theta}_x) \le&\sum\limits_{n = 1}^{L}\|c_f(U^{n-\theta})\|_{\infty}\|U^{n-\theta}\|\|U^{n-\theta}_x\| \\ \le& C\sum\limits_{n = 1}^{L}\|U^{n-\theta}\|^2+\frac{1}{2}\sum\limits_{n = 1}^{L}\|U_{x}^{n-\theta }\|^2, \end{split} \end{equation}$

(4.8)

$\begin{equation} \sum\limits_{n = 1}^{L}(\hat{g}^{n-\theta},U^{n-\theta})\le\frac{1}{2}\sum\limits_{n = 1}^{L}\|\hat{g}^{n-\theta}\|^2 +\frac{1}{2}\sum\limits_{n = 1}^{L}\|U^{n-\theta}\|^2, \end{equation}$

(4.9)

where we use the bounded condition $\|c_f(U^{n-\theta})\|_{\infty}\leq C$ .

Substituting (4.7)–(4.9) into (4.6), we arrive at

$\begin{equation} \begin{split} & \mathbb{H}[U^L]-\mathbb{H}[U^{0}]+ 4\tau\sum\limits_{n = 1}^{L}(\Psi_t^{\alpha,n} U_{x},U^{n-\theta}_x)+ 4\tau\sum\limits_{n = 1}^{L}(Q^{n-\theta},\Psi_{\tau}^{\beta,n}Q)\\ \le& C\tau \left(\sum\limits_{n = 1}^{L}\|\hat{g}^{n-\theta}\|^2+\sum\limits_{n = 1}^{L}\|U^{n-\theta}\|^2\right). \end{split} \end{equation}$

(4.10)

In what follows, using Lemmas 4.1 and 4.2 and the Gronwall inequality, we have

$\begin{equation} \|U^L\|^2-\|U^0\|^2\le C\tau\sum\limits_{n = 1}^{L}\|\hat{g}^{n-\theta}\|^2. \end{equation}$

(4.11)

Since $U^0 = 0$ , we obtain

$\begin{equation} \|U^L\|^2\le C\tau\sum\limits_{n = 1}^{L}\|\hat{g}^{n-\theta}\|^2. \end{equation}$

(4.12)

Noting that $U^L = u^L_h-\bar{u}_h^0$ and using the triangle inequality, the conclusion of this theorem is derived. □

5. Numerical results

In this section, we present numerical simulation results for both smooth and nonsmooth solutions to verify the effectiveness of the numerical scheme. Next, we set the nonlinear term $f(u) = u^2$ , the spatial domain $\Omega = (0, 1)$ , and the time interval $J = (0, 1]$ .

Example 5.1 The exact solution is $u(x, t) = t^{2}\sin(2\pi x)$ satisfying $u(x, 0) = 0$ , and the known source function $g(x, t)$ is given by

$\begin{equation} g(x,t) = \sin(2\pi x)\left(2t+\frac{8\pi ^2t^{2-\alpha}}{\Gamma(3-\alpha)}+\frac{32\pi^4t^{2-\beta}}{\Gamma(3-\beta)}+4\pi^2t^2\right)+2\pi t^2\cos(2\pi x)+2\pi t^4\sin(4\pi x ). \end{equation}$

(5.1)

In , fixing $\tau = 1/1000$ and choosing $h = 1/10, 1/20, 1/40, 1/80$ , we provide the $L^2$ -errors and the spatial convergence rates for $u$ and $q$ with different parameters $\alpha$ , $\beta$ , and $\theta$ , where $\theta\le\min\{\alpha, \beta, \frac{1}{2}\}$ . Similarly, in , taking $h = 1/1000$ , we calculate the $L^2$ -errors and the time convergence rates with $\tau = 1/10, 1/20, 1/40, 1/80$ . From and , one can see that the convergence rates in both space and time are close to 2 when the exact solution is smooth. In , if $\theta > \min\{\alpha, \beta, \frac{1}{2}\}$ , the convergence accuracy will be unstable, which verifies the range of $\theta$ values from a numerical perspective. To observe the effect of numerical simulation more clearly, we provide the comparison images between numerical solutions and exact solutions. In , we show distinct comparison images of the numerical solutions of $u_h$ and $q_h$ and the exact solutions of $u$ and $q$ with $\tau = 1/1000$ , $h = 1/80$ , $\alpha = 0.2$ , $\beta = 0.8$ , and $\theta = 0.2$ .

Table 1. Spatial convergence results with

$\tau = 1/1000$ .

$\alpha$	$\beta$	$\theta$	$h$	$\\|u_h-u\\|$	Rate	$\\|q_h-q\\|$	Rate
			1/10	2.2165E-02	-	2.6449E-02	-
		0.2	1/20	5.6375E-03	1.9752	6.1401E-03	2.1069
			1/40	1.4151E-03	1.9941	1.5121E-03	2.0217
			1/80	3.5399E-04	1.9992	3.8250E-04	1.9830
			1/10	2.2165E-02	-	2.6470E-02	-
0.2	0.8	-0.5	1/20	5.6369E-03	1.9753	6.1607E-03	2.1032
			1/40	1.4146E-03	1.9945	1.5327E-03	2.0070
			1/80	3.5346E-04	2.0008	4.0308E-04	1.9269
			1/10	2.2164E-02	-	2.6490E-02	-
		-1	1/20	5.6364E-03	1.9754	6.1810E-03	2.0996
			1/40	1.4141E-03	1.9949	1.5530E-03	1.9928
			1/80	3.5293E-04	2.0024	4.2346E-04	1.8747
			1/10	2.1828E-02	-	4.0463E-02	-
		0.5	1/20	5.5499E-03	1.9756	9.6844E-03	2.0629
			1/40	1.3932E-03	1.9941	2.3964E-03	2.0148
			1/80	3.4861E-04	1.9987	5.9910E-04	2.0000
			1/10	2.1828E-02	-	4.0465E-02	-
0.5	0.5	0.2	1/20	5.5499E-03	1.9757	9.6868E-03	2.0626
			1/40	1.3931E-03	1.9941	2.3988E-03	2.0137
			1/80	3.4854E-04	1.9989	6.0151E-04	1.9956
			1/10	2.1826E-02	-	4.0523E-02	-
		-1	1/20	5.5484E-03	1.9759	9.7445E-03	2.0561
			1/40	1.3916E-03	1.9953	2.4564E-03	1.9880
			1/80	3.4706E-04	2.0035	6.5921E-04	1.8977
			1/10	2.1399E-02	-	5.8275E-02	-
		0.2	1/20	5.4386E-03	1.9763	1.4195E-02	2.0375
			1/40	1.3651E-03	1.9943	3.5279E-03	2.0085
			1/80	3.4156E-04	1.9988	8.8248E-04	1.9992
			1/10	2.1399E-02	-	5.8276E-02	-
0.8	0.2	0	1/20	5.4386E-03	1.9763	1.4196E-02	2.0374
			1/40	1.3650E-03	1.9943	3.5290E-03	2.0082
			1/80	3.4153E-04	1.9989	8.8360E-04	1.9978
			1/10	2.1396E-02	-	5.8410E-02	-
		-1	1/20	5.4352E-03	1.9769	1.4329E-02	2.0272
			1/40	1.3616E-03	1.9970	3.6619E-03	1.9683
			1/80	3.3812E-04	2.0097	1.0167E-03	1.8487

