Difference between revisions of "Silicon Nitride Membrane"

Latest revision as of 11:40, 30 November 2023

Silicon Nitride Membrane
Background
Benchmark ID	siliconNitrideMembrane_n60020m1q2
Category	misc
System-Class	AP-LTI-FOS
Parameters
nstates	60020
ninputs	1
noutputs	2
nparameters	2
components	A, B, C, E
Copyright
License	NA
Creator	Lihong Feng
Editor	Lihong Feng Christian Himpe
Location
NA

Description

Figure 1: silicon nitride membrane temperature profile

A silicon nitride membrane (SiN membrane) ^[1] can be a part of a gas sensor, but also a part of an infra-red sensor, a microthruster, an optical filter etc. This structure resembles a microhotplate similar to other micro-fabricated devices such as gas sensors ^[2] and infrared sources ^[3] (See also Gas Sensor Benchmark). See Fig. 1, the temperature profile for the SiN membrane.

The governing heat transfer equation in the membrane is:

\nabla \cdot (\kappa \nabla T)+Q - \rho c_p \cdot \frac{\partial T}{\partial t}=0

where $\kappa$ is the thermal conductivity in $W m^{-1} K^{-1}$ , $c_p$ is the specific heat capacity in $J kg^{-1} K^{-1}$ , $\rho$ is the mass density in $kg m^{-3}$ and $T$ is the temperature distribution. We assume a homogeneous heat generation rate over a lumped resistor:

Q = \frac{u^2(t)}{R(T)}

with $Q$ the heat generation rate per unit volume in $W m^{-3}$ . We use the initial condition $T_0 = 273K$ , and the Dirichlet boundary condition $T = 273 K$ at the bottom of the computational domain.

The convection boundary condition at the top of the membrane is

q=h(T-T_{air}),

where $h$ is the heat transfer coefficient between the membrane and the ambient air in $W m^{-2} K^{-1}$ .

Discretization

Under the above convection boundary condition and assuming $T_{air}=0$ , a finite element discretization of the heat transfer model leads to the parametrized system as below,

(E_0+\rho c_p \cdot E_1) \dot{T} +(A_0 +\kappa \cdot A_1 +h \cdot A_2)T = B \frac{u^2(t)}{R(T)}, \quad y=C T,

where the volumetric heat capacity $\rho c_p$ , thermal conductivity $\kappa$ and the heat transfer coefficient $h$ between the membrane are kept as parameters. The volumetric hear capacity $\rho c_p$ is the product of two independent variables, i.e. the specific hear capacity $c_p$ and the density $\rho$ . The range of interest for the four independent variables are $\kappa \in [2, 5]$ , $c_p \in [400, 750]$ , $\rho \in [3000,3200]$ and $h \in [10, 12]$ respectively. The frequency range is $f \in [0,25]Hz$ . What is of interest is the output in time domain. The interesting time interval is $t \in [0,0.04]s$ .

Here $R(T)$ is either a constant heat resistivity $R(T)=R_0$ , or $R(T)=R_0(1+\alpha T)$ , which depends linearly on the temperature. Here we use $R_0=274.94 \Omega$ and temperature coefficient $\alpha=2.293 \pm 0.006 \times 10^{-4}$ . The model was created and meshed in ANSYS. It contains a constant load vector $B$ corresponding to the constant input power of $2.49mW$ . The number of degrees of freedom is $n=60,020$ .

The input function $u(t)$ is a step function with the value $1$ , which disappears at the time $0.02s$ . This means between $0s$ and $0.02s$ input is one and after that it is zero. However, be aware that $u(t)$ is just a factor with which the load vector B is multiplied and which corresponds to the heating power of $2.49mW$ . This means if one keeps $u(t)$ as suggested above, the device is heated with $2.49mW$ for the time length of 0.02s and after that the heating is turned off. If for whatever reason, one wants the heating power to be $5mW$ , then $u(t)$ has to be set equal to two, etc. When $R(T)=R_0(1+\alpha T)$ , it is a function of the state vector $T$ and hence, the system has non-linear input (It is also called a weakly nonlinear system.).

Data

The model is generated in ANSYS. The system matrices are in MatrixMarket format and can be downloaded here: SiN_membrane.tgz.

