Polymerization Inhibitor: N,N-Diethylhydroxylamine Used as an efficient polymerization inhibitor for alkene and vinyl monomers.
End-Polymerization Inhibitor: Acts as an effective inhibitor for end-polymerization.
Terminator in Emulsion Polymerization: An excellent terminator in the aulsion polymerization process of butadiene-styrene rubber.
Antioxidant for Unsaturated Oils and Resins: Used as an antioxidant to prevent oxidation in unsaturated oils and resins.
Stabilizer for Photosensitive Materials: A favorable stabilizer for photosensitive resins, aulsions, and synthetic resins.
Photochaical Smog Inhibitor: Helps reduce photochaical smog in environmental protection applications.
Corrosion Inhibitor: Used as a corrosion inhibitor for boiler feed water and steam heat exchangers.
Antioxidant in Photography: Used as an antioxidant in photographic processes.
N,N-Diethylhydroxylamine manufacturer
TEL: +86-632-3671188
FAX: +86-632-3671189
E-mail: [email protected]
ADD: No.1, Fuqian South Road, Xuecheng Chemical Industrial Park, Xuecheng District, Zaozhuang City, Shandong Province, China
What is N,N-Diethylhydroxylamine used for?

PESA is a green water-soluble polymer with non-phosphor and non-nitrogenn. PESA has good scale inhibition and dispersion properties on calcium carbonate, calcium sulfate, barium sulfate, strontium sulfate, calcium fluoride and silicon scale in water, and has good synergistic effect with phosphonate.
PESA is biodegradable and has a wide range of applications, especially for cooling water systems under high alkali, high hardness and high pH conditions, and can achieve high concentration multiple operation. PESA has good compatibility with chlorine and compatibility with other agents.

What is Polyepoxysuccinic Acid?

51274-37-4 refers to the product Polyepoxysuccinic Acid
PESA is a green water-soluble polymer with non-phosphor and non-nitrogenn. PESA has good scale inhibition and dispersion properties on calcium carbonate, calcium sulfate, barium sulfate, strontium sulfate, calcium fluoride and silicon scale in water, and has good synergistic effect with phosphonate.
PESA is biodegradable and has a wide range of applications, especially for cooling water systems under high alkali, high hardness and high pH conditions, and can achieve high concentration multiple operation. PESA has good compatibility with chlorine and compatibility with other agents.
cas number 51274-37-4 is what products

DBNPA (2,2-Dibromo-3-Nitrilo-Propionamide) is a highly effective antimicrobial and biocidal compound widely used in various industrial and commercial applications. Below is a detailed introduction to its characteristics, applications, and other relevant information:
Chemical Properties and Structure
Chemical Formula: C3H2ON2Br2
Molecular Structure: Contains a cyanoacetamide backbone with two bromine atoms attached, giving it strong electrophilicity and reactivity against biological molecules.
Physical Properties:
Appears as a white to off-white crystalline powder or solid.
Solubility: Sparingly soluble in water but more soluble in polar organic solvents (e.g., acetone, ethanol).
Melting Point: Approximately 122–125°C.
Chemical Reactivity: Releases bromine ions in aqueous solutions, which disrupt microbial cell membranes and enzymes, leading to cell death.
Applications
Industrial Water Treatment:
Used in cooling water systems, boilers, and pipelines to prevent biofouling (slime, algae, and bacterial growth).
Controls microbial-induced corrosion (MIC) by eliminating the microbial communities that cause corrosion.
Oil and Gas Industry:
Applied in drilling fluids, fracturing fluids, and production systems to prevent microbial degradation of fluids and equipment corrosion.
Helps maintain the efficiency of oil recovery processes by reducing biofilm formation.
Paints and Coatings:
Added as a preservative to water-based paints, inks, and adhesives to prevent microbial spoilage, extending product shelf life.
Textiles and Leather:
Used in textile finishing to inhibit mold and bacteria growth, especially in humid environments.
Paper and Pulp Industry:
Controls slime formation in paper mills, improving paper quality and reducing equipment blockages.
Agriculture and Horticulture:
As a disinfectant for greenhouses, irrigation systems, and storage facilities to prevent plant pathogens.
Main Manufacturers
Kairui Chemistry Co., Ltd.:has experiences of more than 20 years in the R&D, production management and upstream&downstream of supply chain management , as well as more than 15 years' export experiences, fast quotation system and the professional dangerous goods operation team, which ensure timely delivery and professional&satisfied service for global clients. Until now, our products have been exported to more than 70 countries & regions.

