• Embarking on the synthesis of methylone https://emergencydentistwichitakansas.com/unveiling-the-chemistry-of-methylone-synthesis-properties-and-pharmacological-effects, a notable member of the cathinone family, is a journey that intertwines scientific innovation with ethical consciousness. Methylone, renowned for its psychoactive effects akin to MDMA, beckons chemists into a realm where chemistry meets responsibility.

    The synthesis initiates with the procurement of precursor compounds, a task entwined with legal considerations and chemical ingenuity. Chemists navigate regulatory landscapes, employing inventive strategies to access precursor materials while upholding legal compliance and safety standards.

    Central to the synthesis process is the meticulous orchestration of chemical reactions. From precursor molecules, a carefully choreographed sequence of transformations unfolds, guided by the skilled hands of chemists. Control over reaction conditions is paramount, ensuring not only the efficiency of synthesis but also the safety of laboratory personnel and the environment.

    Safety protocols stand as sentinels throughout the synthesis endeavor, emphasizing the importance of responsible practices. Chemists don protective gear, implement ventilation systems, and adhere to stringent procedures to mitigate risks and prevent accidents. These measures reflect a commitment to the well-being of all involved in the synthesis process.

    Beyond the laboratory bench, ethical considerations cast a profound shadow. Chemists engage in introspection, contemplating the societal implications of their work. Discussions on harm reduction, public health, and responsible use permeate scientific discourse, guiding researchers in their quest for knowledge.

    In the synthesis of methylone, chemists embody the fusion of science and responsibility. Their endeavors illuminate the interconnectedness of chemical innovation, regulatory compliance, and ethical consciousness. By embracing these principles, chemists contribute not only to the advancement of cathinone chemistry but also to the promotion of safety, integrity, and societal well-being.
    Embarking on the synthesis of methylone https://emergencydentistwichitakansas.com/unveiling-the-chemistry-of-methylone-synthesis-properties-and-pharmacological-effects, a notable member of the cathinone family, is a journey that intertwines scientific innovation with ethical consciousness. Methylone, renowned for its psychoactive effects akin to MDMA, beckons chemists into a realm where chemistry meets responsibility. The synthesis initiates with the procurement of precursor compounds, a task entwined with legal considerations and chemical ingenuity. Chemists navigate regulatory landscapes, employing inventive strategies to access precursor materials while upholding legal compliance and safety standards. Central to the synthesis process is the meticulous orchestration of chemical reactions. From precursor molecules, a carefully choreographed sequence of transformations unfolds, guided by the skilled hands of chemists. Control over reaction conditions is paramount, ensuring not only the efficiency of synthesis but also the safety of laboratory personnel and the environment. Safety protocols stand as sentinels throughout the synthesis endeavor, emphasizing the importance of responsible practices. Chemists don protective gear, implement ventilation systems, and adhere to stringent procedures to mitigate risks and prevent accidents. These measures reflect a commitment to the well-being of all involved in the synthesis process. Beyond the laboratory bench, ethical considerations cast a profound shadow. Chemists engage in introspection, contemplating the societal implications of their work. Discussions on harm reduction, public health, and responsible use permeate scientific discourse, guiding researchers in their quest for knowledge. In the synthesis of methylone, chemists embody the fusion of science and responsibility. Their endeavors illuminate the interconnectedness of chemical innovation, regulatory compliance, and ethical consciousness. By embracing these principles, chemists contribute not only to the advancement of cathinone chemistry but also to the promotion of safety, integrity, and societal well-being.
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  • In the secretive realm of chemical synthesis, the production of PMK Glycidate https://diabetes-watch-blog.com/exploring-the-chemistry-of-pmk-glycidate-synthesis-properties-and-applications emerges as a captivating tale of scientific ingenuity and ethical conundrums. As a crucial building block in MDMA synthesis, its creation navigates a maze of reactions, blending intricate chemistry with societal implications.

    The saga unfolds with safrole, extracted from natural sources, undergoing a meticulous isomerization process to yield isosafrole. This initial transformation sets the stage for subsequent conversions, laying the groundwork for the synthesis's complexity.

    Transitioning to the oxidation phase, isosafrole undergoes a pivotal metamorphosis into PMK, facilitated by carefully selected oxidizing agents. This step demands precision to optimize yield while minimizing the formation of undesirable by-products, showcasing the delicate balance of chemical reactivity.