Dimensions

System structure:

\begin{array}{rcl} (E_1 + \rho c_p E_2)\dot{x}(t) &=& -(A_1 + \kappa A_2 + h A_3)x(t) + Bu(t) \\ y(t) &=& Cx(t) \end{array}

System dimensions:

$E_{1,2} \in \mathbb{R}^{60020 \times 60020}$ , $A_{1,2,3} \in \mathbb{R}^{60020 \times 60020}$ , $B \in \mathbb{R}^{60020 \times 1}$ , $C \in \mathbb{R}^{2 \times 60020}$ .

References

↑ T. Bechtold, D. Hohfeld, E. B. Rudnyi and M. Guenther, "Efficient extraction of thin-film thermal parameters from numerical models via parametric model order reduction", J. Micromech. Microeng. 20(4): 045030, 2010.
↑ J. Spannhake, O. Schulz, A. Helwig, G. Müller and T. Doll, "Design, development and operational concept of an advanced MEMS IR source for miniaturized gas sensor systems", Proc. Sensors: 762--765, 2005.
↑ M. Graf, D. Barrettino, S. Taschini, C. Hagleitner, A. Hierlemann and H. Baltes, "Metal oxide-based monolithic complementary metal oxide semiconductor gas sensor microsystem", Anal. Chem., 76(15): 4437--4445, 2004.

Contact

Lihong Feng

Tamara Bechtold

[bechthold10-1] T. Bechtold, D. Hohfeld, E. B. Rudnyi and M. Guenther, "Efficient extraction of thin-film thermal parameters from numerical models via parametric model order reduction", J. Micromech. Microeng. 20(4): 045030, 2010.

[spannhake05-2] J. Spannhake, O. Schulz, A. Helwig, G. Müller and T. Doll, "Design, development and operational concept of an advanced MEMS IR source for miniaturized gas sensor systems", Proc. Sensors: 762--765, 2005.

[graf04-3] M. Graf, D. Barrettino, S. Taschini, C. Hagleitner, A. Hierlemann and H. Baltes, "Metal oxide-based monolithic complementary metal oxide semiconductor gas sensor microsystem", Anal. Chem., 76(15): 4437--4445, 2004.

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[2]

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@@ Line 4: / Line 4: @@
 [[Category:first differential order]]
 [[Category:time invariant]]
+{{Infobox
+|Title           = Silicon Nitride Membrane
+|Benchmark ID    = siliconNitrideMembrane_n60020m1q2
+|Category        = misc
+|System-Class    = AP-LTI-FOS
+|nstates         = 60020
+|ninputs         = 1
+|noutputs        = 2
+|nparameters     = 2
+|components      = A, B, C, E
+|License         = NA
+|Creator         = [[User:Feng]]
+|Editor          =
+* [[User:Feng]]
+* [[User:Himpe]]
+|Zenodo-link     = NA
+}}
 ==Description==
@@ Line 80: / Line 98: @@
 :<math>
 \begin{array}{rcl}
-(E_0 + \rho c_p E_1)\dot{x}(t) &=& -(A_0 + \kappa A_1 + h A_3)x(t) + Bu(t) \\
+(E_1 + \rho c_p E_2)\dot{x}(t) &=& -(A_1 + \kappa A_2 + h A_3)x(t) + Bu(t) \\
 y(t) &=& Cx(t)
 \end{array}
@@ Line 87: / Line 105: @@
 System dimensions:
-<math>E_0 \in \mathbb{R}^{60020 \times 60020}</math>,
+<math>E_{1,2} \in \mathbb{R}^{60020 \times 60020}</math>,
-<math>E_1 \in \mathbb{R}^{60020 \times 60020}</math>,
+<math>A_{1,2,3} \in \mathbb{R}^{60020 \times 60020}</math>,
-<math>A_0 \in \mathbb{R}^{60020 \times 60020}</math>,
-<math>A_1 \in \mathbb{R}^{60020 \times 60020}</math>,
-<math>A_2 \in \mathbb{R}^{60020 \times 60020}</math>,
 <math>B \in \mathbb{R}^{60020 \times 1}</math>,
 <math>C \in \mathbb{R}^{2 \times 60020}</math>.