| Show Table

DownLoad: CSV

Table 2. Time convergence results with

$h = 1/1000$ .

$\alpha$	$\beta$	$\theta$	$\tau$	$\\|u_h-u\\|$	Rate	$\\|q_h-q\\|$	Rate
			1/10	1.9614E-03	-	7.7510E-02	-
		0.2	1/20	5.0017E-04	1.9714	1.9814E-02	1.9679
			1/40	1.2703E-04	1.9773	5.0533E-03	1.9712
			1/80	3.2128E-05	1.9832	1.2867E-03	1.9736
			1/10	7.2565E-03	-	2.8650E-01	-
0.2	0.8	-0.5	1/20	1.8309E-03	1.9867	7.2335E-02	1.9858
			1/40	4.6032E-04	1.9919	1.8206E-02	1.9903
			1/80	1.1551E-04	1.9946	4.5778E-03	1.9917
			1/10	1.2197E-02	-	4.8151E-01	-
		-1	1/20	3.1215E-03	1.9662	1.2329E-01	1.9655
			1/40	7.8542E-04	1.9907	3.1091E-02	1.9875
			1/80	1.9579E-04	2.0042	7.8135E-03	1.9924
			1/10	5.3041E-04	-	2.1042E-02	-
		0.5	1/20	1.3386E-04	1.9863	5.3622E-03	1.9724
			1/40	3.3676E-05	1.9910	1.3637E-03	1.9753
			1/80	8.4582E-06	1.9933	3.4761E-04	1.9720
			1/10	1.1457E-03	-	4.5326E-02	-
0.5	0.5	0.2	1/20	2.8884E-04	1.9879	1.1461E-02	1.9836
			1/40	7.2679E-05	1.9907	2.8911E-03	1.9871
			1/80	1.8260E-05	1.9929	7.2972E-04	1.9862
			1/10	1.5622E-02	-	6.1668E-01	-
		-1	1/20	4.0111E-03	1.9615	1.5838E-01	1.9611
			1/40	1.0095E-03	1.9904	3.9868E-02	1.9901
			1/80	2.5362E-04	1.9929	1.0017E-02	1.9928
			1/10	5.2861E-04	-	2.0885E-02	-
		0.5	1/20	1.3465E-04	1.9730	5.3245E-03	1.9717
			1/40	3.4107E-05	1.9811	1.3530E-03	1.9765
			1/80	8.5857E-06	1.9901	3.4270E-04	1.9812
			1/10	2.2763E-03	-	8.9851E-02	-
0.8	0.5	0	1/20	5.7402E-04	1.9875	2.2660E-02	1.9874
			1/40	1.4460E-04	1.9890	5.7086E-03	1.9889
			1/80	3.6405E-05	1.9899	1.4372E-03	1.9898
			1/10	1.5534E-02	-	6.1313E-01	-
		-1	1/20	3.9902E-03	1.9609	1.5749E-01	1.9609
			1/40	1.0033E-03	1.9917	3.9605E-02	1.9916
			1/80	2.5177E-04	1.9946	9.9391E-03	1.9945

| Show Table

DownLoad: CSV

Table 3. Time convergence results with

$h = 1/1000$ .

$\alpha$	$\beta$	$\theta$	$\tau$	$\\|u_h-u\\|$	Rate	$\\|q_h-q\\|$	Rate
			1/10	2.4519E-03	-	9.6803E-02	-
0.1	0.9	0.11	1/20	6.2095E-04	1.9813	2.4519E-02	1.9811
			1/40	5.2080E-04	0.2538	2.0647E-02	0.2480
			1/80	4.0699E+02	-19.5758	1.6068E+04	-19.5699
			1/10	1.8093E-03	-	7.1425E-02	-
0.5	0.5	0.51	1/20	4.5109E-04	2.0039	1.7808E-02	2.0039
			1/40	2.0018E-04	1.1721	7.8154E-03	1.1881
			1/80	5.1099E-04	-1.3520	2.0090E-02	-1.3621
			1/10	4.8552E-04	-	1.9119E-02	-
0.8	0.2	0.21	1/20	1.2438E-04	1.9647	4.8398E-03	1.9820
			1/40	5.8298E-05	1.0933	2.2123E-03	1.1294
			1/80	2.3759E-02	-8.6708	9.3790E-01	-8.7277

| Show Table

DownLoad: CSV

Figure 1.

$u_h$ ,

$q_h$ and

$u$ ,

$q$ with

$\tau = 1/1000$ ,

$h = 1/80$ ,

$\alpha = 0.2$ ,

$\beta = 0.8$ ,

$\theta = 0.2$ .