    The pinnacle of the synthesis is reached during glycidation, where PMK transforms into PMK Glycidate. This critical transformation requires a symphony of reactants and conditions, orchestrated with finesse by skilled chemists. The judicious selection of epoxidizing agents and solvents directs the molecular dance, culminating in the creation of PMK Glycidate.

    However, beyond the laboratory bench lies a tapestry interwoven with ethical dilemmas. The clandestine synthesis of PMK Glycidate fuels the underground market for MDMA, perpetuating substance abuse and societal harm. As regulatory scrutiny intensifies, clandestine chemists face mounting obstacles, highlighting the need for responsible scientific practices.

    In the grand narrative of chemistry, the synthesis of PMK Glycidate serves as a testament to human innovation and the pursuit of knowledge. Yet, it also serves as a sobering reminder of the ethical considerations inherent in scientific endeavors. As we unravel the chemistry behind PMK Glycidate synthesis, we confront not only the intricacies of molecules but also the broader implications for society.
    In the secretive realm of chemical synthesis, the production of PMK Glycidate https://diabetes-watch-blog.com/exploring-the-chemistry-of-pmk-glycidate-synthesis-properties-and-applications emerges as a captivating tale of scientific ingenuity and ethical conundrums. As a crucial building block in MDMA synthesis, its creation navigates a maze of reactions, blending intricate chemistry with societal implications. The saga unfolds with safrole, extracted from natural sources, undergoing a meticulous isomerization process to yield isosafrole. This initial transformation sets the stage for subsequent conversions, laying the groundwork for the synthesis's complexity. Transitioning to the oxidation phase, isosafrole undergoes a pivotal metamorphosis into PMK, facilitated by carefully selected oxidizing agents. This step demands precision to optimize yield while minimizing the formation of undesirable by-products, showcasing the delicate balance of chemical reactivity. The pinnacle of the synthesis is reached during glycidation, where PMK transforms into PMK Glycidate. This critical transformation requires a symphony of reactants and conditions, orchestrated with finesse by skilled chemists. The judicious selection of epoxidizing agents and solvents directs the molecular dance, culminating in the creation of PMK Glycidate. However, beyond the laboratory bench lies a tapestry interwoven with ethical dilemmas. The clandestine synthesis of PMK Glycidate fuels the underground market for MDMA, perpetuating substance abuse and societal harm. As regulatory scrutiny intensifies, clandestine chemists face mounting obstacles, highlighting the need for responsible scientific practices. In the grand narrative of chemistry, the synthesis of PMK Glycidate serves as a testament to human innovation and the pursuit of knowledge. Yet, it also serves as a sobering reminder of the ethical considerations inherent in scientific endeavors. As we unravel the chemistry behind PMK Glycidate synthesis, we confront not only the intricacies of molecules but also the broader implications for society.
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  • Mephedrone https://mmc-chemicals.com/mephedrone-use-during-pregnancy-risks-and-considerations, a synthetic stimulant that has surged in popularity within illicit drug circles, offers a fascinating lens through which to examine the intricate chemistry and broader societal implications of drug production. Investigating the synthesis of mephedrone unveils a complex narrative interwoven with scientific innovation, legal complexities, and public health concerns.

    The synthesis of mephedrone initiates with precursor chemicals like 4-methylpropiophenone and ammonium formate, which undergo a series of meticulously controlled chemical reactions. Guided by specific catalysts, these precursors undergo transformations to yield the intermediary compound 4-methylmethcathinone (4-MMC). Further refinement steps culminate in the synthesis of mephedrone. However, this process demands precision, expertise, and strict adherence to safety protocols to mitigate the inherent risks associated with chemical synthesis.

    Navigating the legal landscape surrounding mephedrone synthesis presents significant challenges. Regulations governing its production and distribution vary widely across jurisdictions, leading to inconsistencies in enforcement and oversight. Despite regulatory efforts, clandestine laboratories persist, exploiting legal loopholes and technological advancements to evade detection.

    Beyond its chemical synthesis and legal ramifications, mephedrone's presence in society raises broader concerns about public health and social well-being. Its availability through illicit channels exposes users to unpredictable risks, with consequences extending to individuals, families, and communities.

    Addressing the multifaceted issues surrounding mephedrone synthesis requires a collaborative effort from stakeholders across various sectors. Scientists, policymakers, law enforcement agencies, and community organizations must work together to develop evidence-based strategies for harm reduction, education, and intervention. By fostering awareness, implementing effective regulations, and promoting public health initiatives, stakeholders can mitigate the risks associated with mephedrone use and promote healthier communities.

