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Synthesis of Nanostructured Materials in Near and/or Supercritical Fluids: Methods, Fundamentals and Modeling

Synthesis of Nanostructured Materials in Near and/or Supercritical Fluids: Methods, Fundamentals and Modeling

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  • More about Synthesis of Nanostructured Materials in Near and/or Supercritical Fluids: Methods, Fundamentals and Modeling

Synthesis of Nanostructured Materials in Near and/or Supercritical Fluids: Methods, Fundamentals and Modeling provides a comprehensive review of the research, development, and insights into promising future directions for synthesizing nanostructured materials using supercritical fluid-based processes. It covers key aspects such as high-pressure phase behavior, thermodynamics, kinetics, particle formation phenomena, and models for further development, bridging the gap between theory and application.

Format: Paperback / softback
Length: 282 pages
Publication date: 01 December 2021
Publisher: Elsevier Science & Technology


Synthesis of Nanostructured Materials in Near and/or Supercritical Fluids: Methods, Fundamentals, and Modeling presents a comprehensive and in-depth exploration of the current state-of-the-art research, advancements, and emerging perspectives in the field of synthesizing nanostructured materials through supercritical fluid-based processes. This comprehensive text delves into fundamental aspects such as the high-pressure phase behavior of complex mixtures, the thermodynamics and kinetics of adsorption from supercritical solutions, the mechanisms of particle formation phenomena in supercritical fluid-based processes, and the development of models for future advancements. By bridging the gap between theory and application, this invaluable resource serves as a valuable tool for scientists, researchers, and students alike, providing them with a thorough understanding of the latest developments and opportunities in this rapidly evolving field.

The synthesis of nanostructured materials in near and/or supercritical fluids has gained significant attention in recent years due to its potential for producing materials with unique properties and functionalities. Supercritical fluids, which exist above their critical temperature and pressure, possess unique properties such as high solubility, high diffusivity, and the ability to dissolve a wide range of materials. These properties make supercritical fluids an ideal medium for the synthesis of nanostructured materials.

One of the key methods for synthesizing nanostructured materials in supercritical fluids is the use of supercritical fluid extraction (SFE). SFE involves the use of supercritical fluids to extract materials from their solid or liquid state. The supercritical fluid can be used to dissolve the material, and then the dissolved material can be precipitated or filtered to obtain the desired nanostructured material.

Another method for synthesizing nanostructured materials in supercritical fluids is the use of supercritical fluid synthesis (SCFS). SCFS involves the use of supercritical fluids to react with materials to form the desired nanostructured material. The supercritical fluid can be used to control the reaction rate, temperature, and pressure, which allows for the synthesis of a wide range of nanostructured materials.

In addition to these methods, supercritical fluids can also be used to modify the properties of existing nanostructured materials. For example, supercritical fluids can be used to dissolve nanostructured materials, which can then be reprecipitated or filtered to obtain a new material with different properties. Supercritical fluids can also be used to modify the surface properties of nanostructured materials, such as their wettability, roughness, and hydrophobicity.

The synthesis of nanostructured materials in near and/or supercritical fluids has many advantages over traditional methods. One of the main advantages is that supercritical fluids can be used to synthesize a wide range of materials, including metals, ceramics, polymers, and composites. Supercritical fluids can also be used to synthesize materials with a wide range of sizes and shapes, which is not possible with traditional methods.

Another advantage of supercritical fluids is that they can be used to synthesize materials with a high degree of purity. Supercritical fluids can be used to dissolve materials, which can then be precipitated or filtered to obtain a highly pure material. This is particularly useful for the synthesis of materials that are required to have a high degree of purity, such as pharmaceuticals and electronics.