DownLoad: Full-Size Img PowerPoint

Example 5.2 In this example, we consider the case where the nonsmooth solution is taken as $u = (t^{\alpha+\beta}+t^3) \sin(2\pi x)$ , and the known source term $g(x, t)$ is

$\begin{equation} \begin{split} g(x,t) = &\sin(2\pi x)\left[(\alpha+\beta)t^{\alpha+\beta-1}+3t^2+4\pi^2\left(\frac{t^{\beta}\Gamma(\alpha+\beta+1)}{\Gamma(\beta+1)}+\frac{6t^{3-\alpha}}{\Gamma(4-\alpha)}\right)\right]\\ &+\sin(2\pi x)\left[16\pi^4\left(\frac{t^{\alpha}\Gamma(\alpha+\beta+1)}{\Gamma(\alpha+1)}+\frac{6t^{3-\beta}}{\Gamma(4-\beta)}\right)+4\pi^2(t^{\alpha+\beta}+t^3)\right]\\ &+2\pi (t^{\alpha+\beta}+t^3)\cos(2\pi x)+2\pi(t^{\alpha+\beta} +t^3)^2\sin(4\pi x ). \end{split} \end{equation}$

(5.2)

presents the $L^2$ -errors and the spatial convergence rates of $u$ and $q$ before and after adding the starting parts with $h = 1/10, 1/20, 1/40, 1/80$ , $\tau = 1/2000$ , where Error_o denotes the error before adding the starting parts and Error_c denotes the error after adding the starting parts.

Table 4. Spatial convergence results with

$\alpha = 0.9$ ,

$\beta = 0.2$ ,

$\tau = 1/2000$ .

		$\\|u_h-u\\|$				$\\|q_h-q\\|$
$\theta$	$h$	Error_o	Rate	Error_c	Rate	Error_o	Rate	Error_c	Rate
	1/10	4.2694E-02	-	4.2693E-02	-	1.2162E-01	-	1.2163E-01	-
0.2	1/20	1.0850E-02	1.9763	1.0850E-02	1.9763	2.9675E-02	2.0351	2.9679E-02	2.0349
	1/40	2.7235E-03	1.9942	2.7234E-03	1.9942	7.3708E-03	2.0094	7.3746E-03	2.0088
	1/80	6.8165E-04	1.9984	6.8155E-04	1.9985	1.8361E-03	2.0051	1.8400E-03	2.0029
	1/10	4.2693E-02	-	4.2692E-02	-	1.2165E-01	-	1.2168E-01	-
-0.5	1/20	1.0849E-02	1.9764	1.0849E-02	1.9764	2.9706E-02	2.0340	2.9728E-02	2.0331
	1/40	2.7227E-03	1.9945	2.7221E-03	1.9947	7.4017E-03	2.0048	7.4237E-03	2.0016
	1/80	6.8085E-04	1.9996	6.8028E-04	2.0005	1.8671E-03	1.9871	1.8891E-03	1.9744
	1/10	4.2691E-02	-	4.2690E-02	-	1.2172E-01	-	1.2177E-01	-
-1	1/20	1.0848E-02	1.9766	1.0846E-02	1.9767	2.9776E-02	2.0314	2.9822E-02	2.0297
	1/40	2.7209E-03	1.9952	2.7197E-03	1.9957	7.4714E-03	1.9947	7.5178E-03	1.9880
	1/80	6.7905E-04	2.0025	6.7786E-04	2.0044	1.9368E-03	1.9477	1.9833E-03	1.9224

| Show Table

DownLoad: CSV

The spatial convergence rate is almost unaffected before and after correction, based on a comparison of the data in . In and , we present the $L^2$ -errors and the time convergence rates of $u$ and $q$ before and after adding the starting parts. Without the addition of the starting parts, the time convergence rates are unstable and cannot reach the second-order convergence results computed by the generalized BDF2- $\theta$ . After adding the starting parts, the time convergence rates keep around $2$ , indicating that the starting part plays a major role in correcting the time convergence rates.

Table 5. Spatial convergence results with

$\alpha = 0.5$ ,

$\beta = 0.7$ ,

$\tau = 1/2000$ .

		$\\|u_h-u\\|$				$\\|q_h-q\\|$
$\theta$	$h$	Error_o	Rate	Error_c	Rate	Error_o	Rate	Error_c	Rate
	1/10	4.3949E-02	-	4.3948E-02	-	6.8838E-02	-	6.8891E-02	-
0.5	1/20	1.1177E-02	1.9753	1.1176E-02	1.9754	1.6266E-02	2.0814	1.6318E-02	2.0778
	1/40	2.8070E-03	1.9934	2.8057E-03	1.9940	3.9696E-03	2.0348	4.0219E-03	2.0205
	1/80	7.0358E-04	1.9963	7.0222E-04	1.9984	9.4708E-04	2.0674	9.9935E-04	2.0088
	1/10	4.3949E-02	-	4.3948E-02	-	6.8842E-02	-	6.8897E-02	-
0.2	1/20	1.1177E-02	1.9753	1.1176E-02	1.9754	1.6270E-02	2.0811	1.6324E-02	2.0774
	1/40	2.8069E-03	1.9935	2.8055E-03	1.9940	3.9739E-03	2.0336	4.0279E-03	2.0189
	1/80	7.0346E-04	1.9964	7.0206E-04	1.9986	9.5140E-04	2.0624	1.0054E-03	2.0023
	1/10	4.3948E-02	-	4.3946E-02	-	6.8877E-02	-	6.8974E-02	-
-1	1/20	1.1176E-02	1.9754	1.1174E-02	1.9756	1.6304E-02	2.0788	1.6401E-02	2.0722
	1/40	2.8061E-03	1.9938	2.8035E-03	1.9948	4.0077E-03	2.0244	4.1049E-03	1.9984
	1/80	7.0259E-04	1.9978	7.0007E-04	2.0017	9.8520E-04	2.0243	1.0824E-03	1.9231

| Show Table

DownLoad: CSV

Table 6. Time convergence results with

$\alpha = 0.9$ ,

$\beta = 0.2$ ,

$h = 1/2000$ .

