Difference between revisions of "Team:Hong Kong-CUHK/Modeling"

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<center><div style="text-align:justify; text-justify:inter-ideograph; width:800px">
  
<center><div style="text-align:justify; text-justify:inter-ideograph; width:1000px">
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<h1>Modeling</h1>
<font face="Times New Roman" size="5pt">
+
<h1> Modeling</h1>
+
 
<br>
 
<br>
  
<p><font face="Times New Roman" size="4pt"> Magnetosome can be used in different perspective and it shows a good variety in different application. Three applications has been modelled in different perspective. Let me show the great variety of using magnetosome:</p></font>
+
<p>Magnetosome can be used in different perspectives, thus a great potential to apply in multiple instances. Three applications has been modeled as follows:</p>
<h2> 1) Protein extraction:</h2>
+
<h2>(1) Protein Extraction (This modelling regarding to protein extraction was done by City University of Hong Kong through Collaboration) </h2>
<p><font face="Times New Roman" size="4pt">Magnetosome can be used in microscopic point of view. We try to model his efficiency to bind with different proteins and use GFP-nanobody for immunoprecipitation. The main purpose of this modelling is to stimulate the binding dynamics of a fixed concentration of magnetosome and GFP-nanobody in different initial concentration of antigens.</p></font>
+
<p>Magnetosome can be used in microscopic point of view. We tried to model the efficiency to bind with <b>(a) different proteins</b> and <b>(b) use GFP-nanobody for immunoprecipitation</b>. The main purpose of this modelling is to stimulate the <b>binding dynamics</b> of a fixed concentration of magnetosome and GFP-nanobody in different initial concentration of antigens.</p><br>
<p><font face="Times New Roman" size="4pt">Various conditions and parameters:</p></font>
+
<p>Various conditions and parameters:</p>
 
<center><table><tr>
 
<center><table><tr>
<th>Fixed quantity</th> <th>quantity</th>
+
<b><th>Fixed Quantity</th> <th>Quantity</th></b>
 
</tr><tr>
 
</tr><tr>
<th>Volume of the mixture</th> <th>1000ul</th>
+
<th>Volume of the mixture</th> <th>1000 &mu;l</th>
 
</tr></table></center>
 
</tr></table></center>
 
 
<center><table><tr>
 
<center><table><tr>
<th>Parameters</th> <th>quantity</th>
+
<th>Parameters</th> <th>Quantity</th>
 
</tr><tr>
 
</tr><tr>
<th>Molecular Weight of magnetosome</th> <th>6.89 x108 g</th>
+
<th>Molar Mass of Magnetosome</th> <th>6.89 &times; 10<sup>8</sup> </th>
 
</tr><tr>
 
</tr><tr>
<th>Number of GFP-nanobody per magnetosome</th> <th>362</th>
+
<th>Number of GFP-nanobody per Magnetosome</th> <th>362</th>
 
</tr><tr>
 
</tr><tr>
<th>association rate constant kon(Marta H. Kubala†, 2010)</th>
+
<th>Association Rate Constant (k<sub>on</sub>; Marta H. Kubala†, 2010)</th>
<th>8.84x104M-1s-1</th>
+
<th>8.84 &times; 10<sup>4</sup> M<sup>-1</sup> s<sup>-1</sup></th>
 
</tr><tr>
 
</tr><tr>
<th>dissociation rate constant koff(Marta H. Kubala†, 2010)</th>
+
<th>Dissociation Rate Constant (k<sub>off</sub>; Marta H. Kubala†, 2010)</th>
<th>1.24x10-4s-1</th>
+
<th>1.24 &times; 10<sup>-4</sup> s<sup>-1</sup></th>
 
</tr></table></center>
 
</tr></table></center>
 
 
<center><table><tr>
 
<center><table><tr>
<th>Condition</th> <th>quantity</th>
+
<th>Condition</th> <th>Quantity</th>
 
</tr><tr>
 
</tr><tr>
<th>Amount of magnetosome</th> <th>1.5mg</th>
+
<th>Amount of Magnetosome</th> <th>1.5 mg</th>
 
</tr><tr>
 
</tr><tr>
<th>Weight of GFP-nanobody</th> <th>negligible</th>
+
<th>Weight of GFP-nanobody</th> <th>Negligible</th>
 
