Metal Organic Frameworks Episode 2: Storing and Separating Gases with MOFs

Micromeritics

12 Dec 201803:27

Summary

TLDRThe discussion centers on the distinct challenges of gas storage and separation, emphasizing the importance of material properties such as polarizability and size. By engineering materials with specific characteristics, researchers can optimize gas storage and facilitate selective separation processes. Applications range from energy transformation using metal-organic frameworks (MOFs) to healthcare innovations like on-demand oxygen delivery for respiratory patients. The speaker highlights the significance of a collaborative team and advanced instrumentation in driving these innovative solutions, focusing on both energy-related and defense applications.

Takeaways

😀 Storing and separating gases are distinct issues that require different approaches.
😀 The focus on gas storage is on deliverable capacity rather than total storage capacity.
😀 High pressures in gas storage systems can be costly and should be minimized.
😀 Materials can be designed to be stickier for specific gases or impurities for effective separation.
😀 Gases vary in properties such as polarizability (stickiness) and size, affecting their storage methods.
😀 Programmable materials can be developed to selectively store specific gases based on their properties.
😀 Metal-organic frameworks (MOFs) are highly porous materials ideal for storing gases like natural gas and hydrogen.
😀 MOFs can also be used in energy-intensive separations and alternative energy applications.
😀 In healthcare, MOFs can facilitate on-demand oxygen delivery for patients with chronic respiratory conditions.
😀 A strong team and proper instruments are crucial for successful research and application development.

Q & A

What are the two main challenges addressed in gas storage and separation?
-The two main challenges are the effective storage of gases, focusing on deliverable capacity, and the separation of specific gases from mixtures, ensuring the removal of impurities.
Why is deliverable capacity important in gas storage?
-Deliverable capacity is important because it indicates how much gas can be retrieved from the storage system without resorting to high pressures, which can increase costs.
What unique properties of gases affect their storage methods?
-The unique properties that affect storage methods are the gases' polarizability, which relates to their stickiness, and their size.
How can programmable materials be utilized for gas separation?
-Programmable materials can be engineered to selectively store specific gases or separate them from others by altering the pore sizes or the hydrophobicity/hydrophilicity of the materials.
What role do metal-organic frameworks (MOFs) play in energy applications?
-MOFs are utilized to store gases like natural gas or hydrogen efficiently, which could have transformative effects on the energy sector.
In healthcare, how can MOFs benefit patients with chronic respiratory illnesses?
-MOFs can be used to provide on-demand delivery of oxygen to patients suffering from chronic respiratory illnesses, such as COPD.
What is the significance of team dynamics in the research mentioned?
-Team dynamics are significant because collaborative efforts among skilled researchers, including graduate students and postdocs, are essential for the success of complex projects in gas storage and separation.
What is the impact of high pressures on gas storage systems?
-High pressures can increase costs associated with gas storage, making it important to design systems that maximize gas retrieval at lower pressures.
How does the polarizability of a gas influence material selection?
-The polarizability of a gas influences material selection by determining how 'sticky' the material should be for effective gas storage or separation.
What applications beyond energy does the research team focus on?
-Beyond energy applications, the research team also focuses on defense-related applications and uses of MOFs in healthcare, such as drug delivery and enzyme immobilization.