wl-hydrophilic-polymer/task1/task1-paper-info/ANTI-FOG US10241237B2.json

{
    "content": "The synthesis of hydrophilic polymers involves functional groups such as sulfonated resins and non-ionic surfactants containing hydroxyl reactive groups, which enhance the hydrophilicity of the polymers by increasing their water absorption and improving interactions with water, leading to better anti-fog properties.The hydrophilic polymers synthesized include polyurethane segments characterized by urethane groups containing carbonyl groups that enhance hydrophilicity, as well as acrylic polymers incorporating functional groups such as carboxylates from acrylic acid and dimethylol propionic acid, which enhance interactions with water through ionic and hydrogen bonding.The text excerpt does not provide specific information about the monomer structures or functional groups that enhance the hydrophilicity of the corresponding polymers.The synthesis of hydrophilic polymers utilizes monomers such as fatty alcohols with hydroxyl groups, including dodecyl alcohol, cetyl alcohol, and oleyl alcohol, which enhance hydrophilicity through their ability to form hydrogen bonds with water, thus increasing solubility and interaction; additionally, polyethoxylated and polypropoxylated fatty alcohols contain multiple ethylene oxide or propylene oxide repeat units, contributing to improved water affinity and minimizing surfactant leaching due to increased hydrophilic segments.The monomers used for synthesizing hydrophilic polymers include 2-[Methoxy(polyethyleneoxy)propyl] which contains ether functional groups that enhance hydrophilicity by forming hydrogen bonds with water, and trimethoxysilane which can also interact with water due to its silanol groups.The synthesis involves PEG-based dicarboxylic acid ammonium salts, which possess functional groups such as carboxylic acids and ammonium that enhance the hydrophilicity of the polymers due to their ability to form hydrogen bonds and ionic interactions with water.The hydrophilicity of the synthesized polymers is enhanced by the presence of functional groups in the hydrophilic aziridine crosslinkers, which improve interactions with water due to the ability of these groups to form hydrogen bonds with water molecules.The synthesis involved monomers such as PEG-modified DVSZN004, which contains ether functional groups that enhance hydrophilicity by increasing hydrogen bonding capacity with water molecules, thereby improving water interactions and promoting wettability.The hydrophilic polymers are synthesized using monomers such as poly(ethylene glycol) which contains hydroxyl functional groups that enhance the hydrophilicity of the resulting polymers, facilitating strong interactions with water through hydrogen bonding.PZ-2382 includes functional groups that enhance the hydrophilicity of the polymers, while PEG-based modified DVSZN004 provides additional hydrophilic properties due to its ethylene glycol units, which facilitate interactions with water through hydrogen bonding.The synthesis involved PEG-based modified DVSZN004, which contains functional groups such as hydroxyl groups that enhance the hydrophilicity of the corresponding polymers by forming strong hydrogen bonds with water molecules, leading to improved water interaction.The synthesis involves monomers such as PEG-based modified DVSZN004, which contains ether functional groups that enhance hydrophilicity through their ability to form hydrogen bonds with water, leading to improved interactions and solubility in aqueous environments.The monomers used for synthesizing hydrophilic polymers include PEG-modified DVSZN004, which contains polyethylene glycol (PEG) as a functional group that enhances hydrophilicity, and water, which enhances interactions with water due to its polar nature and ability to form hydrogen bonds.The synthesis of hydrophilic polymers involved the use of PZ-2382, which contains hydrophilic aziridine crosslinkers, enhancing hydrophilicity due to their ability to form hydrogen bonds with water molecules, thereby increasing interactions with water and improving the overall performance of the coated films."
}
	`{`
	"content": "The synthesis of hydrophilic polymers involves functional groups such as sulfonated resins and non-ionic surfactants containing hydroxyl reactive groups, which enhance the hydrophilicity of the polymers by increasing their water absorption and improving interactions with water, leading to better anti-fog properties.The hydrophilic polymers synthesized include polyurethane segments characterized by urethane groups containing carbonyl groups that enhance hydrophilicity, as well as acrylic polymers incorporating functional groups such as carboxylates from acrylic acid and dimethylol propionic acid, which enhance interactions with water through ionic and hydrogen bonding.The text excerpt does not provide specific information about the monomer structures or functional groups that enhance the hydrophilicity of the corresponding polymers.The synthesis of hydrophilic polymers utilizes monomers such as fatty alcohols with hydroxyl groups, including dodecyl alcohol, cetyl alcohol, and oleyl alcohol, which enhance hydrophilicity through their ability to form hydrogen bonds with water, thus increasing solubility and interaction; additionally, polyethoxylated and polypropoxylated fatty alcohols contain multiple ethylene oxide or propylene oxide repeat units, contributing to improved water affinity and minimizing surfactant leaching due to increased hydrophilic segments.The monomers used for synthesizing hydrophilic polymers include 2-[Methoxy(polyethyleneoxy)propyl] which contains ether functional groups that enhance hydrophilicity by forming hydrogen bonds with water, and trimethoxysilane which can also interact with water due to its silanol groups.The synthesis involves PEG-based dicarboxylic acid ammonium salts, which possess functional groups such as carboxylic acids and ammonium that enhance the hydrophilicity of the polymers due to their ability to form hydrogen bonds and ionic interactions with water.The hydrophilicity of the synthesized polymers is enhanced by the presence of functional groups in the hydrophilic aziridine crosslinkers, which improve interactions with water due to the ability of these groups to form hydrogen bonds with water molecules.The synthesis involved monomers such as PEG-modified DVSZN004, which contains ether functional groups that enhance hydrophilicity by increasing hydrogen bonding capacity with water molecules, thereby improving water interactions and promoting wettability.The hydrophilic polymers are synthesized using monomers such as poly(ethylene glycol) which contains hydroxyl functional groups that enhance the hydrophilicity of the resulting polymers, facilitating strong interactions with water through hydrogen bonding.PZ-2382 includes functional groups that enhance the hydrophilicity of the polymers, while PEG-based modified DVSZN004 provides additional hydrophilic properties due to its ethylene glycol units, which facilitate interactions with water through hydrogen bonding.The synthesis involved PEG-based modified DVSZN004, which contains functional groups such as hydroxyl groups that enhance the hydrophilicity of the corresponding polymers by forming strong hydrogen bonds with water molecules, leading to improved water interaction.The synthesis involves monomers such as PEG-based modified DVSZN004, which contains ether functional groups that enhance hydrophilicity through their ability to form hydrogen bonds with water, leading to improved interactions and solubility in aqueous environments.The monomers used for synthesizing hydrophilic polymers include PEG-modified DVSZN004, which contains polyethylene glycol (PEG) as a functional group that enhances hydrophilicity, and water, which enhances interactions with water due to its polar nature and ability to form hydrogen bonds.The synthesis of hydrophilic polymers involved the use of PZ-2382, which contains hydrophilic aziridine crosslinkers, enhancing hydrophilicity due to their ability to form hydrogen bonds with water molecules, thereby increasing interactions with water and improving the overall performance of the coated films."
	`}`