</tr><tr>
 
</tr><tr>
<th>Initial molarity of antigen (GFP)</th> <th>Varying from 0 to 1.6E-6M</th>
+
<th>Initial Molarity of Antigen (GFP)</th> <th>Varying from 0 to 1.6 &mu;M</th>
 
</tr><tr>
 
</tr><tr>
<th>Initial amount of GFP:GFP-nanobody complex</th> <th>0</th>
+
<th>Initial Amount of GFP:GFP-nanobody complex</th> <th>0</th>
 
</tr></table></center>
 
</tr></table></center>
  
<p><font face="Times New Roman" size="4pt">First, the molarity of the magnetosome is needed to calculate since the amount of magnetosome and its molecular weight are known,</p></font>
+
<p>First, the molarity of magnetosomes is calculated since the amount of magnetosome and its molecular weight are known,</p><br>
<Center>Molarity of Magnetosome=(1.5mg/6.89 x108 g)/(1ml)=2.18 x10-9M</center>
+
<Center>Molarity of Magnetosome = (1.5 mg / 6.89 &times; 10<sup>8</sup> g) / (1 ml) = 2.18 nM</center><br>
<p><font face="Times New Roman" size="4pt">There are 362 GFP-nanobody per each magnetosome, the molarity of GFP-nanobody is:</p></font>
+
<p>There are 362 GFP-nanobody per each magnetosome, so the molarity of GFP-nanobody is:</p><br>
<Center>Molarity of GFP-nanobody = 2.18 x10-9M x 362 = 7.78 x10-7M</Center>
+
<Center>Molarity of GFP-nanobody = 2.18 nM &times; 362 = 7.78 &times; 10<sup>-7</sup> M</Center><br>
<p><font face="Times New Roman" size="4pt">After that, a software called Simbiology is used in MATLAB and it help us to model and stimulate the dynamics of the association and dissociation between molecules. By constructing a model about the mathematics relationship between molecules. enmolecules,reaction process can be stimulated.</p></font>
+
<p>After that, a software called Simbiology in MATLAB is used to model and stimulate the dynamics of the association and dissociation between the molecules. By constructing a model about the mathematical relationship between molecules, reaction process can be stimulated.</p>
  
  
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<center><img src="https://static.igem.org/mediawiki/2015/6/6f/CUHK_Modeling_Binding_activity.jpg"></center>
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<center><img src="https://static.igem.org/mediawiki/2015/6/6f/CUHK_Modeling_Binding_activity.jpg" width="600px"></center>
<p><font face="Times New Roman" size="4pt">Figure 1: Binding activity</p></font>
+
<p style="font-size: 12px"><b>Figure 1:</b> Binding activity</p>
  
<p><font face="Times New Roman" size="4pt">For Forward reaction (association) rate: </p> </font>
+
<p>For Forward Reaction (Association) rate: </p>  
<center>kon *[GFP-nanobody]*[antigens]</center>
+
<center>k<sub>on</sub> &times; [GFP-nanobody] &times; [Antigen]</center>
  
<p><font face="Times New Roman" size="4pt">For backward reaction (dissociation) rate:  </p></font>
+
<p>For Reverse Reaction (Dissociation) rate:  </p>
<center> koff *[GFP-nanobody-antigens-complex]</center>
+
<center>k<sub>off</sub> &times; [GFP-nanobody-antigen Complex]</center>
  
<p><font face="Times New Roman" size="4pt">Net reaction rate:  </p></font>
+
<p>Net Reaction Rate:  </p>
<center>kon *[GFP-nanobody]*[antigens] - koff *[GFP-nanobody-antigens-complex]</center>
+
<center>k<sub>on</sub> &times; [GFP-nanobody] &times; [Antigen] &minus; k<sub>off</sub> &times; [GFP-nanobody-antigen Complex]</center>
  
<p><font face="Times New Roman" size="4pt">Note: kon, koff are the reaction rate constant described in the parameters table.</p></font>
+
<p>Note: k<sub>on</sub>, k<sub>off</sub> are the reaction rate constants described in the parameters table above.</p>
  
