Not trying to challenge you in this comment: I legit want to know more.
I’m I’m agreement on the need for transformation of C. I also agree that this is more than likely going to have to come from natural sources.
Why won’t geological sequestration (e.g., chemically bonding it to rock, concrete, or Tailings) work? The thing I like about this method is that its super long term transformation (basically removal) as long as pH is controlled.
What methods look promising? I saw some biocell things that looked cool but way too niche to be practical.
Cutting emissions is definitely a key part of all this, but there’s a lag phase before the warming if the emissions we emit now are realized. On top of this, there is woefully limited regulations around methane and n2o in key sectors.
We don’t need transformation of C, we need transformation of just CO2 in other C based compounds.
The reason why capture doesn’t really work, is because you need to spend a lot of energy to break CO bonds. Therefore any solution is based on very weak chemical bonds. It means that CO2 desorbes over time, substituted by other gases. And adsorption needs to break an equilibrium, against “natural direction of processes”, i.e. requires energy.
Unless we find an efficient version of artificial photosynthesis, everything else is a waste of resources
We don’t need transformation of C, we need transformation of just CO2 in other C based compounds.
I think I’m being too general in my wording, and you’re getting hung up - an issue with typing on mobile is that I abbreviate everything. I mean CO2 sequestration/transformation.
The reason why capture doesn’t really work, is because you need to spend a lot of energy to break CO bonds. Therefore any solution is based on very weak chemical bonds. It means that CO2 desorbes over time, substituted by other gases
Yet we see this in the biological sphere, where CO2 is taken into the plants, the plants die, get broken down, some of the CO2 they transformed into biomass is decomposed, and released as CO2 by the microbial community. Some of it (climate permitting) is transformed into soil organic carbon, which has multiple fractions. Some are short-lived, and readily broken down by the microbial community (more CO2 release); some fractions (humus, or protected SOC) are much longer lived, and result in a net loss from the C system.
All of this is unsurprising, given that this is the natural system, and therefore the system ultimately balances out, due to multiple sources of inputs and outputs.
I agree about cost/energy to break CO bonds, however, the examples I’ve seen seem to indicate that it’s more stable long term.
Biochar seems interesting too, yet that requires a lot of energy input, and soil application has mixed results. You could make biochar, and then stuff it deeper into the soil or into geological formations, perhaps. Better if that biochar comes from food wastes, livestock production wastes etc. than plants.
As I said, it’s a fucking huge problem with a million facets. We’re so categorically fucked…
Not trying to challenge you in this comment: I legit want to know more.
I’m I’m agreement on the need for transformation of C. I also agree that this is more than likely going to have to come from natural sources.
Why won’t geological sequestration (e.g., chemically bonding it to rock, concrete, or Tailings) work? The thing I like about this method is that its super long term transformation (basically removal) as long as pH is controlled.
What methods look promising? I saw some biocell things that looked cool but way too niche to be practical.
Cutting emissions is definitely a key part of all this, but there’s a lag phase before the warming if the emissions we emit now are realized. On top of this, there is woefully limited regulations around methane and n2o in key sectors.
We don’t need transformation of C, we need transformation of just CO2 in other C based compounds.
The reason why capture doesn’t really work, is because you need to spend a lot of energy to break CO bonds. Therefore any solution is based on very weak chemical bonds. It means that CO2 desorbes over time, substituted by other gases. And adsorption needs to break an equilibrium, against “natural direction of processes”, i.e. requires energy.
Unless we find an efficient version of artificial photosynthesis, everything else is a waste of resources
I think I’m being too general in my wording, and you’re getting hung up - an issue with typing on mobile is that I abbreviate everything. I mean CO2 sequestration/transformation.
Yet we see this in the biological sphere, where CO2 is taken into the plants, the plants die, get broken down, some of the CO2 they transformed into biomass is decomposed, and released as CO2 by the microbial community. Some of it (climate permitting) is transformed into soil organic carbon, which has multiple fractions. Some are short-lived, and readily broken down by the microbial community (more CO2 release); some fractions (humus, or protected SOC) are much longer lived, and result in a net loss from the C system.
All of this is unsurprising, given that this is the natural system, and therefore the system ultimately balances out, due to multiple sources of inputs and outputs.
I agree about cost/energy to break CO bonds, however, the examples I’ve seen seem to indicate that it’s more stable long term.
Biochar seems interesting too, yet that requires a lot of energy input, and soil application has mixed results. You could make biochar, and then stuff it deeper into the soil or into geological formations, perhaps. Better if that biochar comes from food wastes, livestock production wastes etc. than plants.
As I said, it’s a fucking huge problem with a million facets. We’re so categorically fucked…