    Moreover, understanding the chemistry and societal impact of mephedrone synthesis provides valuable insights into broader discussions on drug regulation and substance abuse prevention. By addressing the root causes of drug production and consumption, society can strive towards a more informed and proactive approach to tackling substance abuse and promoting overall well-being.
    Mephedrone https://mmc-chemicals.com/mephedrone-use-during-pregnancy-risks-and-considerations, a synthetic stimulant that has surged in popularity within illicit drug circles, offers a fascinating lens through which to examine the intricate chemistry and broader societal implications of drug production. Investigating the synthesis of mephedrone unveils a complex narrative interwoven with scientific innovation, legal complexities, and public health concerns. The synthesis of mephedrone initiates with precursor chemicals like 4-methylpropiophenone and ammonium formate, which undergo a series of meticulously controlled chemical reactions. Guided by specific catalysts, these precursors undergo transformations to yield the intermediary compound 4-methylmethcathinone (4-MMC). Further refinement steps culminate in the synthesis of mephedrone. However, this process demands precision, expertise, and strict adherence to safety protocols to mitigate the inherent risks associated with chemical synthesis. Navigating the legal landscape surrounding mephedrone synthesis presents significant challenges. Regulations governing its production and distribution vary widely across jurisdictions, leading to inconsistencies in enforcement and oversight. Despite regulatory efforts, clandestine laboratories persist, exploiting legal loopholes and technological advancements to evade detection. Beyond its chemical synthesis and legal ramifications, mephedrone's presence in society raises broader concerns about public health and social well-being. Its availability through illicit channels exposes users to unpredictable risks, with consequences extending to individuals, families, and communities. Addressing the multifaceted issues surrounding mephedrone synthesis requires a collaborative effort from stakeholders across various sectors. Scientists, policymakers, law enforcement agencies, and community organizations must work together to develop evidence-based strategies for harm reduction, education, and intervention. By fostering awareness, implementing effective regulations, and promoting public health initiatives, stakeholders can mitigate the risks associated with mephedrone use and promote healthier communities. Moreover, understanding the chemistry and societal impact of mephedrone synthesis provides valuable insights into broader discussions on drug regulation and substance abuse prevention. By addressing the root causes of drug production and consumption, society can strive towards a more informed and proactive approach to tackling substance abuse and promoting overall well-being.
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  • In the intricate tapestry of chemical compounds, BMK Methyl Glycidate https://euromed-cdc.org/2024/02/09/bmk-methyl-glycidate-a-versatile-intermediate-in-organic-synthesis/ emerges as a hidden gem, quietly revolutionizing industries with its remarkable properties and versatile applications. Born from the fusion of glycidic acid and methylamine, this compound embodies the essence of creativity and scientific ingenuity.

    At its core, BMK Methyl Glycidate serves as a cornerstone in pharmaceutical synthesis, offering a vital pathway to numerous life-saving medications. As a key intermediate in the production of pharmaceuticals, it facilitates the creation of complex molecules with precision and efficiency, paving the way for advancements in healthcare.

    Beyond the realm of medicine, BMK Methyl Glycidate has captivated the fragrance industry with its subtle yet enchanting aroma. Its inclusion in perfumes and colognes adds a touch of sophistication and allure, elevating scent compositions to new heights and captivating the senses of consumers worldwide.

    Furthermore, the compound's versatility extends into materials science, where it plays a pivotal role in the development of advanced polymers and coatings. By serving as a building block for innovative materials, BMK Methyl Glycidate enhances the performance and durability of various products, from industrial coatings to consumer goods.

    However, the utilization of BMK Methyl Glycidate demands careful attention to safety protocols and regulatory standards. As with any potent chemical compound, responsible handling and storage are paramount to safeguarding both human health and the environment.