DBNPA Manufacturer & DBNPA latest Price

Chemical Structure and Properties
Chemical Structure: Acrylic Homopolymer is a high-molecular polymer formed by the polymerization of acrylic acid monomers. The molecular chain is mainly composed of repeating acrylic acid units, with a general structural formula of [-CH₂-CH(COOH)-]ₙ, where n represents the degree of polymerization, determining the molecular weight and properties of the polymer.
Physical Properties: Typically a colorless to light yellow transparent liquid, and some appear as white powder or granular. It has good solubility, dissolving in water to form a uniform solution, and can also dissolve in polar organic solvents such as ethanol and acetone. Additionally, its viscosity increases with the increase of molecular weight and concentration.
Chemical Properties: The molecular chain contains carboxyl groups (-COOH), giving it certain acidity, which can undergo neutralization reaction with alkalis to form corresponding salts. Meanwhile, carboxyl groups can participate in chemical reactions such as esterification and amidation, modifying the polymer or crosslinking with other substances to improve performance and meet different application requirements. It also has good thermal stability and oxidation resistance, maintaining structural and performance stability within a certain temperature range and oxidative environment.
Application Fields
Water Treatment: As a scale inhibitor and dispersant, it can inhibit the crystallization and precipitation of insoluble salts such as calcium carbonate, calcium sulfate, and barium sulfate, preventing scale formation on pipes and equipment surfaces. It is widely used in industrial circulating cooling water systems, boiler water systems, reverse osmosis water treatment systems, etc., to improve heat transfer efficiency and service life of equipment.
Textile and Dyeing Industry: Used as a textile sizing agent to enhance the adhesion of sizing to fibers, making yarn smoother during weaving and reducing breakage; as a dyeing auxiliary to improve the dispersibility and permeability of dyes, enhancing dyeing uniformity and color fastness, and also playing a role in anti-staining and color fixing.
Coatings and Adhesives: Applied in manufacturing acrylic resin coatings, which feature good weather resistance, water resistance, chemical corrosion resistance, and decorative properties, widely used in architectural coatings, automotive coatings, wood coatings, etc. In adhesives, it can improve adhesion strength, water resistance, and aging resistance for bonding materials like paper, wood, leather, and plastics.
Paper Industry: As a paper strength enhancer, it improves the strength and stiffness of paper; as a paper sizing agent, it enhances water resistance and printing adaptability; and as a pigment dispersant, it ensures uniform dispersion of pigments in paper, improving gloss and whiteness.
Main Manufacturers
Kairui Chemical: Its produced kr-1000 acrylic homopolymer is a low-molecular-weight polyacrylic acid with a molecular weight of about 2000, effectively inhibiting the precipitation of low-solubility salts such as calcium carbonate, calcium oxalate, calcium sulfate, and barium sulfate. Contact InformationContact Information 