<p><font face="Times New Roman" size="4pt">By using the function of SimBiology, we stimulate the dynamic of the system with the initial
+
<p>By using SimBiology, we stimulated the dynamic of the system with the initial
concentration of antigen from 0M to 1.6E-6M with an interval of 2E-7M. </p>
+
concentration of antigen from 0 to 1.6 &mu;M with an interval of 0.2 &mu;M. </p>
  
  
  
  
<img src="https://static.igem.org/mediawiki/2015/2/20/CUHK_Modeling_Figure_2.jpg">
+
<img src="https://static.igem.org/mediawiki/2015/2/20/CUHK_Modeling_Figure_2.jpg" width="800px">
<p>Figure 2</p>
+
<p style="font-size: 12px"><b>Figure 2</b></p>
  
<p>From figure 2, we can see that when the molarity of antigen below that of GFP-nanobody (7.78 x10-7M), it becomes the limiting reagent, and the final molarity of the nanobody-antigen complex equals the initial molarity of antigen, vice versa.</p>
+
<p>From Figure 2, we can see that when the molarity of antigen below that of GFP-nanobody (7.78 &times; 10<sup>-7</sup> M), it becomes the limiting reagent, and the final molarity of the nanobody-antigen complex equals the initial molarity of antigen, vice versa.</p><br>
<p>Another observation is that, as the molarity of antigen increase, the reaction (i.e. the formation of nanobody-antigen complex) goes equilibrium quicker. This can be explained by the increased forward reaction rate, which depends on the molarity of GFP-nanobody and antigen as well. </p>
+
<p>Another observation is that, as the molarity of antigen increase, the reaction (i.e. the formation of nanobody-antigen complex) goes equilibrium more quickly. This can be explained by the increased forward reaction rate, which depends on the molarity of GFP-nanobody and antigen as well. </p>
  
  
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<h2> 2) Microbial Fuel cell </h2>
+
<h2>(2) Microbial Fuel Cell</h2>
<p>In a Microbial Fuel cell, the chemical enrgy is transformed into the electrical energy through a cascade of electrochemical reaction. The mutated nitrogenase in Azobacter will produce hydrogen gas by the side reaction and break down into hydrogen ion due to the existence of hydrogenase. Alternatively the electrons can be transferred transferred to the oxidized mediator molecules that transfer them to the electrode. By using magnetosome, the distance between the bacteria and electrode will be decreased and it reduce the diffusion distance of the oxidized mediator. This approach increase the current density and increase efficiency of of generating electricity in Mircrobial fuel cell. </p>
+
<p>In a microbial fuel cell (MFC), chemical energy is transformed into electrical energy through a cascade of electrochemical reaction. The mutated nitrogenase in <i>Azotobacter</i> will produce hydrogen gas by the side reaction and break down into hydrogen ion due to the existence of hydrogenase. Alternatively, the electrons can be transferred to the electrode via the oxidized mediator molecules. By using magnetosome, the distance between the bacteria and electrode can be decreased, thus reduces the diffusion distance of the oxidized mediator. This approach would increase the current density and efficiency of electricity generation in MFC. </p>
  
<p>In this model, current density distribution in hydrogen-oxygen fuel cell is studied. It includes the ful coupling between the mass balances at the anode and cathode, the momentum balances in the gas channel, the gas flow in the porous electrodes, the balance of the ionic current carried by the mediator and an electronic current balance.</p>
+
<p>In this model, current density distribution in hydrogen-oxygen fuel cell was studied. It included the fuel coupling between the mass balances at the anode and cathode; the momentum balances in the gas channel; the gas flow in the porous electrodes; the balance of the ionic current carried by the mediator; and an electronic current balance.</p>
  
<img src="https://static.igem.org/mediawiki/2015/9/93/CUHK_Modeling_Figure_3.jpg">
+
<img src="https://static.igem.org/mediawiki/2015/9/93/CUHK_Modeling_Figure_3.jpg" height="400px">
<p>Figure 3</p>
+
<p style="font-size: 12px"><b>Figure 3</b></p>
  
