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Related Concept Videos

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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Physical Properties Affecting Solubility02:19

Physical Properties Affecting Solubility

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Solutions of Gases in Liquids
As for any solution, the solubility of a gas in a liquid is affected by the attractive intermolecular forces between solute and solvent species. Unlike solid and liquid solutes, however, there is no solute-solute intermolecular attraction to overcome when a gaseous solute dissolves in a liquid solvent since the atoms or molecules comprising a gas are far separated and experience negligible interactions. Consequently, solute-solvent interactions are the sole...
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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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Turbulent Flow: Problem Solving01:09

Turbulent Flow: Problem Solving

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Carbonation is a process used to dissolve carbon dioxide gas in a liquid, commonly used in the production of carbonated beverages. Achieving efficient carbonation requires careful control of temperature, pressure, and flow conditions. By adjusting these parameters, carbonation efficiency can be maximized, producing a higher concentration of CO2 in the liquid.
Temperature is a key factor in CO2 solubility. In this case, the CO2 gas and the liquid are cooled to 20°C. Lower temperatures...
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Porosity and Absorption of Aggregate01:20

Porosity and Absorption of Aggregate

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Aggregates contain pores of varying sizes; while some are completely enclosed within the particles, others open onto the surface, allowing water to penetrate. The porosity of aggregates is a major factor contributing to the overall porosity of concrete, given that aggregates constitute about three-quarters of concrete's volume.
When all pores in an aggregate are filled with water, the aggregate is considered saturated and surface-dry. If left in dry air, water will evaporate until the...
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Updated: Oct 26, 2025

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Porous materials for carbon dioxide separations.

Rebecca L Siegelman1,2,3, Eugene J Kim1, Jeffrey R Long4,5,6

  • 1Department of Chemistry, University of California, Berkeley, CA, USA.

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|July 29, 2021
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Summary

Carbon capture and sequestration (CCS) is vital for climate change mitigation. This review explores advanced porous materials for CO2 capture, addressing sector-specific challenges to accelerate CCS deployment.

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Area of Science:

  • Materials Science
  • Chemical Engineering
  • Environmental Science

Background:

  • Global investment in climate change mitigation drives interest in carbon capture and sequestration (CCS).
  • CCS technologies are crucial for reducing emissions from large point sources and hard-to-abate industries.
  • CCS also supports low-carbon fuel production and atmospheric CO2 removal.

Purpose of the Study:

  • To review the development of porous materials as next-generation sorbents for CO2 capture.
  • To address stream- and sector-specific challenges in CCS applications.
  • To discuss material science needs for expanding CCS technology deployment.

Main Methods:

  • Literature review of porous materials for CO2 capture.
  • Analysis of CCS applications in various industrial sectors.
  • Case studies within the evolving energy landscape.

Main Results:

  • Porous materials show promise as advanced sorbents for CO2 capture.
  • Sector-specific challenges and opportunities for CCS implementation are identified.
  • The review highlights the critical role of materials science in CCS advancement.

Conclusions:

  • Continued innovation in porous materials is essential for effective CO2 capture.
  • Addressing sector-specific needs will facilitate broader CCS deployment.
  • Collaboration between materials scientists and engineers is key to advancing carbon capture technologies.