		$\\|u_h-u\\|$				$\\|q_h-q\\|$
$\theta$	$\tau$	Error_o	Rate	Error_c	Rate	Error_o	Rate	Error_c	Rate
	1/10	2.1916E-03	-	4.2694E-02	-	8.6515E-02	-	1.2162E-01	-
0.2	1/20	1.6194E-03	0.4365	1.0850E-02	1.9763	6.3929E-02	0.4365	2.9675E-02	2.0351
	1/40	1.0890E-03	0.5725	2.7235E-03	1.9942	4.2990E-02	0.5725	7.3710E-03	2.0093
	1/80	6.8790E-04	0.6627	6.8165E-04	1.9984	2.7157E-02	0.6627	1.8364E-03	2.0050
	1/10	2.5540E-03	-	4.2693E-02	-	1.0123E-01	-	1.2164E-01	-
0	1/20	1.1111E-03	1.2007	1.0850E-02	1.9763	4.3864E-02	1.2065	2.9692E-02	2.0345
	1/40	7.7616E-04	0.5176	2.7231E-03	1.9944	3.0641E-02	0.5176	7.3878E-03	2.0069
	1/80	5.0234E-04	0.6277	6.8122E-04	1.9990	1.9831E-02	0.6277	1.8531E-03	1.9952
	1/10	2.4652E-02	-	4.2689E-02	-	9.7312E-01	-	1.2182E-01	-
-0.5	1/20	7.1878E-03	1.7781	1.0845E-02	1.9768	2.8376E-01	1.7779	2.9872E-02	2.0279
	1/40	1.9420E-03	1.8880	2.7184E-03	1.9962	7.6702E-02	1.8874	7.5673E-03	1.9809
	1/80	5.5906E-04	1.7965	6.7658E-04	2.0064	2.2071E-02	1.7971	2.0329E-03	1.8962

| Show Table

DownLoad: CSV

Table 7. Time convergence results with

$\alpha = 0.5$ ,

$\beta = 0.7$ ,

$h = 1/2000$ .

		$\\|u_h-u\\|$				$\\|q_h-q\\|$
$\theta$	$\tau$	Error_o	Rate	Error_c	Rate	Error_o	Rate	Error_c	Rate
	1/10	1.1456E-02	-	4.3948E-02	-	4.5228E-01	-	6.8880E-02	-
0.5	1/20	5.0680E-03	1.1767	1.1176E-02	1.9754	2.0008E-01	1.1767	1.6307E-02	2.0786
	1/40	2.2184E-03	1.1919	2.8060E-03	1.9939	8.7577E-02	1.1919	4.0110E-03	2.0235
	1/80	9.6796E-04	1.1965	7.0250E-04	1.9979	3.8213E-02	1.1965	9.8850E-04	2.0207
	1/10	5.4375E-03	-	4.3948E-02	-	2.1466E-01	-	6.8904E-02	-
0.2	1/20	2.5220E-03	1.1084	1.1176E-02	1.9754	9.9562E-02	1.1084	1.6332E-02	2.0769
	1/40	1.1387E-03	1.1472	2.8053E-03	1.9941	4.4952E-02	1.1472	4.0351E-03	2.0170
	1/80	5.0160E-04	1.1828	7.0188E-04	1.9989	1.9802E-02	1.1827	1.0126E-03	1.9946
	1/10	2.8636E-02	-	4.3948E-02	-	1.1304E+00	-	6.8904E-02	-
-1	1/20	7.7097E-03	1.8931	1.1176E-02	1.9754	3.0439E-01	1.8929	1.6332E-02	2.0769
	1/40	1.9098E-03	2.0133	2.8053E-03	1.9941	7.5437E-02	2.0126	4.0351E-03	2.0170
	1/80	6.3574E-04	1.5869	7.0188E-04	1.9989	2.5098E-02	1.5877	1.0126E-03	1.9946

| Show Table

DownLoad: CSV

In , we obtain the comparison images between the numerical solution and the exact solution with $\tau = 1/1000$ , $h = 1/80$ , $\alpha = 0.9$ , $\beta = 0.2$ , and $\theta = 0.2$ . In and , we present the space and time convergence rate images of $u_h$ and $q_h$ under different parameters $\alpha$ , $\beta$ , and $\theta$ . From Figure 4, one can see that the corrected scheme with the starting parts can effectively restore the second-order convergence rate for the nonsmooth problem.

Figure 2.

$u_h$ ,

$q_h$ and

$u$ ,

$q$ with

$\tau = 1/2000$ ,

$h = 1/80$ ,

$\alpha = 0.9$ ,

$\beta = 0.2$ ,

$\theta = 0.2$ .

DownLoad: Full-Size Img PowerPoint

Figure 3. The spatial convergence rates in

$L^2$ -errors with different parameters

$\alpha$ ,

$\beta$ , and

$\theta$ .

DownLoad: Full-Size Img PowerPoint

Figure 4. The time convergence rates in

$L^2$ -errors with different parameters

$\alpha$ ,

$\beta$ , and

$\theta$ .

DownLoad: Full-Size Img PowerPoint

Example 5.3. To better investigate the effect of changes of two fractional parameters $\alpha$ and $\beta$ on the convergence rates, we introduce the numerical example with two nonsmooth terms. Here, we take the nonsmooth solution $u$ with

$u = (t^{1+\alpha}+t^{1+\beta}+t^3) \sin(2\pi x),$

and the known source term

$\begin{equation} \begin{split} g(x,t) = &\sin(2\pi x)\left[(1+\alpha)t^\alpha+(1+\beta)t^\beta+3t^2+4\pi^2\left(t\Gamma(2+\alpha)+\frac{t^{1+\beta-\alpha}\Gamma(2+\beta)}{\Gamma(2+\beta-\alpha)}+\frac{6t^{3-\alpha}}{\Gamma(4-\alpha)}\right)\right]\\ &+\sin(2\pi x)\left[16\pi^4\left(\frac{t^{1+\alpha-\beta}\Gamma(2+\alpha)}{\Gamma(2+\alpha-\beta)}+t\Gamma(2+\beta)+\frac{6t^{3-\beta}}{\Gamma(4-\beta)}\right)+4\pi^2(t^{1+\alpha}+t^{1+\beta}+t^3)\right]\\ &+2\pi (t^{1+\alpha}+t^{1+\beta}+t^3)\cos(2\pi x)+2\pi(t^{1+\alpha}+t^{1+\beta}+t^3)^2\sin(4\pi x ). \end{split} \end{equation}$

(5.3)

In , we provide the errors of $\|u_h-u\|$ and $\|q_h-q\|$ and the spatial convergence rates under different parameters, which indicate that the corrected term hardly affects the spatial convergence rate.

Table 8. Spatial convergence results with

$\alpha = 0.5$ ,

$\beta = 0.6$ ,

$\tau = 1/2000$ .