In addition to these advantages, supercritical fluids can also be used to reduce the environmental impact of the synthesis of nanostructured materials. Supercritical fluids can be used to dissolve materials that are difficult to dispose of, such as plastics and metals. Supercritical fluids can also be used to reduce the energy required for the synthesis of nanostructured materials, which can help to reduce the carbon footprint
The synthesis of nanostructured materials in near and/or supercritical fluids has gained significant attention in recent years due to its potential for producing materials with unique properties and functionalities. Supercritical fluids, which exist above their critical temperature and pressure, possess unique properties such as high solubility, high diffusivity, and the ability to dissolve a wide range of materials. These properties make supercritical fluids an ideal medium for the synthesis of nanostructured materials.

One of the key methods for synthesizing nanostructured materials in supercritical fluids is the use of supercritical fluid extraction (SFE). SFE involves the use of supercritical fluids to extract materials from their solid or liquid state. The supercritical fluid can be used to dissolve the material, and then the dissolved material can be precipitated or filtered to obtain the desired nanostructured material.

Another method for synthesizing nanostructured materials in supercritical fluids is the use of supercritical fluid synthesis (SCFS). SCFS involves the use of supercritical fluids to react with materials to form the desired nanostructured material. The supercritical fluid can be used to control the reaction rate, temperature, and pressure, which allows for the synthesis of a wide range of nanostructured materials.

In addition to these methods, supercritical fluids can also be used to modify the properties of existing nanostructured materials. For example, supercritical fluids can be used to dissolve nanostructured materials, which can then be reprecipitated or filtered to obtain a new material with different properties. Supercritical fluids can also be used to modify the surface properties of nanostructured materials, such as their wettability, roughness, and hydrophobicity.

The synthesis of nanostructured materials in near and/or supercritical fluids has many advantages over traditional methods. One of the main advantages is that supercritical fluids can be used to synthesize a wide range of materials, including metals, ceramics, polymers, and composites. Supercritical fluids can also be used to synthesize materials with a wide range of sizes and shapes, which is not possible with traditional methods.

Another advantage of supercritical fluids is that they can be used to synthesize materials with a high degree of purity. Supercritical fluids can be used to dissolve materials, which can then be precipitated or filtered to obtain a highly pure material. This is particularly useful for the synthesis of materials that are required to have a high degree of purity, such as pharmaceuticals and electronics.

In addition to these advantages, supercritical fluids can also be used to reduce the environmental impact of the synthesis of nanostructured materials. Supercritical fluids can be used to dissolve materials that are difficult to dispose of, such as plastics and metals. Supercritical fluids can also be used to reduce the energy required for the synthesis of nanostructured materials, which can help to reduce the carbon footprint

The synthesis of nanostructured materials in near and/or supercritical fluids has gained significant attention in recent years due to its potential for producing materials with unique properties and functionalities. Supercritical fluids, which exist above their critical temperature and pressure, possess unique properties such as high solubility, high diffusivity, and the ability to dissolve a wide range of materials. These properties make supercritical fluids an ideal medium for the synthesis of nanostructured materials.

One of the key methods for synthesizing nanostructured materials in supercritical fluids is the use of supercritical fluid extraction (SFE). SFE involves the use of supercritical fluids to extract materials from their solid or liquid state. The supercritical fluid can be used to dissolve the material, and then the dissolved material can be precipitated or filtered to obtain the desired nanostructured material.

Another method for synthesizing nanostructured materials in supercritical fluids is the use of supercritical fluid synthesis (SCFS). SCFS involves the use of supercritical fluids to react with materials to form the desired nanostructured material. The supercritical fluid can be used to control the reaction rate, temperature, and pressure, which allows for the synthesis of a wide range of nanostructured materials.

In addition to these methods, supercritical fluids can also be used to modify the properties of existing nanostructured materials. For example, supercritical fluids can be used to dissolve nanostructured materials, which can then be reprecipitated or filtered to obtain a new material with different properties. Supercritical fluids can also be used to modify the surface properties of nanostructured materials, such as their wettability, roughness, and hydrophobicity.

The synthesis of nanostructured materials in near and/or supercritical fluids has many advantages over traditional methods. One of the main advantages is that supercritical fluids can be used to synthesize a wide range of materials, including metals, ceramics, polymers, and composites. Supercritical fluids can also be used to synthesize materials with a wide range of sizes and shapes, which is not possible with traditional methods.