Acrylic Homopolymer Specialized Manufacturer

​A research team from [Research Institution Name] has been conducting in-depth research on the use of ozone-based water treatment methods to address the growing problem of PFAS (per- and polyfluoroalkyl substances) contamination in water sources. PFAS are a group of man-made chemicals that are highly persistent in the environment and have been linked to various health problems, including cancer, thyroid disease, and developmental issues.​
The researchers are focusing on understanding the effectiveness of ozone in breaking down PFAS compounds and converting them into less harmful substances. Ozone, a powerful oxidizing agent, has shown potential in treating PFAS-contaminated water, but there are still many unknowns regarding the optimal treatment conditions and the by-products formed during the process.​
In their experiments, the research team is using a series of laboratory-scale reactors to test different ozone doses, contact times, and water quality parameters. They are analyzing the fate of different PFAS compounds, including the more common perfluorooctanoic acid (PFOA) and perfluorooctanesulfonic acid (PFOS), as well as emerging PFAS substances.​
"The results of our initial experiments are promising. We have found that ozone can effectively degrade a significant portion of PFAS compounds in water. However, we also need to carefully monitor the formation of by-products, as some of them may also have potential environmental and health impacts," said Dr. [Researcher's Name], the lead author of the study.​
The researchers are also investigating the combination of ozone with other treatment processes, such as advanced oxidation processes (AOPs) using hydrogen peroxide or ultraviolet light. This combined approach may enhance the degradation efficiency of PFAS and reduce the formation of unwanted by-products.​
Understanding the mechanisms of ozone-based PFAS degradation is another important aspect of the research. The team is using advanced analytical techniques, such as mass spectrometry and nuclear magnetic resonance spectroscopy, to study the chemical reactions that occur during the treatment process.​
The findings of this research could have significant implications for the development of practical and effective water treatment solutions for PFAS contamination. If successful, ozone-based treatment methods could be implemented in water treatment plants across the country to address the widespread problem of PFAS in water sources. However, more research is needed to optimize the treatment process and ensure its long-term effectiveness and safety. The research team plans to continue their studies and collaborate with other institutions and industry partners to translate their findings into real-world applications.
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ClickWater scarcity has emerged as one of the most pressing global challenges of the 21st century, affecting billions of people across continents. Climate change, population growth, and unsustainable water usage practices have exacerbated this crisis, leading to depleted aquifers, dried-up rivers, and compromised water quality. In this context, advanced water treatment technologies have become indispensable tools in ensuring a reliable supply of clean water for both domestic and industrial use.
Water Treatment Plant Upgrades to Meet Increasing Demand​
Desalination, the process of removing salt and other impurities from seawater or brackish water, has long been considered a viable solution for water-scarce regions with access to coastal areas. Traditional desalination methods, such as multi-stage flash distillation, are energy-intensive and costly, limiting their widespread adoption. However, recent advancements in reverse osmosis (RO) desalination have significantly improved energy efficiency and reduced costs. Modern RO systems use high-pressure pumps to force water through semipermeable membranes, which trap salt and other contaminants. With the development of low-energy membranes and energy recovery devices, the energy consumption of RO desalination has decreased by more than 50% in the past few decades, making it a feasible option for many arid and semi-arid regions, including the Middle East, Australia, and parts of the United States.
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Wastewater recycling is another critical strategy in addressing water scarcity. Treated wastewater, which was once considered a waste product, can now be reused for a variety of purposes, such as irrigation, industrial processes, and even drinking water. Advanced wastewater treatment processes, such as membrane bioreactors (MBRs), combine biological treatment with membrane filtration to produce high-quality effluent. MBRs are compact, efficient, and capable of removing a wide range of pollutants, including nutrients, pathogens, and emerging contaminants like pharmaceuticals. In countries like Singapore, which faces severe water scarcity, wastewater recycling through the "NEWater" program has become a cornerstone of national water security, providing up to 40% of the country's water needs
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In addition to desalination and wastewater recycling, rainwater harvesting and stormwater management are also gaining importance as complementary approaches to water treatment. Advanced filtration systems can treat rainwater and stormwater, making them suitable for non-potable uses such as toilet flushing, gardening, and street cleaning. This reduces the demand for freshwater from traditional sources, easing the pressure on already strained water supplies.​
However, addressing water scarcity requires more than just technological solutions. It also demands a shift in societal attitudes towards water conservation and sustainable usage. Governments and policymakers play a crucial role in promoting water-saving practices, investing in water infrastructure, and implementing effective water governance frameworks. International cooperation is also essential, as water scarcity is a global issue that transcends national boundaries. By combining advanced water treatment technologies with proactive water management strategies, we can work towards ensuring a sustainable water future for generations to come here to edit.