<p>The fuel cell in the cathode and anode is counterflow and it shows that the hydrogen-rich anode gas is entering from the left. The electrochemical reaction in the cell are give below:</p>
+
<p>The fuel cell in the cathode and anode is counter-flow and it shows that the hydrogen-rich anode gas is entering from the left. The electrochemical reaction in the cell are give below:</p>
<p>Anode: H2+ 2e--> 2H+ </p>
+
<p>Anode: H<sub>2</sub> + 2 e<sup>&minus;</sup> &rarr; 2 H<sup>+</sup></p>
<p>Cathode: 1/2O2+ 2e- ->O2- </p>
+
<p>Cathode: 1/2 O<sub>2</sub> + 2 e<sup>&minus;</sup> &rarr; O<sup>2-</sup> </p>
  
  
<p>This model includes different process that shows below:</p>
+
<p>This model includes different processes:</p>
 
<p>• Electronic charge balance (Ohm’s law)</p>  
 
<p>• Electronic charge balance (Ohm’s law)</p>  
 
<p>• Ionic charge balance (Ohm’s law)</p>  
 
<p>• Ionic charge balance (Ohm’s law)</p>  
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<p>• Mass balances in gas phase in both gas channels and porous electrodes (Maxwell-Stefan Diffusion and Convection)</p>
 
<p>• Mass balances in gas phase in both gas channels and porous electrodes (Maxwell-Stefan Diffusion and Convection)</p>
  
<p>Assume the Butler-Volmer charge transfer kinetics describe the charge transfer current density and the first electron transfer is used to be rate determining step, at the anode, hydrogen is oxidized to form hydrogen ion.</p>
+
<p>Assuming the Butler-Volmer charge transfer kinetics describes the charge transfer current density and the first electron transfer is used to be rate determining step at the anode, hydrogen is oxidized to form hydrogen ion.</p>
  
<img src="https://static.igem.org/mediawiki/2015/1/11/CUHK_Modeling_Formula_i%28a%2Cct%29.jpg">
+
<center><img src="https://static.igem.org/mediawiki/2015/1/11/CUHK_Modeling_Formula_i%28a%2Cct%29.jpg" width="500px"></center>
  
<p>i0,a =the anode exchange current density (A/m2)</p>
+
<p>i<sub>0</sub>,a = the anode exchange current density (A m<sup>-2</sup>)</p>
<p>ch2 is the molar concentration of hydrogen</p>
+
<p>c<sub>h2</sub> is the molar concentration of hydrogen</p>
<p>ch+ is the molar concentration of water</p>
+
<p>c<sub>h+</sub> is the molar concentration of water</p>
<p>ct the total concentration of species (mol/m3)</p>
+
<p>c<sub>t</sub> the total concentration of species (mol m<sup>-3</sup>)</p>
<p>ch2,ref and ch2,ref is the reference concentrations (mol/m3)</p>
+
<p>c<sub>h2,ref</sub> and c<sub>h+,ref</sub> is the reference concentrations (mol m<sup>-3</sup>)</p>
<p>F is Faraday’s constant (C/mol)</p>
+
<p>F is Faraday’s constant (C mol<sup>-1</sup>)</p>
<p>R the gas constant (J/ (mol•K))</p>
+
<p>R is the gas constant (J mol<sup>-1</sup> K<sup>-1</sup>))</p>
<p>T the temperature (K)</p>
+
<p>T is the temperature (K)</p>
<p>η the overvoltage (V)</p>
+
<p>&eta; is the overvoltage (V)</p>
  
 
<p>For the cathode:</p>
 
<p>For the cathode:</p>
  
<img src="https://static.igem.org/mediawiki/2015/7/7a/CUHK_Modeling_Formula_i%28c%2Cct%29.jpg">
+
<center><img src="https://static.igem.org/mediawiki/2015/7/7a/CUHK_Modeling_Formula_i%28c%2Cct%29.jpg" width="500px"></center>
  
  
  
  
<p>At the anode’s inlet boundary, the potential is fixed at a reference potential of zero. At the cathode’s inlet boundary, set the potential to the cell voltage, Vcell. The latter is given by</p>
+
<p>At the anode’s inlet boundary, the potential is fixed at a reference potential of zero. At the cathode’s inlet boundary, set the potential to the cell voltage, V<sub>cell</sub>. The latter is given by</p>
  