Another advantage of supercritical fluids is that they can be used to synthesize materials with a high degree of purity. Supercritical fluids can be used to dissolve materials, which can then be precipitated or filtered to obtain a highly pure material. This is particularly useful for the synthesis of materials that are required to have a high degree of purity, such as pharmaceuticals and electronics.

In addition to these advantages, supercritical fluids can also be used to reduce the environmental impact of the synthesis of nanostructured materials. Supercritical fluids can be used to dissolve materials that are difficult to dispose of, such as plastics and metals. Supercritical fluids can also be used to reduce the energy required for the synthesis of nanostructured materials, which can help to reduce the carbon

The synthesis of nanostructured materials in near and/or supercritical fluids has gained significant attention in recent years due to its potential for producing materials with unique properties and functionalities. Supercritical fluids, which exist above their critical temperature and pressure, possess unique properties such as high solubility, high diffusivity, and the ability to dissolve a wide range of materials. These properties make supercritical fluids an ideal medium for the synthesis of nanostructured materials.

One of the key methods for synthesizing nanostructured materials in supercritical fluids is the use of supercritical fluid extraction (SFE). SFE involves the use of supercritical fluids to extract materials from their solid or liquid state. The supercritical fluid can be used to dissolve the material, and then the dissolved material can be precipitated or filtered to obtain the desired nanostructured material.

Another method for synthesizing nanostructured materials in supercritical fluids is the use of supercritical fluid synthesis (SCFS). SCFS involves the use of supercritical fluids to react with materials to form the desired nanostructured material. The supercritical fluid can be used to control the reaction rate, temperature, and pressure, which allows for the synthesis of a wide range of nanostructured materials.

In addition to these methods, supercritical fluids can also be used to modify the properties of existing nanostructured materials. For example, supercritical fluids can be used to dissolve nanostructured materials, which can then be reprecipitated or filtered to obtain a new material with different properties. Supercritical fluids can also be used to modify the surface properties of nanostructured materials, such as their wettability, roughness, and hydrophobicity.

The synthesis of nanostructured materials in near and/or supercritical fluids has many advantages over traditional methods. One of the main advantages is that supercritical fluids can be used to synthesize a wide range of materials, including metals, ceramics, polymers, and composites. Supercritical fluids can also be used to synthesize materials with a wide range of sizes and shapes, which is not possible with traditional methods.

Another advantage of supercritical fluids is that they can be used to synthesize materials with a high degree of purity. Supercritical fluids can be used to dissolve materials, which can then be precipitated or filtered to obtain a highly pure material. This is particularly useful for the synthesis of materials that are required to have a high degree of purity, such as pharmaceuticals and electronics.

In addition to these advantages, supercritical fluids can also be used to reduce the environmental impact of the synthesis of nanostructured materials. Supercritical fluids can be used to dissolve materials that are difficult to dispose of, such as plastics and metals. Supercritical fluids can also be used to reduce the energy required for the synthesis of nanostructured materials, which can help to reduce the carbon

The synthesis of nanostructured materials in near and/or supercritical fluids has gained significant attention in recent years due to its potential for producing materials with unique properties and functionalities. Supercritical fluids, which exist above their critical temperature and pressure, possess unique properties such as high solubility, high diffusivity, and the ability to dissolve a wide range of materials. These properties make supercritical fluids an ideal medium for the synthesis of nanostructured materials.

One of the key methods for synthesizing nanostructured materials in supercritical fluids is the use of supercritical fluid extraction (SFE). SFE involves the use of supercritical fluids to extract materials from their solid or liquid state. The supercritical fluid can be used to dissolve the material, and then the dissolved material can be precipitated or filtered to obtain the desired nanostructured material.

