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Carbon-dioxide Fixation01:28

Carbon-dioxide Fixation

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Carbon dioxide fixation in prokaryotes enables the assimilation of inorganic carbon into organic molecules, supporting biosynthetic pathways, sustaining ecosystems, and contributing to the global carbon cycle. It also has industrial applications in carbon capture and bioproduct synthesis. Autotrophic organisms rely on this process to utilize CO₂ as a carbon source in diverse environments.The Calvin CycleThe Calvin cycle is the most widespread carbon fixation mechanism, primarily used by...
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Phase Diagrams02:39

Phase Diagrams

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A phase diagram combines plots of pressure versus temperature for the liquid-gas, solid-liquid, and solid-gas phase-transition equilibria of a substance. These diagrams indicate the physical states that exist under specific conditions of pressure and temperature and also provide the pressure dependence of the phase-transition temperatures (melting points, sublimation points, boiling points). Regions or areas labeled solid, liquid, and gas represent single phases, while lines or curves represent...
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Carbon Dioxide Transport in the Blood01:19

Carbon Dioxide Transport in the Blood

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Carbon dioxide (CO2) transport in the blood is critical to human physiology. On average, our body cells produce around 200 mL of CO2 per minute, precisely the quantity expelled by the lungs. This process involves the transportation of CO2 from the tissue cells to the lungs in three primary forms.
Forms of CO2 Transport
1. Dissolved in plasma: A small percentage (7-10%) of CO2 is transported and dissolved directly in the plasma.
2. Carbaminohemoglobin: Just over 20% of CO2 is chemically bound to...
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The Carbon Cycle01:14

The Carbon Cycle

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Carbon is the basis of all organic matter on Earth, and is recycled through the ecosystem in two primary processes: one in which carbon is exchanged among living organisms, and one in which carbon is cycled over long periods of time through fossilized organic remains, weathering of rocks, and volcanic activity. Human activities, including increased agricultural practices and the burning of fossil fuels, has greatly affected the balance of the natural carbon cycle.
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The Calvin Benson Cycle01:46

The Calvin Benson Cycle

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Ribulose 1,5- bisphosphate carboxylase/oxygenase (RuBisCo) is a critical enzyme that catalyzes carbon dioxide assimilation during photosynthesis. However, it is an inefficient enzyme, having an extremely slow catalytic rate. A typical enzyme can process about a thousand molecules per second; however, RuBisCo fixes only around three-carbon dioxides per second. Photosynthetic cells compensate for this slow rate by synthesizing very high amounts of RuBisCo, making it the most abundant single...
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Carbonation Shrinkage01:24

Carbonation Shrinkage

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Atmospheric CO2 penetrates the concrete's pores and, in the presence of moisture, forms carbonic acid, which then reacts with calcium hydroxide in the hydrated cement, forming calcium carbonate. This process reduces the concrete's volume and is termed carbonation shrinkage.
The concrete's permeability is slightly reduced as calcium carbonate produced during the reaction fills its pores. Furthermore, its strength is slightly enhanced as the water released during the reaction...
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Related Experiment Video

Updated: Sep 2, 2025

Author Spotlight: Standardizing the Development of Amine-Based Silica Composites as CO2 Adsorbents for Direct Air Capture
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Author Spotlight: Standardizing the Development of Amine-Based Silica Composites as CO2 Adsorbents for Direct Air Capture

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Recent advances in CO2 capture and reduction.

Kecheng Wei1, Huanqin Guan1, Qiang Luo2

  • 1Department of Chemistry, Brown University, Providence, Rhode Island 02912, USA. ssun@brown.edu.

Nanoscale
|August 9, 2022
PubMed
Summary
This summary is machine-generated.

Negative carbon emission technologies are crucial for managing excessive carbon dioxide (CO2) emissions. This review covers advances in CO2 capture using adsorbents and conversion via thermochemical hydrogenation and electrochemical reduction, focusing on efficient catalysts and integrated processes.

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Area of Science:

  • Chemical Engineering
  • Materials Science
  • Environmental Science

Background:

  • Continuous anthropogenic CO2 emissions necessitate negative carbon emission technologies.
  • Efficient capture and conversion of CO2 into valuable chemicals are in high demand.

Purpose of the Study:

  • To review recent advancements in CO2 capture and conversion chemistry and processes.
  • To highlight integrated approaches for optimizing energy efficiency in CO2 capture and conversion.

Main Methods:

  • Summarizing adsorbent materials for CO2 capture (hydroxide-, amine-, MOF-based).
  • Reviewing thermochemical CO2 hydrogenation and electrochemical CO2 reduction.
  • Discussing catalyst development and catalyst-electrolyte interface engineering.

Main Results:

  • Various adsorbent materials show promise for CO2 capture.
  • Thermochemical and electrochemical CO2 conversion methods are advancing with efficient catalysts.
  • Integrated CO2 capture and conversion processes improve energy efficiency.

Conclusions:

  • Developing efficient catalysts and engineered interfaces are key for CO2 conversion.
  • Integrating capture and conversion processes optimizes energy efficiency.
  • Coupling direct air capture with CO2 conversion offers a pathway to negative emissions and energy sustainability.