How to plot my graph using pc1d
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- HOW TO PLOT MY GRAPH USING PC1D ZIP FILE
- HOW TO PLOT MY GRAPH USING PC1D SOFTWARE
- HOW TO PLOT MY GRAPH USING PC1D SIMULATOR
Three major subsections named DEVICE, REGION 1 and EXCITATION.
HOW TO PLOT MY GRAPH USING PC1D SOFTWARE
Once you start the software by double clicking, a parameter page will open. You may create a shortcut on desktop or elsewhere for quick access. Double-click this file and PC1D will start. Inside the folder you will find anĪpplication file ‘PC1D.exe’. Named ‘PC1D5’ will be created under the same directory.
HOW TO PLOT MY GRAPH USING PC1D ZIP FILE
Installation guide: Download the zip file from the website. PC1D.exe (Publisher: University of New South Wales) It can be downloaded from the following website.
HOW TO PLOT MY GRAPH USING PC1D SIMULATOR
The simulator PC1D is developed by University of New South Wales and it is availableįreely. Front side contact is made in the form of fingers to letįigure II.10.3: Standard industrial solar cell structure The emitter and the BSF are fabricated by diffusion. Highly doped region of base material (p+ type in this case, p+ means higher doping than P). Provided at the back side to reduce surface recombination losses. The front surface is textured to reduce reflection further. An anti reflection coating is provided on the front side to reduce reflection. The n+ emitter (n+ means higher doping than n-type) and the p-type base form The structure is similar to that of aĭiode. ID is the diode current given by Shockley equation.įigure II.10.2: I–V curve shift in case of an illuminated diodeĪ standard solar cell is described in Figure II.10.3. IL is the light generated current due to the photovoltaic effect, The generated current creates a forward bias across the Hence, the overall I–V curve is dragged down the Y-axis by an amountĮqual to the light generated current. The p-side move down the energy barrier and the holes from the n-side move up the barrierĪcross the junction. In other words, the electrons generated in The EHP thus created adds onto the reverseĬurrent due to minority carriers in the junction. Has extra energy equal to that of the photon. When a PN junction is illuminated with light (as in a solar cell), the photons excite theĮlectrons in the valence band to jump to the conduction band such that the electron now The ideality factor n varies from 1 to 2 depending on the fabrication process andįigure II.10.1: I–V characteristics of a P–N junction diode of different materials N is the ideality factor, also known as the quality factor or sometimes the emissionĬoefficient.
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IS is the reverse bias saturation current, In a P–N junction diode, the diode current is given by the ‘Shockley Equation’: Hands-on training in the use of PC1D through simulation of basic devices. The main aim of the exercises provided is to get a Junction diode will be studied and its use as a single junction solar cell will be explored Of a one-dimensional device simulator named PC1D. To simulate and understand the behaviour of P–N junction diodes through the medium Know some typical values of these parameters and to know solar cell efficiency underĪbility to plot different parameters against different spatial and temporal variation.Ībility to simulate in batch and export the data to other format.Ībility to change the mode of excitation to study solar cell under different conditions. To be able simulate in batch of to study the effect of parameters like junction depths,Ībility to figure out important parameters for solar cell operation. To simulate P-N junction under equilibrium, dark and illuminated conditions. To know typical values of these parameters. To understand the basic parameters of interest in fabrication of solar cell. The objective is further broken down in the following ways: Simulator, the objectives of these experiments is to learn to use the simulator for solar cell Published based on the results obtained from PC1D. There are many research papers that have been This is a one-dimensional simulatorĪnd well recognized all over the world. One dimensional) is a simulator which is freely available. Instead one can do the simple simulation toĮstimate the effect of a given parameter on solar cell efficiency. Then measure the performance of solar cells. If you want to know how much a given parameter affects the performance ofĪ solar cell, it will be waste of time and resources to fabricate solar cells for each scenario and Thickness of antireflective coating, material of antireflective coating, metal contacts, Of P-type), doping of the substrates, depth of the junction, doping profile of the junction, Solar cell efficiency depends on many parameters which include type of substrate (N-type University of Sussex Library, on at 13:18:40, subject to the Cambridge Core terms of use, available at The PC1D software Methodology Simulation Exercise Results and Discussionĭownloaded from. Objectives Outcome of this Experiment Background Theory Solar Cell Structure Solar Cell Simulation Using PC1D Simulator