		$\\|u_h-u\\|$				$\\|q_h-q\\|$
$\theta$	$h$	Error_o	Rate	Error_c	Rate	Error_o	Rate	Error_c	Rate
	1/10	6.5710E-02	-	6.5710E-02	-	1.1335E-01	-	1.1335E-01	-
0.5	1/20	1.6709E-02	1.9755	1.6709E-02	1.9755	2.7037E-02	2.0678	2.7037E-02	2.0678
	1/40	4.1946E-03	1.9940	4.1946E-03	1.9940	6.6773E-03	2.0176	6.6775E-03	2.0175
	1/80	1.0498E-03	1.9984	1.0498E-03	1.9984	1.6615E-03	2.0068	1.6617E-03	2.0066
	1/10	6.5710E-02	-	6.5710E-02	-	1.1336E-01	-	1.1336E-01	-
0.2	1/20	1.6708E-02	1.9755	1.6708E-02	1.9755	2.7042E-02	2.0676	2.7042E-02	2.0676
	1/40	4.1944E-03	1.9940	4.1944E-03	1.9940	6.6826E-03	2.0167	6.6825E-03	2.0167
	1/80	1.0497E-03	1.9986	1.0497E-03	1.9985	1.6668E-03	2.0033	1.6667E-03	2.0034
	1/10	6.5709E-02	-	6.5709E-02	-	1.1339E-01	-	1.1339E-01	-
-0.5	1/20	1.6708E-02	1.9756	1.6708E-02	1.9756	2.7078E-02	2.0661	2.7077E-02	2.0662
	1/40	4.1935E-03	1.9943	4.1935E-03	1.9943	6.7188E-03	2.0109	6.7178E-03	2.0110
	1/80	1.0487E-03	1.9995	1.0487E-03	1.9995	1.7031E-03	1.9801	1.7020E-03	1.9808

| Show Table

DownLoad: CSV

In –, fixing $\tau = 1/4000$ , choosing $h = 1/10, 1/20, 1/40, 1/80$ , and changing parameters $\alpha$ , $\beta$ , and $\theta$ , we provide the $L^2$ -errors and the time convergence rates for $u$ and $q$ based on the corrected scheme and uncorrected scheme. The impact of different fractional parameters on the time convergence rates of nonsmooth problems is evident from Tables 9–11. Furthermore, one can see that the corrected scheme with the starting part can effectively restore the second-order convergence rate.

Table 9. Time convergence results with

$\alpha = 0.1$ ,

$\beta = 0.9$ ,

$h = 1/4000$ .

		$\\|u_h-u\\|$				$\\|q_h-q\\|$
$\theta$	$\tau$	Error_o	Rate	Error_c	Rate	Error_o	Rate	Error_c	Rate
	1/10	8.9204E-03	-	6.2820E-03	-	3.5216E-01	-	2.4809E-01	-
0.1	1/20	5.2261E-03	0.7714	1.8535E-03	1.7609	2.0632E-01	0.7714	7.3209E-02	1.7608
	1/40	2.6562E-03	0.9764	4.9663E-04	1.9001	1.0486E-01	0.9764	1.9628E-02	1.8992
	1/80	1.2855E-03	1.0470	1.2782E-04	1.9580	5.0749E-02	1.0470	5.0645E-03	1.9544
	1/10	1.1291E-02	-	9.1163E-03	-	4.4575E-01	-	3.5998E-01
0	1/20	6.8182E-03	0.7277	2.7085E-03	1.7510	2.6917E-01	0.7277	1.0696E-01	1.7509
	1/40	3.4949E-03	0.9641	7.2773E-04	1.8960	1.3797E-01	0.9641	2.8751E-02	1.8954
	1/80	1.6987E-03	1.0408	1.8766E-04	1.9553	6.7062E-02	1.0408	7.4268E-03	1.9528
	1/10	2.1457E-02	-	2.6030E-02	-	1.1105E+00	-	1.7696E+00	-
-0.5	1/20	1.4552E-02	0.5603	8.3150E-03	1.6464	8.5207E-01	0.3822	6.2053E-01	1.5118
	1/40	7.7887E-03	0.9017	2.2980E-03	1.8554	4.7736E-01	0.8359	1.7762E-01	1.8047
	1/80	3.8350E-03	1.0222	6.0067E-04	1.9357	2.3888E-01	0.9988	4.7205E-02	1.9118

| Show Table

DownLoad: CSV

Table 10. Time convergence results with

$\alpha = 0.5$ ,

$\beta = 0.6$ ,

$h = 1/4000$ .

		$\\|u_h-u\\|$				$\\|q_h-q\\|$
$\theta$	$\tau$	Error_o	Rate	Error_c	Rate	Error_o	Rate	Error_c	Rate
	1/10	4.3621E-03	-	3.6704E-03	-	1.7226E-01	-	1.4498E-01	-
0.5	1/20	1.0876E-03	2.0039	9.5152E-04	1.9476	4.2941E-02	2.0042	3.7576E-02	1.9480
	1/40	3.3133E-04	1.7148	2.4178E-04	1.9765	1.3080E-02	1.7150	9.5356E-03	1.9784
	1/80	1.1132E-04	1.5735	6.1138E-05	1.9835	4.3948E-03	1.5735	2.3985E-03	1.9912
	1/10	1.4643E-03	-	1.0614E-03	-	5.8318E-02	-	4.2803E-02	-
0.2	1/20	4.8956E-04	1.5806	3.0032E-04	1.8214	1.9326E-02	1.5934	1.2126E-02	1.8197
	1/40	1.6670E-04	1.5542	7.8625E-05	1.9335	6.5811E-03	1.5541	3.1895E-03	1.9267
	1/80	5.7051E-05	1.5470	1.9768E-05	1.9918	2.2523E-03	1.5470	8.1546E-04	1.9676
	1/10	8.7609E-03	-	6.8360E-03	-	3.4601E-01	-	2.7011E-01	-
0	1/20	2.2404E-03	1.9673	1.9129E-03	1.8374	8.8510E-02	1.9669	7.5599E-02	1.8371
	1/40	5.6418E-04	1.9895	5.0061E-04	1.9340	2.2304E-02	1.9886	1.9798E-02	1.9330
	1/80	1.5985E-04	1.8194	1.2738E-04	1.9746	6.3107E-03	1.8214	5.0505E-03	1.9709

| Show Table

DownLoad: CSV

Table 11. Time convergence results with

$\alpha = 0.9$ ,

$\beta = 0.1$ ,

$h = 1/4000$ .

