Difference between revisions of "Team:Aix-Marseille/Integrated Practices"

Revision as of 10:39, 17 October 2016 (view source)

Loulou (Talk | contribs)

← Older edit

Revision as of 19:20, 19 October 2016 (view source)

Loulou (Talk | contribs)

Newer edit →

Line 8:

−

~~Nowadays, platinum is processed along~~ a ~~'''linear pathway'''~~. ~~Platinum is acquired from~~ mining~~, mostly in South Africa ([~~[Team:~~Pretoria_UP|Pretoria~~]~~]) Russia~~ and ~~Zimbabwe where it is found~~ in ~~relatively high concentrations: around 5ppm<ref>Bau~~ and al.~~, 2015 http~~://dx.~~doi~~.org.~~gate1~~.~~inist~~.~~fr/10~~.~~1016/j~~.~~hydromet.2015~~.01.~~002<~~/~~ref>~~. ~~These absolute concentrations~~ are ~~rather lower than most~~ metals, ~~so platinum~~ in ~~often~~ a ~~by-product~~ of ~~another mined resource~~ such ~~as nickel or coal~~.

+

Before and during the conception of our process we investigate many subject in order to design a optimal and relevant process. To do so we pick up the advice of many specialists.

+

We wished first to investigate the platinum mining issue. To do so we asked the iGEM team of Pretoria to provide us some [https://2016.igem.org/Team:Aix-Marseille/Integrated_Practices/Mines information] about condition and consequences of platinum mining. Thanks to these data and bibliography we realized what consequences platinum mining can involve in terms of sustainability, ecology, and social issues and that reinforce our determination find a way to recycle platinum. Dialogue with an [https://2016.igem.org/Team:Aix-Marseille/Integrated_Practices/history historian PhD student] showed us how metals issues have always been a central problematic throughout history. This had strengthen again our feeling that our process was a wise and relevant project to achieve.

+

As we deigned our bio-synthetic project we wonder how our project could be applied for real. We though we could spread our engineered bacteria directly along the roads. But many laws forbid the release of engineered organism in the environment so we decided to change our strategy.

+

Thanks to bibliography and [https://2016.igem.org/Team:Aix-Marseille/Integrated_Practices/Environment Mr. Triboit], (an ecologist engineer), we learn that bacteria are able to be in symbiosis with plants roots cells and improve their metals recovery, especially thanks to their siderophore.

+

This technique is actually developed in some laboratory but for the realization of our project this would have been a problem with environmental laws too.

+

Mr.Triboit enlighten us about the current situation: many process involving plants and phytoremediation are being developed and our process could appear elsewhere to connect with all these solutions. We realized pretty soon that if our process involve bacteria as we planned, there would be a need to confine it.

+

That's how we decided to design a process performed in a controlled environment that could be plugged to other processes occurring directly in environment. Controlled environment means here a bioreactor, at least a process occurring in a environment where parameters are set and controlled, downstream processes are connected, and releases containing organisms are destroyed.

+

If we were certain of the necessity of developing such a process we were not sure about which already existing biotechnological process (mainly phytoremediation processes) our process could be connected to.

+

[https://2016.igem.org/Team:Aix-Marseille/Integrated_Practices/Process Mr.Sigoillot], an process engineering expert, helped us to shape our project in a economical way: we decided our process should absolutely end on nanoparticle production in order to produce a highly valuable form.

+

Moreover Mr. Sigoillot and Mr.Triboit brought us both a crucial aspect of platinum pollution: sewage sludge are so polluted than people would pay to get rid of it! Thus a process starting from sewage sludge as a basic raw material would have positive financial and environmental balance!

−

There is an '''urgency''' to find a way to produce it '''sustainably''' before '''2064''', its exhaustion date. It's probably better to think about '''how to change the economic pathway''' of platinum than to try to find an alternative metal to platinum since the only substiture to platinum, palladium has its reserves more depleted than the paltinum ones and should be exhausted in '''2024'''.