    In essence, BMK Methyl Glycidate symbolizes the spirit of progress in modern chemistry, where creativity and innovation converge to drive meaningful change. Its diverse applications across industries underscore its significance as a catalyst for innovation, shaping the landscape of chemistry and unlocking new frontiers of possibility.
    In the intricate tapestry of chemical compounds, BMK Methyl Glycidate https://euromed-cdc.org/2024/02/09/bmk-methyl-glycidate-a-versatile-intermediate-in-organic-synthesis/ emerges as a hidden gem, quietly revolutionizing industries with its remarkable properties and versatile applications. Born from the fusion of glycidic acid and methylamine, this compound embodies the essence of creativity and scientific ingenuity. At its core, BMK Methyl Glycidate serves as a cornerstone in pharmaceutical synthesis, offering a vital pathway to numerous life-saving medications. As a key intermediate in the production of pharmaceuticals, it facilitates the creation of complex molecules with precision and efficiency, paving the way for advancements in healthcare. Beyond the realm of medicine, BMK Methyl Glycidate has captivated the fragrance industry with its subtle yet enchanting aroma. Its inclusion in perfumes and colognes adds a touch of sophistication and allure, elevating scent compositions to new heights and captivating the senses of consumers worldwide. Furthermore, the compound's versatility extends into materials science, where it plays a pivotal role in the development of advanced polymers and coatings. By serving as a building block for innovative materials, BMK Methyl Glycidate enhances the performance and durability of various products, from industrial coatings to consumer goods. However, the utilization of BMK Methyl Glycidate demands careful attention to safety protocols and regulatory standards. As with any potent chemical compound, responsible handling and storage are paramount to safeguarding both human health and the environment. In essence, BMK Methyl Glycidate symbolizes the spirit of progress in modern chemistry, where creativity and innovation converge to drive meaningful change. Its diverse applications across industries underscore its significance as a catalyst for innovation, shaping the landscape of chemistry and unlocking new frontiers of possibility.
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  • Hypertension, or high blood pressure, affects millions of individuals worldwide and is a significant risk factor for cardiovascular disease. The management of hypertension often involves the use of medications, each with its unique chemical composition targeting various physiological pathways. In this article, we explore the intricate chemistry behind common blood pressure medications.
    https://respecthealthcareheroes.org/cas-28578-16-7-decoding-the-chemical-enigma
    Hypertension, or high blood pressure, affects millions of individuals worldwide and is a significant risk factor for cardiovascular disease. The management of hypertension often involves the use of medications, each with its unique chemical composition targeting various physiological pathways. In this article, we explore the intricate chemistry behind common blood pressure medications. https://respecthealthcareheroes.org/cas-28578-16-7-decoding-the-chemical-enigma
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  • **1. Fundamentals of Chemical Compounds:
    At its core, a chemical compound is a substance composed of two or more different elements held together by chemical bonds. These elements combine in specific ratios, giving rise to a vast array of compounds with distinct properties. Water (H2O) and sodium chloride (NaCl) are classic examples, showcasing the fundamental nature of chemical combinations.
    https://neurologyinterpreter.com/the-comprehensive-exploration-of-cas-28578-16-7-chemistry-applications-and-safety

    **2. Versatility in Nature:
    Chemical compounds are omnipresent in the natural world. Organic compounds, containing carbon, hydrogen, and other elements, form the basis of life itself. DNA, proteins, and carbohydrates are intricate examples of compounds that orchestrate the marvel of biological existence. Meanwhile, inorganic compounds contribute to the composition of minerals, rocks, and essential components of Earth's crust.

    **3. Applications in Industry:
    The industrial realm heavily relies on chemical compounds. From polymers and plastics to pharmaceuticals and agrochemicals, these compounds are instrumental in the production of countless goods. Innovations in material science continually introduce new compounds with enhanced properties, leading to breakthroughs in manufacturing processes and product development.

    **4. Pharmaceutical Marvels:
    The world of medicine is deeply intertwined with chemical compounds. Pharmaceuticals, designed to diagnose, treat, and prevent diseases, are often complex formulations of active ingredients and carefully selected excipients. The chemical ingenuity behind these medications has revolutionized healthcare, contributing to advancements in disease management and patient care.

    **5. Environmental Impact:
    Unfortunately, not all chemical compounds contribute positively. Some pollutants and toxins are also chemical compounds, leading to environmental challenges. Understanding the composition and behavior of these substances is crucial for mitigating their impact and developing sustainable solutions to address environmental concerns.