		$\\|u_h-u\\|$				$\\|q_h-q\\|$
$\theta$	$\tau$	Error_o	Rate	Error_c	Rate	Error_o	Rate	Error_c	Rate
	1/10	1.2779E-03	-	4.4043E-04	-	5.0452E-02	-	2.5629E-02	-
0.1	1/20	1.0267E-03	0.3157	1.1804E-04	1.8996	4.0534E-02	0.3158	7.0942E-03	1.8531
	1/40	7.5884E-04	0.4362	3.0793E-05	1.9386	2.9957E-02	0.4362	1.8662E-03	1.9265
	1/80	5.0089E-04	0.5993	8.1141E-06	1.9241	1.9774E-02	0.5993	4.7828E-04	1.9642
	1/10	4.3621E-03	-	1.4545E-03	-	7.7482E-02	-	6.1261E-02	-
0	1/20	1.8873E-03	0.6822	3.9496E-04	1.8807	4.6434E-02	0.7387	1.6763E-02	1.8697
	1/40	9.2034E-04	0.3539	1.0228E-04	1.9492	3.6333E-02	0.3539	4.3730E-03	1.9386
	1/80	6.1337E-04	0.5854	2.5740E-05	1.9904	2.4215E-02	0.5854	1.1169E-03	1.9692
	1/10	9.0746E-03	-	6.1035E-03	-	3.5896E-01	-	2.4209E-01	-
-0.1	1/20	2.3761E-03	1.9332	1.7550E-03	1.7982	9.4044E-02	1.9324	6.9621E-02	1.7980
	1/40	7.1647E-04	1.7296	4.6664E-04	1.9111	2.8284E-02	1.7333	1.8526E-02	1.9100
	1/80	5.9682E-04	0.2636	1.1984E-04	1.9612	2.3561E-02	0.2636	4.7711E-03	1.9572

| Show Table

DownLoad: CSV

To further validate the performance of the parameter $\theta$ in numerical simulations with nonsmooth solutions, we provide the computing data in , from which one can see that the parameter $\theta$ still needs to satisfy $\theta\le \min\{\alpha, \beta, \frac{1}{2}\}$ , whether before or after correction. Notably, when $\theta$ is negative, as long as it is not much less than 0, we can still obtain second-order convergence accuracy.

Table 12. Time convergence results with

$\alpha = 0.7$ ,

$\beta = 0.3$ ,

$h = 1/4000$ .

		$\\|u_h-u\\|$				$\\|q_h-q\\|$
$\theta$	$\tau$	Error_o	Rate	Error_c	Rate	Error_o	Rate	Error_c	Rate
	1/10	3.3675E-03	-	2.0604E-03	-	1.3333E-01	-	8.2027E-02	-
0.31	1/20	1.2977E-03	1.3757	5.3018E-04	1.9584	5.1287E-02	1.3783	2.1127E-02	1.9570
	1/40	1.9442E-03	-0.5833	1.4145E-04	1.9062	7.6738E-02	-0.5813	5.6232E-03	1.9096
	1/80	6.1733E-02	-4.9888	1.3510E-04	0.0663	2.4372E+00	-4.9892	5.3212E-03	0.0797
	1/10	4.5472E-02	-	3.0346E-02	-	1.7952E+00	-	1.1983E+00	-
-0.5	1/20	1.2127E-02	1.9067	9.1861E-03	1.7240	4.7880E-01	1.9066	3.6273E-01	1.7240
	1/40	3.1344E-03	1.9520	2.4851E-03	1.8861	1.2376E-01	1.9518	9.8141E-02	1.8859
	1/80	7.9608E-04	1.9772	6.4304E-04	1.9504	3.1447E-02	1.9766	2.5407E-02	1.9496
	1/10	1.1762E+00	-	3.4223E-01	-	4.6430E+01	-	1.3512E+01	-
-5	1/20	3.9521E-01	1.5734	1.9704E-01	0.7964	1.5601E+01	1.5734	7.7788E+00	0.7966
	1/40	1.2069E-01	1.7113	7.7857E-02	1.3396	4.7643E+00	1.7113	3.0736E+00	1.3396
	1/80	3.3458E-02	1.8509	2.4673E-02	1.6579	1.3208E+00	1.8509	9.7402E-01	1.6579

| Show Table

DownLoad: CSV

The time convergence rates of $u$ and $q$ are compared before and after correction with different parameters $\alpha$ , $\beta$ , and $\theta$ in Figure 5, where the slope of the line segment indicates the convergence rate. The slope of each line segment in the corrected images is the same regardless of the parameters chosen, indicating that the introduction of the starting part has a significant effect on the time convergence rates for the case with nonsmooth solutions.

Figure 5. The time convergence rates in

$L^2$ -errors with different parameters

$\alpha$ ,

$\beta$ , and

$\theta$ .

DownLoad: Full-Size Img PowerPoint

6. Conclusions

In this article, the spatial mixed finite element method with the generalized BDF2- $\theta$ for solving the time-fractional generalized Rosenau-RLW-Burgers equation was presented. Detailed proofs of stability were shown. The numerical scheme's effectiveness and feasibility were verified by conducting numerical examples that included both smooth and nonsmooth solutions. The numerical examples with good regularity indicated that our algorithm with changed parameters $\alpha$ , $\beta$ , and $\theta$ can maintain second-order convergence in time. Especially, the nonsmooth examples demonstrated that adding the correction term could effectively solve the problem of reduced order caused by weak singularity.

Author contributions

N. Yang: Writing–original draft, Formal analysis, Software; Y. Liu: Methodology, Validation, Formal analysis, Funding acquisition, Supervision, Writing–review & editing. All authors have read and agreed to the published version of the manuscript.

Use of Generative-AI tools declaration

The authors declare they have not used Artificial Intelligence (AI) tools in the creation of this article.

Acknowledgments

This work was supported by the National Natural Science Foundation of China (12061053), Young Innovative Talents Project of Grassland Talents Project and Program for Innovative Research Team in Universities of Inner Mongolia Autonomous Region (NMGIRT2413).

Conflict of interest

The authors declare that they have no conflicts of interest.