<img src="https://static.igem.org/mediawiki/2015/2/24/CUHK_Modeling_Formula_v%28cell%29.jpg">
+
<center><img src="https://static.igem.org/mediawiki/2015/2/24/CUHK_Modeling_Formula_v%28cell%29.jpg" width="500px"></center>
  
<p>where Vpol is the polarization. In this model, φeq,a Δ = 0 V and φeq,c Δ = 1 V , and you simulate the fuel cell over the range 0,2 V Vcell ≤ ≤ 0,95 V by using Vpol in the range 0.05 V through 0.8 V as the parameter for the parametric solver.</p>
+
<p>where V<sub>pol</sub> is the polarization.</p><p>In this model, &Delta; &phi;<sub>eq,c</sub> = 1 V and &Delta; &phi;<sub>eq,a</sub> = 0 V ,and the fuel cell over the range 0.2 &le; V<sub>cell</sub> &le; 0.95 V is simulated by using V<sub>pol</sub> in the range 0.05 V through 0.8 V as the parameter for the parametric solver.</p>
  
<p>Results: The following figure shows the hydrogen mole fraction in the anode at a cell polarization of 0.5.V</p>
+
<p>Results: The following figure shows the hydrogen mole fraction in the anode at a cell polarization of 0.5 V</p>
  
<img src="https://static.igem.org/mediawiki/2015/f/f0/CUHK_Modeling_anode.jpg">
+
<img src="https://static.igem.org/mediawiki/2015/f/f0/CUHK_Modeling_anode.jpg" width="600px">
  
  
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<p>The following figure shows the oxygen mole fraction in the cathode:</p>
 
<p>The following figure shows the oxygen mole fraction in the cathode:</p>
  
<img src="https://static.igem.org/mediawiki/2015/a/aa/CUHK_Modeling_cathode.jpg">
+
<img src="https://static.igem.org/mediawiki/2015/a/aa/CUHK_Modeling_cathode.jpg" width="600px">
  
  
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<p>For the following figure, it shows power output as a function of cell voltage. The maximum
 
<p>For the following figure, it shows power output as a function of cell voltage. The maximum
power-output for this unit cell is about 940 W/m2</p>
+
power-output for this unit cell is about 940 W m<sup>-2</sup></p>
 +
 
 +
<img src="https://static.igem.org/mediawiki/2015/d/d7/CUHK_Modeling_Graph.jpg" width="800px">
  
<img src="https://static.igem.org/mediawiki/2015/d/d7/CUHK_Modeling_Graph.jpg">
 
</font>
 
  
  

Latest revision as of 01:54, 7 October 2015

Modeling


Magnetosome can be used in different perspectives, thus a great potential to apply in multiple instances. Three applications has been modeled as follows:

(1) Protein Extraction (This modelling regarding to protein extraction was done by City University of Hong Kong through Collaboration)

Magnetosome can be used in microscopic point of view. We tried to model the efficiency to bind with (a) different proteins and (b) use GFP-nanobody for immunoprecipitation. The main purpose of this modelling is to stimulate the binding dynamics of a fixed concentration of magnetosome and GFP-nanobody in different initial concentration of antigens.


Various conditions and parameters:

Fixed Quantity Quantity
Volume of the mixture 1000 μl
Parameters Quantity
Molar Mass of Magnetosome 6.89 × 108
Number of GFP-nanobody per Magnetosome 362
Association Rate Constant (kon; Marta H. Kubala†, 2010) 8.84 × 104 M-1 s-1
Dissociation Rate Constant (koff; Marta H. Kubala†, 2010) 1.24 × 10-4 s-1
Condition Quantity
Amount of Magnetosome 1.5 mg
Weight of GFP-nanobody Negligible
Initial Molarity of Antigen (GFP) Varying from 0 to 1.6 μM
Initial Amount of GFP:GFP-nanobody complex 0

First, the molarity of magnetosomes is calculated since the amount of magnetosome and its molecular weight are known,


Molarity of Magnetosome = (1.5 mg / 6.89 × 108 g) / (1 ml) = 2.18 nM

There are 362 GFP-nanobody per each magnetosome, so the molarity of GFP-nanobody is:


Molarity of GFP-nanobody = 2.18 nM × 362 = 7.78 × 10-7 M

After that, a software called Simbiology in MATLAB is used to model and stimulate the dynamics of the association and dissociation between the molecules. By constructing a model about the mathematical relationship between molecules, reaction process can be stimulated.

