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| − | <img src="https://static.igem.org/mediawiki/2018/thumb/0/01/T--Stanford-Brown-RISD--Title_Model.png/1600px-T--Stanford-Brown-RISD--Title_Model.png"> | + | <h1> Measurement </h1> |
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| − | <h3> Abstract & Introduction </h3> | + | <h3> Isothermal Titration Calorimetry (ITC) </h3> |
| − | <p> Mycelium is an ideal candidate for the construction of building materials on Mars due in most part to its replicability; a builder will end up with more material than he brought with him. However, while concrete and rebar are not easily transported, they are conveniently measured in volume and in weight, and a builder can precisely simulate the things that he can build given his material constraints. The model developed for our project attempts to confer this ease of measurability onto mycelium in order to better understand its utility as a building material—given a starting amount of mycelium, how much can a builder grow given his time constraints? Alternately, if a builder brings fillable molds and a starter colony of mycelium—how long will it take for his fungus to fill the mold? I constructed a Python model to answer these questions, and to simulate the fractal and competitive growth pattern of mycelial hyphae, in the hopes that it will be used to inform others’ efforts in growing mycelium in the future. </p> | + | <p> </p> |
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