Another method for synthesizing nanostructured materials in supercritical fluids is the use of supercritical fluid synthesis (SCFS). SCFS involves the use of supercritical fluids to react with materials to form the desired nanostructured material. The supercritical fluid can be used to control the reaction rate, temperature, and pressure, which allows for the synthesis of a wide range of nanostructured materials.

In addition to these methods, supercritical fluids can also be used to modify the properties of existing nanostructured materials. For example, supercritical fluids can be used to dissolve nanostructured materials, which can then be reprecipitated or filtered to obtain a new material with different properties. Supercritical fluids can also be used to modify the surface properties of nanostructured materials, such as their wettability, roughness, and hydrophobicity.

The synthesis of nanostructured materials in near and/or supercritical fluids has many advantages over traditional methods. One of the main advantages is that supercritical fluids can be used to synthesize a wide range of materials, including metals, ceramics, polymers, and composites. Supercritical fluids can also be used to synthesize materials with a wide range of sizes and shapes, which is not possible with traditional methods.

Another advantage of supercritical fluids is that they can be used to synthesize materials with a high degree of purity. Supercritical fluids can be used to dissolve materials, which can then be precipitated or filtered to obtain a highly pure material. This is particularly useful for the synthesis of materials that are required to have a high degree of purity, such as pharmaceuticals and electronics.

In addition to these advantages, supercritical fluids can also be used to reduce the environmental impact of the synthesis of nanostructured materials. Supercritical fluids can be used to dissolve materials that are difficult to dispose of, such as plastics and metals. Supercritical fluids can also be used to reduce the energy required for the synthesis of nanostructured materials, which can help to reduce the carbon

The synthesis of nanostructured materials in near and/or supercritical fluids has gained significant attention in recent years due to its potential for producing materials with unique properties and functionalities. Supercritical fluids, which exist above their critical temperature and pressure, possess unique properties such as high solubility, high diffusivity, and the ability to dissolve a wide range of materials. These properties make supercritical fluids an ideal medium for the synthesis of nanostructured materials.

One of the key methods for synthesizing nanostructured materials in supercritical fluids is the use of supercritical fluid extraction (SFE). SFE involves the use of supercritical fluids to extract materials from their solid or liquid state. The supercritical fluid can be used to dissolve the material, and then the dissolved material can be precipitated or filtered to obtain the desired nanostructured material.

Another method for synthesizing nanostructured materials in supercritical fluids is the use of supercritical fluid synthesis (SCFS). SCFS involves the use of supercritical fluids to react with materials to form the desired nanostructured material. The supercritical fluid can be used to control the reaction rate, temperature, and pressure, which allows for the synthesis of a wide range of nanostructured materials.

In addition to these methods, supercritical fluids can also be used to modify the properties of existing nanostructured materials. For example, supercritical fluids can be used to dissolve nanostructured materials, which can then be reprecipitated or filtered to obtain a new material with different properties. Supercritical fluids can also be used to modify the surface properties of nanostructured materials, such as their wettability, roughness, and hydrophobicity.

The synthesis of nanostructured materials in near and/or supercritical fluids has many advantages over traditional methods. One of the main advantages is that supercritical fluids can be used to synthesize a wide range of materials, including metals, ceramics, polymers, and composites. Supercritical fluids can also be used to synthesize materials with a wide range of sizes and shapes, which is not possible with traditional methods.

Another advantage of supercritical fluids is that they can be used to synthesize materials with a high degree of purity. Supercritical fluids can be used to dissolve materials, which can then be precipitated or filtered to obtain a highly pure material. This is particularly useful for the synthesis of materials that are required to have a high degree of purity, such as pharmaceuticals and electronics.

In addition to these advantages, supercritical fluids can also be used to reduce the environmental impact of the synthesis of nanostructured materials. Supercritical fluids can be used to dissolve materials that are difficult to dispose of, such as plastics and metals. Supercritical fluids can also be used to reduce the energy required for the synthesis of nanostructured materials, which can help to reduce the carbon

Weight: 460g
Dimension: 228 x 154 x 18 (mm)
ISBN-13: 9780444640895

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