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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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Carbon-dioxide Fixation01:28

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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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Bioremediation00:46

Bioremediation

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Bioremediation is the use of prokaryotes, fungi, or plants to remove pollutants from the environment. This process has been used to remove harmful toxins in groundwater as a byproduct of agricultural run-off and also to clean up oil spills.
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Energy Stored in Capacitors01:10

Energy Stored in Capacitors

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A parallel plate capacitor, when connected to a battery, develops a potential difference across its plates. This potential difference is key to the operation of the capacitor, as it determines how much electrical energy the capacitor can store.
By integrating the equation that relates voltage and current in a capacitor, one can derive an equation for the voltage across the capacitor at any given time. This equation is crucial in understanding and predicting the behavior of capacitors in...
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Energy Stored in a Capacitor01:12

Energy Stored in a Capacitor

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When an archer pulls the string in a bow, he saves the work done in the form of elastic potential energy. When he releases the string, the potential energy is released as kinetic energy of the arrow. A capacitor works on the same principle in which the work done is saved as electric potential energy. The potential energy (UC) could be calculated by measuring the work done (W) to charge the capacitor.
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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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Related Experiment Video

Updated: Mar 13, 2026

Author Spotlight: Standardizing the Development of Amine-Based Silica Composites as CO2 Adsorbents for Direct Air Capture
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Carbon Capture and Storage: concluding remarks.

G C Maitland1

  • 1Department of Chemical Engineering, Imperial College London, South Kensington Campus, London SW7 2AZ, UK. g.maitland@imperial.ac.uk.

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|October 11, 2016
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Summary
This summary is machine-generated.

Integrating materials and process design is crucial for effective Carbon Capture and Storage (CCS). Holistic simulation optimizes CCS and CO2 utilization (CCU) processes, meeting climate targets.

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Area of Science:

  • Chemical Engineering
  • Materials Science
  • Environmental Science

Background:

  • Carbon Capture and Storage (CCS) is vital for meeting COP21 greenhouse gas (GHG) reduction targets.
  • Current CCS discussions focus heavily on carbon capture technologies, excluding biological methods.

Purpose of the Study:

  • To synthesize key themes and messages from CCS discussions.
  • To contextualize CCS within broader carbon mitigation strategies.
  • To highlight the importance of integrated materials and process design.

Main Methods:

  • Analysis of 23 discussion papers, primarily on carbon capture technologies.
  • Integration of chemical and materials science perspectives.
  • Utilizing examples from discussion papers to illustrate integration potential.

Main Results:

  • A critical need for integrating materials and process design in CCS.
  • Process and materials simulation are enabling reverse materials molecular engineering.
  • Optimized CCS and CO2 utilization (CCU) processes are achievable through holistic approaches.

Conclusions:

  • Closer integration of materials and process design is essential for optimizing CCS and CCU.
  • Cross-disciplinary interactions and holistic approaches are key to developing cost-effective CCS.
  • Further research in capture materials, process innovation, and policy is needed.