Figure 1: Binding activity

For Forward Reaction (Association) rate:

kon × [GFP-nanobody] × [Antigen]

For Reverse Reaction (Dissociation) rate:

koff × [GFP-nanobody-antigen Complex]

Net Reaction Rate:

kon × [GFP-nanobody] × [Antigen] − koff × [GFP-nanobody-antigen Complex]

Note: kon, koff are the reaction rate constants described in the parameters table above.

By using SimBiology, we stimulated the dynamic of the system with the initial concentration of antigen from 0 to 1.6 μM with an interval of 0.2 μM.

Figure 2

From Figure 2, we can see that when the molarity of antigen below that of GFP-nanobody (7.78 × 10-7 M), it becomes the limiting reagent, and the final molarity of the nanobody-antigen complex equals the initial molarity of antigen, vice versa.


Another observation is that, as the molarity of antigen increase, the reaction (i.e. the formation of nanobody-antigen complex) goes equilibrium more quickly. This can be explained by the increased forward reaction rate, which depends on the molarity of GFP-nanobody and antigen as well.

(2) Microbial Fuel Cell

In a microbial fuel cell (MFC), chemical energy is transformed into electrical energy through a cascade of electrochemical reaction. The mutated nitrogenase in Azotobacter will produce hydrogen gas by the side reaction and break down into hydrogen ion due to the existence of hydrogenase. Alternatively, the electrons can be transferred to the electrode via the oxidized mediator molecules. By using magnetosome, the distance between the bacteria and electrode can be decreased, thus reduces the diffusion distance of the oxidized mediator. This approach would increase the current density and efficiency of electricity generation in MFC.

In this model, current density distribution in hydrogen-oxygen fuel cell was studied. It included the fuel coupling between the mass balances at the anode and cathode; the momentum balances in the gas channel; the gas flow in the porous electrodes; the balance of the ionic current carried by the mediator; and an electronic current balance.

Figure 3

The fuel cell in the cathode and anode is counter-flow and it shows that the hydrogen-rich anode gas is entering from the left. The electrochemical reaction in the cell are give below:

Anode: H2 + 2 e → 2 H+

Cathode: 1/2 O2 + 2 e → O2-

This model includes different processes:

• Electronic charge balance (Ohm’s law)

• Ionic charge balance (Ohm’s law)

• Butler-Volmer charge transfer kinetics

• Flow distribution in gas channels (Navier-Stokes)

• Flow in the porous GDEs (Brinkman equations)

• Mass balances in gas phase in both gas channels and porous electrodes (Maxwell-Stefan Diffusion and Convection)

Assuming the Butler-Volmer charge transfer kinetics describes the charge transfer current density and the first electron transfer is used to be rate determining step at the anode, hydrogen is oxidized to form hydrogen ion.

i0,a = the anode exchange current density (A m-2)

ch2 is the molar concentration of hydrogen

ch+ is the molar concentration of water

ct the total concentration of species (mol m-3)

ch2,ref and ch+,ref is the reference concentrations (mol m-3)

F is Faraday’s constant (C mol-1)

R is the gas constant (J mol-1 K-1))

T is the temperature (K)

η is the overvoltage (V)

For the cathode:

At the anode’s inlet boundary, the potential is fixed at a reference potential of zero. At the cathode’s inlet boundary, set the potential to the cell voltage, Vcell. The latter is given by

where Vpol is the polarization.

In this model, Δ φeq,c = 1 V and Δ φeq,a = 0 V ,and the fuel cell over the range 0.2 ≤ Vcell ≤ 0.95 V is simulated by using Vpol in the range 0.05 V through 0.8 V as the parameter for the parametric solver.

Results: The following figure shows the hydrogen mole fraction in the anode at a cell polarization of 0.5 V

The following figure shows the oxygen mole fraction in the cathode:

For the following figure, it shows power output as a function of cell voltage. The maximum power-output for this unit cell is about 940 W m-2