References

[1]	Takeuchi Y, Park C, Noborio K, et al. (2010) Heat transfer in SiC compact heat exchanger. Fusion Eng Des 85: 1266-1270. doi: 10.1016/j.fusengdes.2010.03.017
[2]	Steen M, Ranzani L (2000) Potential of SiC as a heat exchanger material in combined cycle plant. Ceram Int 26: 849-854. doi: 10.1016/S0272-8842(00)00027-4
[3]	Casady JB, Johnson RW (1996) Status of silicon carbide (SiC) as a wide-bandgap semiconductor for high-temperature applications: A review. Solid State Electron 39: 1409-1422. doi: 10.1016/0038-1101(96)00045-7
[4]	Joshi RP, Neudeck PG, Fazi C (2000) Analysis of the temperature dependent thermal conductivity of silicon carbide for high temperature applications. J Appl Phys 88: 265-269. doi: 10.1063/1.373651
[5]	Pachaiyappan R, Gopinath R, Gopalakannan S (2015) Processing techniques of a silicon carbide heat exchanger and its capable properties-A review. Appl Mech Mater 787: 513-517. doi: 10.4028/www.scientific.net/AMM.787.513
[6]	Gulbransen EA, Jansson SA (1972) The high-temperature oxidation, reduction, and volatilization reactions of silicon and silicon carbide. Oxid Met 4: 181-201. doi: 10.1007/BF00613092
[7]	Badini C, Liedtke V, Euchberger G, et al. (2012) Self passivating behavior of multilayer SiC under simulated atmospheric re-entry conditions. J Eur Ceram Soc 32: 4435-4445. doi: 10.1016/j.jeurceramsoc.2012.07.031
[8]	Jacobson NS, Fox DS, Opila EJ (1998) High temperature oxidation of ceramic matrix composites. Pure Appl Chem 70: 493-500. doi: 10.1351/pac199870020493
[9]	Squire TH, Marschall J (2010) Material property requirements for analysis and design of UHTC components in hypersonic applications. J Eur Ceram Soc 30: 2239-2251. doi: 10.1016/j.jeurceramsoc.2010.01.026
[10]	Levine SR, Opila EJ, Halbig MC, et al. (2002) Evaluation of ultra-high temperature ceramics foraeropropulsion use. J Eur Ceram Soc 22: 2757-2767. doi: 10.1016/S0955-2219(02)00140-1
[11]	Wuchina E, Opila E, Opeka M, et al. (2007) UHTCs: Ultra-high temperature ceramic materials for extreme environment applications. Electrochem Soc Interface 16: 30-36.
[12]	Neuman EW, Hilmas GE, Fahrenholtz WG (2013) Strength of zirconium diboride to 2300 ℃. J Am Ceram Soc 96: 47-50. doi: 10.1111/jace.12114
[13]	Hu P, Gui K, Yang Y, et al. (2013) Effect of SiC content on the ablation and oxidation behavior of ZrB₂-based ultra high temperature ceramic composites. Materials 6: 1730-1744. doi: 10.3390/ma6051730
[14]	Monteverde F, Bellosi A (2002) Effect of the addition of silicon nitride on sintering behaviour and microstructure of zirconium diboride. Scripta Mater 46 223-228.
[15]	Padovano E, Badini C, Celasco E, et al. (2015) Oxidation behavior of ZrB₂/SiC laminates: Effect of composition on microstructure and mechanical strength. J Eur Ceram Soc 35: 1699-1714. doi: 10.1016/j.jeurceramsoc.2014.12.029
[16]	Daudt NF, Hackemüller FJ, Bram M (2019) Manufacturing of Ti-10Nb based metal sheets by tape casting. Mater Lett 237: 161-164. doi: 10.1016/j.matlet.2018.11.109
[17]	Muralidharan MN, Sunny EK, Dayas KR, et al. (2011) Optimization of process parameters for the production of Ni-Mn-Co-Fe based NTC chip thermistors through tape casting route. J Alloys Compd 509: 9363-9371. doi: 10.1016/j.jallcom.2011.07.037
[18]	Tietz F, Buchkremer HP, Stöver D (2002) Components manufacturing for solid oxide fuel cells. Solid State Ionics 152-153: 373-381. doi: 10.1016/S0167-2738(02)00344-2
[19]	Barcena J, Lagos M, Agote I, et al. (2013) SMARTEES FP₇ space project-towards a new TPS reusable concept for atmospheric eeentry from low earth orbit. 7th European Workshop on Thermal Protection System and Hot Structures.
[20]	Padovano E, Badini C, Biamino S, et al. (2013) Pressureless sintering of ZrB₂-SiC composite laminates using boron and carbon as sintering aids. Adv Appl Ceram 112: 478-486. doi: 10.1179/1743676113Y.0000000119
[21]	Clegg WJ (1992) The fabrication and failure of laminar ceramic composites. Acta Metall Et Mater 40: 3085-3093. doi: 10.1016/0956-7151(92)90471-P
[22]	Zhang J, Huang R, Gu H, et al. (2005) High toughness in laminated SiC ceramics from aqueous tape casting. Scripta Mater 52: 381-385. doi: 10.1016/j.scriptamat.2004.10.026
[23]	Qin S, Jiang D, Zhang J, et al. (2003) Design, fabrication and properties of layered SiC/TiC ceramic with graded thermal residual stress. J Eur Ceram Soc 23: 1491-1497. doi: 10.1016/S0955-2219(02)00306-0
[24]	Prakash O, Sarkar P, Nicholson PS (1995) Crack deflection in ceramic/ceramic laminates with strong interfaces. J Am Ceram Soc 78: 1125-1127. doi: 10.1111/j.1151-2916.1995.tb08455.x
[25]	Lakshminarayanan R, Shetty DK, Cutler RA (1996) Toughening of layered ceramic composites with residua l surface compression. J Am Ceram Soc 79: 79-87. doi: 10.1111/j.1151-2916.1996.tb07883.x
[26]	Green DJ, Cai PZ, Messing GL (1999) Residual stresses in alumina-zirconia laminates. J Eur Ceram Soc 19: 2511-2517. doi: 10.1016/S0955-2219(99)00103-X
[27]	Chamberlain AL, Fahrenholtz WG, Hilmas GE (2006) Pressureless sintering of zirconium diboride. J Am Ceram Soc 89: 450-456. doi: 10.1111/j.1551-2916.2005.00739.x
[28]	Tripp WC, Graham HC (1971) Thermogravimetric study of the oxidation of ZrB₂ in the temperature range of 800 ℃ to 1500 ℃. J Electrochem Soc 118: 1195-1199. doi: 10.1149/1.2408279
[29]	Chamberlain A, Fahrenholtz W, Hilmas G, et al. (2004) High-strength zirconium diboride-based ceramics. J Am Ceram Soc 87: 1170-1172. doi: 10.1111/j.1551-2916.2004.01170.x
[30]	Zhang SC, Hilmas GE, Fahrenholtz WG (2008) Pressureless sintering of ZrB₂-SiC ceramics. J Am Ceram Soc 91: 26-32.
[31]	Biamino S, Antonini A, Eisenmenger-Sittner C, et al. (2010) Multilayer SiC for thermal protection system of space vehicles with decreased thermal conductivity through the thickness. J Eur Ceram Soc 30: 1833-1840. doi: 10.1016/j.jeurceramsoc.2010.01.040
[32]	Biamino S, Antonini A, Pavese M, et al. (2008) MoSi₂ laminate processed by tape casting: Microstructure and mechanical properties' investigation. Intermetallics 16: 758-768. doi: 10.1016/j.intermet.2008.02.007
[33]	Sánchez-Herencia AJ, Baudín de la Lastra C (2009) Ceramic laminates with tailored residual stresses. Bol Soc Esp Ceram 48: 311-320.
[34]	Sglavo VM, Paternoster M, Bertoldi M (2005) Tailored residual stresses in high reliability alumina-mullite ceramic laminates. J Am Ceram Soc 88: 2826-2832. doi: 10.1111/j.1551-2916.2005.00479.x
[35]	Bermejo R, Pascual J, Lube T, et al. (2008) Optimal strength and toughness of Al₂O₃-ZrO₂ laminates designed with external or internal compressive layers. J Eur Ceram Soc 28: 1575-1583. doi: 10.1016/j.jeurceramsoc.2007.11.003
[36]	Thompson MJ, Fahrenholtz WG, Hilmas GE (2012) Elevated temperature thermal properties of ZrB₂ with carbon additions. J Am Ceram Soc 95: 1077-1085.
[37]	Hillman C, Suo Z, Lange FF (1996) Cracking of laminates subjected to biaxial tensile stresses. J Am Ceram Soc 79: 2127-2133. doi: 10.1111/j.1151-2916.1996.tb08946.x
[38]	Spowart JE, Déve HE (2000) Compressive failure of metal matrix composites, In: Kelly A, Zweben C, Comprehensive Composite Materials, Elsevier, 3: 221-245.
[39]	Mari D, Krawitz AD, Richardson JW, et al. (1996) Residual stress in WC-Co measured by neutron diffraction. Mater Sci Eng A-Struct 209: 197-205. doi: 10.1016/0921-5093(95)10147-0
[40]	Shackelford JF, Alexander W (2001) CRC Materials Science and Engineering Handbook, 4 Eds., New York: CRC press, 49: 1557-1558.
[41]	Bansal PN (2006) Handbook of Ceramic Composites, Springer Science & Business Media, 200.
[42]	Zhang X, Zhou P, Hu P, et al. (2011) Toughening of laminated ZrB₂-SiC ceramics with residual surface compression. J Eur Ceram Soc 31: 2415-2423. doi: 10.1016/j.jeurceramsoc.2011.05.024
[43]	Guo SQ (2009) Densification of ZrB₂-based composites and their mechanical and physical properties: A review. J Eur Ceram Soc 29: 995-1011. doi: 10.1016/j.jeurceramsoc.2008.11.008
[44]	Jacobson NS, Myers DL (2011) Active oxidation of SiC. Oxid Met 75: 1-25. doi: 10.1007/s11085-010-9216-4
[45]	Niu Y, Wang H, Li H, et al. (2013) Dense ZrB₂-MoSi₂ composite coating fabricated by low pressure plasma spray (LPPS). Ceram Int 39: 9773-9777. doi: 10.1016/j.ceramint.2013.05.038
[46]	Monteverde F, Savino R (2007) Stability of ultra-high-temperature ZrB₂-SiC ceramics under simulated atmospheric re-entry conditions. J Eur Ceram Soc 27: 4797-4805. doi: 10.1016/j.jeurceramsoc.2007.02.201
[47]	Karlsdottir SN, Halloran JW, Henderson CE (2007) Convection patterns in liquid oxide films on ZrB₂-SiC composites oxidized at a high temperature. J Am Ceram Soc 90: 2863-2867. doi: 10.1111/j.1551-2916.2007.01784.x
[48]	Fahrenholtz WG (2007) Thermodynamic analysis of ZrB₂-SiC oxidation: Formation of a SiC-depleted region. J Am Ceram Soc 90: 143-148. doi: 10.1111/j.1551-2916.2006.01329.x

