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<h1>Carbon Footprint Analysis</h1> | <h1>Carbon Footprint Analysis</h1> | ||
− | <p> | + | <p>We are facing an huge increase in global population, from the current world population of f 7.6 billion to an expected 9.8 billion in 2050[<a target="_blank" href="https://www.un.org/development/desa/publications/world-population-prospects-the-2017-revision.html">1</a>]. This projected increase in global population leads to an increase in both increased food and energy consumption, which in turn in is associated with the release of larger amounts of greenhouse gasses the atmosphere. Right now, we live in a plastic generation. The global production and consumption of plastics have been on the rise for over 50 years now, reaching a plastic consumption of 297.5 million tons by the end of 2015[<a target="_blank" href="http://www.worldwatch.org/global-plastic-production-rises-recycling-lags-0">2</a>]. Plastic products from the petrochemical industries have a high carbon footprint (Boonniteewanich et al,. 2014). The combination of global population increase and a mass consumed non-eco-friendly product, in the form of petroleum-based plastics, could be disastrous. This is one of the reasons that the Groningen iGEM team’s project attempts to produce (bio)styrene, a building block for many plastics, from cellulose as an alternative to substitute the petroleum-based styrene. In this section we have carried out a partial Life Cycle Assessment (LCA) analysis to identify the environmental impact of both alternatives of petroleum-based styrene and bio-based styrene. The main purpose is to provide an insight of environmental burden that is caused by the worldwide styrene industry in terms of carbon dioxide equivalent emissions (CO2-e) and to showcase our greener alternative. </p> |
+ | |||
+ | <p> | ||
+ | For our LCA analysis , we have set the study boundary to what is called the ‘cradle to gate’ analysis instead of a full LCA which is called the ‘cradle to grave’ analysis (see figure 1). The reason for this is twofold. First of all, we discovered the LCA analysis in a late phase of the project. Therefore, so we did not have enough time to do the complete quantitative analysis because, in that case you have to look at all the inputs and outputs of equivalent CO2 of feedstock and energy, for each stage of our process, which is a complex task and in some cases that information is not even freely available. However, the main reason we choose to use the cradle to gate analysis over the cradle to grave is that fact that it is the only part that matters, since we will produce the exact same product, namely styrene. The second part of the life-cycle will be exactly the same. Therefore, the only part that matters is from the feedstock you use and the energy required to the product, in our case styrene. | ||
+ | </p> | ||
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+ | <img src="https://static.igem.org/mediawiki/2018/f/f9/T--Groningen--lcaexplain.jpg"> | ||
+ | <p>Figure 1. Figure retrieved from: <a target="_blank" href="http://www.scielo.org.za/scielo.php?script=sci_arttext&pid=S1021-20192013000200001">http://www.scielo.org.za/scielo.php?script=sci_arttext&pid=S1021-20192013000200001</a> | ||
+ | </p> | ||
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Revision as of 14:25, 13 October 2018
For the StyGreen project, Human Practices was not a box that needed to be filled. It was a tool to integrate our project in the real world. As we are producing plastics, from the beginning Human Practices was very important, as it is a very sensitive subject. However, by talking to a lot of stakeholders, from suppliers to buyers and start-ups to multinationals, we have gained a lot of insights of how the plastic world works, and how we fit in this picture. As Human Practices is not an binary subject, but something that you are working on the whole day, we gave a summary of the biggest influences on the design of our project. However, a lot of insight we had as well by talking to friends, family and complete strangers. One of the first questions always was: “why more plastics?”. We have thought about this a lot, and thought about what is good and what is bad about plastics. We looked into ‘biodegradable’ plastics
, as well as chemically created bio-plastics. To get a good overview, we invite you to have a look at our thought tree. This tree catched the new light in its leaves, and by choosing the right and wrong from it grew into a great tree. Also we had great conversations on how to grow the tree bigger if iGEM is ended. How to scale up the product, and which safety procedures we had to keep in mind. We are facing an huge increase in global population, from the current world population of f 7.6 billion to an expected 9.8 billion in 2050[1]. This projected increase in global population leads to an increase in both increased food and energy consumption, which in turn in is associated with the release of larger amounts of greenhouse gasses the atmosphere. Right now, we live in a plastic generation. The global production and consumption of plastics have been on the rise for over 50 years now, reaching a plastic consumption of 297.5 million tons by the end of 2015[2]. Plastic products from the petrochemical industries have a high carbon footprint (Boonniteewanich et al,. 2014). The combination of global population increase and a mass consumed non-eco-friendly product, in the form of petroleum-based plastics, could be disastrous. This is one of the reasons that the Groningen iGEM team’s project attempts to produce (bio)styrene, a building block for many plastics, from cellulose as an alternative to substitute the petroleum-based styrene. In this section we have carried out a partial Life Cycle Assessment (LCA) analysis to identify the environmental impact of both alternatives of petroleum-based styrene and bio-based styrene. The main purpose is to provide an insight of environmental burden that is caused by the worldwide styrene industry in terms of carbon dioxide equivalent emissions (CO2-e) and to showcase our greener alternative.
For our LCA analysis , we have set the study boundary to what is called the ‘cradle to gate’ analysis instead of a full LCA which is called the ‘cradle to grave’ analysis (see figure 1). The reason for this is twofold. First of all, we discovered the LCA analysis in a late phase of the project. Therefore, so we did not have enough time to do the complete quantitative analysis because, in that case you have to look at all the inputs and outputs of equivalent CO2 of feedstock and energy, for each stage of our process, which is a complex task and in some cases that information is not even freely available. However, the main reason we choose to use the cradle to gate analysis over the cradle to grave is that fact that it is the only part that matters, since we will produce the exact same product, namely styrene. The second part of the life-cycle will be exactly the same. Therefore, the only part that matters is from the feedstock you use and the energy required to the product, in our case styrene.
Figure 1. Figure retrieved from: http://www.scielo.org.za/scielo.php?script=sci_arttext&pid=S1021-20192013000200001
Human Practices
Project Timeline
Carbon Footprint Analysis