    In conclusion, the study of chemical compounds opens a gateway to understanding the intricacies of our universe. From the marvels of life to the innovations that shape industries, the diverse and dynamic nature of chemical compounds continues to captivate scientists, engineers, and curious minds alike, offering a fascinating journey into the heart of matter and its profound implications for our world.
    **1. Fundamentals of Chemical Compounds: At its core, a chemical compound is a substance composed of two or more different elements held together by chemical bonds. These elements combine in specific ratios, giving rise to a vast array of compounds with distinct properties. Water (H2O) and sodium chloride (NaCl) are classic examples, showcasing the fundamental nature of chemical combinations. https://neurologyinterpreter.com/the-comprehensive-exploration-of-cas-28578-16-7-chemistry-applications-and-safety **2. Versatility in Nature: Chemical compounds are omnipresent in the natural world. Organic compounds, containing carbon, hydrogen, and other elements, form the basis of life itself. DNA, proteins, and carbohydrates are intricate examples of compounds that orchestrate the marvel of biological existence. Meanwhile, inorganic compounds contribute to the composition of minerals, rocks, and essential components of Earth's crust. **3. Applications in Industry: The industrial realm heavily relies on chemical compounds. From polymers and plastics to pharmaceuticals and agrochemicals, these compounds are instrumental in the production of countless goods. Innovations in material science continually introduce new compounds with enhanced properties, leading to breakthroughs in manufacturing processes and product development. **4. Pharmaceutical Marvels: The world of medicine is deeply intertwined with chemical compounds. Pharmaceuticals, designed to diagnose, treat, and prevent diseases, are often complex formulations of active ingredients and carefully selected excipients. The chemical ingenuity behind these medications has revolutionized healthcare, contributing to advancements in disease management and patient care. **5. Environmental Impact: Unfortunately, not all chemical compounds contribute positively. Some pollutants and toxins are also chemical compounds, leading to environmental challenges. Understanding the composition and behavior of these substances is crucial for mitigating their impact and developing sustainable solutions to address environmental concerns. In conclusion, the study of chemical compounds opens a gateway to understanding the intricacies of our universe. From the marvels of life to the innovations that shape industries, the diverse and dynamic nature of chemical compounds continues to captivate scientists, engineers, and curious minds alike, offering a fascinating journey into the heart of matter and its profound implications for our world.
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  • IP Chemistry

    IP Chemistry Tuition - Year 3 & Year 4 - ACSI, MGS & SJI

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    IP Chemistry IP Chemistry Tuition - Year 3 & Year 4 - ACSI, MGS & SJI Integrated Programme Chemistry Tuition for ACSI, MGS & SJI Look no further! Our top-rated IP Chemistry tuition program is specifically designed to help ACSI, MGS or SJI students excel in this challenging subject. With ... https://ipchemistrytuition.com/
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  • IP Chemistry Tuition ACSI