Reader Comments

Your name:*

Email:*
© 2020 the Author(s), licensee AIMS Press. This is an open access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0)

通讯作者: 陈斌, bchen63@163.com

1.
沈阳化工大学材料科学与工程学院沈阳 110142

AIMS Materials Science

1.4 3.6

Metrics

Article views(3986) PDF downloads(86) Cited by(0)

Preview PDF

Download XML

Export Citation

Article outline

Show full outline

Figures and Tables

Figures(4) / Tables(2)

AIMS Materials Science

Processing of hybrid laminates integrating ZrB₂/SiC and SiC layers

Related Papers:

Abstract

1. Introduction

2. Numerical scheme

3. Existence and uniqueness of numerical solution

4. Stability

5. Numerical results

6. Conclusions

Author contributions

Use of Generative-AI tools declaration

Acknowledgments

Conflict of interest

References

Reader Comments

通讯作者: 陈斌, bchen63@163.com

Metrics

Figures and Tables

Other Articles By Authors

Catalog

AIMS Materials Science

Processing of hybrid laminates integrating ZrB2/SiC and SiC layers

Related Papers:

Abstract

1. Introduction

2. Numerical scheme

3. Existence and uniqueness of numerical solution

4. Stability

5. Numerical results

6. Conclusions

Author contributions

Use of Generative-AI tools declaration

Acknowledgments

Conflict of interest

References

Reader Comments

通讯作者: 陈斌, bchen63@163.com

Metrics

Figures and Tables

Other Articles By Authors

Related pages

Tools

Export File

Citation

Format

Content

Catalog

Processing of hybrid laminates integrating ZrB₂/SiC and SiC layers