−

The process we’ve designed allows the shaping of a '''circularized economy'''. Instead of being '''wasted''' in the environment, platinum can '''re-enter''' the economy thus making platinum production '''sustainable'''!

−

~~<references/>~~

@@ Line 8: / Line 8: @@
-Nowadays, platinum is processed along a '''linear pathway'''. Platinum is acquired from mining, mostly in South Africa ([[Team:Pretoria_UP|Pretoria]]) Russia and Zimbabwe where it is found in relatively high concentrations: around 5ppm<ref>Bau and al., 2015 http://dx.doi.org.gate1.inist.fr/10.1016/j.hydromet.2015.01.002</ref>.  These absolute concentrations are rather lower than most metals, so platinum in often a by-product of another mined resource such as nickel or coal.
+Before and during the conception of our process we investigate many subject in order to design a optimal and relevant process. To do so we pick up the advice of many specialists.
+We wished first to investigate the platinum mining issue. To do so we asked the iGEM team of Pretoria to provide us some [https://2016.igem.org/Team:Aix-Marseille/Integrated_Practices/Mines information] about condition and consequences of platinum mining. Thanks to these data and bibliography we realized what consequences platinum mining can involve in terms of sustainability, ecology, and social issues and that reinforce our determination  find a way to recycle platinum. Dialogue with an [https://2016.igem.org/Team:Aix-Marseille/Integrated_Practices/history historian PhD student] showed us how metals issues have always been a central problematic throughout history. This  had strengthen again our feeling that our process was a wise and relevant project to achieve.
+As we deigned our bio-synthetic project we wonder how our project could be applied for real. We though we could spread our engineered bacteria directly along the roads. But many laws forbid the release of engineered organism in the environment so we decided to change our strategy.
+Thanks to bibliography and [https://2016.igem.org/Team:Aix-Marseille/Integrated_Practices/Environment Mr. Triboit], (an ecologist engineer), we learn that bacteria are able to be in symbiosis with plants roots cells and improve their metals recovery, especially thanks to their siderophore.
+This technique is actually developed in some laboratory but for the realization of our project this would have been a problem with environmental laws too.
+Mr.Triboit enlighten us about the current situation: many process involving plants and phytoremediation are being developed and our process could appear elsewhere to connect with all these solutions. We realized pretty soon that if our process involve bacteria as we planned, there would be a need to confine it.
+That's how we decided to design a process performed in a controlled environment that could be plugged to other processes occurring directly in environment. Controlled environment means here a bioreactor, at least a process occurring in a environment where parameters are set and controlled, downstream processes are connected, and releases containing organisms are destroyed.
+If we were certain of the necessity of developing such a process we were not sure about which already existing biotechnological process (mainly phytoremediation processes) our process could be connected to.
+[https://2016.igem.org/Team:Aix-Marseille/Integrated_Practices/Process Mr.Sigoillot], an process engineering expert, helped us to shape our project in a economical way: we decided our process should absolutely end on nanoparticle production in order to produce a highly valuable form.
+Moreover Mr. Sigoillot and Mr.Triboit brought us  both a crucial aspect of platinum pollution: sewage sludge are so polluted than people would pay to get rid of it! Thus a process starting from sewage sludge as a basic raw material would have positive financial and environmental balance!
-There is an '''urgency''' to find a way to produce it '''sustainably''' before '''2064''', its exhaustion date. It's probably better to think about '''how to change the economic pathway''' of platinum than to try to find an alternative metal to platinum since the only substiture to platinum, palladium has its reserves more depleted than the paltinum ones and should be exhausted in '''2024'''.
-The process we’ve designed allows the shaping of a '''circularized economy'''. Instead of being '''wasted''' in the environment, platinum can '''re-enter''' the economy thus making platinum production '''sustainable'''!
-<references/>
 {{:Team:Aix-Marseille/Template-Footer}}

Difference between revisions of "Team:Aix-Marseille/Integrated Practices"

Revision as of 19:20, 19 October 2016

Integrated Pratices