    IP Chemistry Tuition - Year 3 & Year 4 - ACSI, MGS & SJI

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    IP Chemistry Tuition ACSI IP Chemistry Tuition - Year 3 & Year 4 - ACSI, MGS & SJI Integrated Programme Chemistry Tuition for ACSI, MGS & SJI Look no further! Our top-rated IP Chemistry tuition program is specifically designed to help ACSI, MGS or SJI students excel in this challenging subject. With ... https://ipchemistrytuition.com/
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  • So once you take our services you won’t have to worry about your assignments anymore as our professionals can deal with any assignments. Our chemistry assignment helper will help you deal with certain important chemistry lessons like organic chemistry, biochemistry, physical chemistry, and inorganic. They will help you clear the base by giving you various notes about atoms, matter, molecules, chemical elements, or chemical compounds.
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  • Basic Organic Chemistry factory Production Method Product Name:Methylpyrrolidone CAS. No. 872-50-4 Molecular formula:C5H9NO Application 1. Used in lithium ion battery industry; 2. Used in semiconductor, LCD cable industry; 3. Used in insulating materials, circuit board industry; 4. Used in polymer, medicine, pesticide and petrochemical industry. Product Parameter (Specification) Product NameMethylpyrrolidone CAS No.872-50-4 Molecular FormulaC5H9NO Nickname (s)N-methylpyrrolidin-2-one; 1-methylpyrrolidin-2-one; N-methyl-pyrrolidin-2-one; 1-Methyl-2-pyrrolidinone; 1-methyl-2-oxo-pyrrolidine; 2-Pyrrolidinone, 1-methyl-. Molecular weight999.13110 Precise quality99.06840 PSA20.31000 LOGP0.17650 Prodection Details Appearance and property: Colorless or yellowish liquid with an amine odor Density: 1.028 g/mL at 25 ° C (lit.) Melting point: - 24 ° C (lit.) Boiling point: 202 ° C (lit.) Flashing Point: 187 ° F Refractive index: n20/D 1.479 Water solubility: >=10 g/100 mL at 20 C Stability: Stable but decomposes upon exposure to light. Combustible. Incompatible with strong oxidizing agents, strong acids, reducing agents, bases. Storage conditions: packing intact, handle gently, storehouse ventilation, away from open fire, high temperature, and oxidant separate storage. Vapor pressure: 0.29 mm Hg (20 ° C) Steam density: 3.4 (vs air) Our Advantages 1. Top quality materials with competitive price; 2. Large capacity of stable materials supplt; 3. Safty and fast shipment by express/air/sea; 4. Sample order acceptable; 5. Professional and great packing as customized; 6. Convenient payment terms by T/T, Paypal, Western Union, Alibaba and others; 7. Reply inquiries in time. Our Factory And Company Our factory advanced production technology and equipment. FactoryCompany Major Exporting Countries Deliver, Shipping And Serving We will provide you with quality products and professional services. You are always welcome to consult us. We will provide you with a comprehensive offer, including quotation, payment, mail, etc. We look forward to your inquiry. Cooperation Cases Operation Handling And Storage Editing 1. Storage method: store in dry and inert gas, keep the container sealed, and store in a cool and dry place. 2. Matters needing attention in operation Avoid exposure: obtain specific instructions before use. Avoid contact with skin and eyes. Avoid inhalation of steam and smoke. Keep away from fire. - no fireworks. Take measures to prevent the accumulation of static electricity. 3. Storage precautions: store in a cool place. Keep container airtight and store in dry and ventilated place. Containers that have been opened must be carefully re-sealed and held upright to prevent leakage. Aeration is sensitive to humidity.Basic Organic Chemistry factory website:http://www.eastchemy.com/basic-organic-chemistry/
    Basic Organic Chemistry factory Production Method Product Name:Methylpyrrolidone CAS. No. 872-50-4 Molecular formula:C5H9NO Application 1. Used in lithium ion battery industry; 2. Used in semiconductor, LCD cable industry; 3. Used in insulating materials, circuit board industry; 4. Used in polymer, medicine, pesticide and petrochemical industry. Product Parameter (Specification) Product NameMethylpyrrolidone CAS No.872-50-4 Molecular FormulaC5H9NO Nickname (s)N-methylpyrrolidin-2-one; 1-methylpyrrolidin-2-one; N-methyl-pyrrolidin-2-one; 1-Methyl-2-pyrrolidinone; 1-methyl-2-oxo-pyrrolidine; 2-Pyrrolidinone, 1-methyl-. Molecular weight999.13110 Precise quality99.06840 PSA20.31000 LOGP0.17650 Prodection Details Appearance and property: Colorless or yellowish liquid with an amine odor Density: 1.028 g/mL at 25 ° C (lit.) Melting point: - 24 ° C (lit.) Boiling point: 202 ° C (lit.) Flashing Point: 187 ° F Refractive index: n20/D 1.479 Water solubility: >=10 g/100 mL at 20 C Stability: Stable but decomposes upon exposure to light. Combustible. Incompatible with strong oxidizing agents, strong acids, reducing agents, bases. Storage conditions: packing intact, handle gently, storehouse ventilation, away from open fire, high temperature, and oxidant separate storage. Vapor pressure: 0.29 mm Hg (20 ° C) Steam density: 3.4 (vs air) Our Advantages 1. Top quality materials with competitive price; 2. Large capacity of stable materials supplt; 3. Safty and fast shipment by express/air/sea; 4. Sample order acceptable; 5. Professional and great packing as customized; 6. Convenient payment terms by T/T, Paypal, Western Union, Alibaba and others; 7. Reply inquiries in time. Our Factory And Company Our factory advanced production technology and equipment. FactoryCompany Major Exporting Countries Deliver, Shipping And Serving We will provide you with quality products and professional services. You are always welcome to consult us. We will provide you with a comprehensive offer, including quotation, payment, mail, etc. We look forward to your inquiry. Cooperation Cases Operation Handling And Storage Editing 1. Storage method: store in dry and inert gas, keep the container sealed, and store in a cool and dry place. 2. Matters needing attention in operation Avoid exposure: obtain specific instructions before use. Avoid contact with skin and eyes. Avoid inhalation of steam and smoke. Keep away from fire. - no fireworks. Take measures to prevent the accumulation of static electricity. 3. Storage precautions: store in a cool place. Keep container airtight and store in dry and ventilated place. Containers that have been opened must be carefully re-sealed and held upright to prevent leakage. Aeration is sensitive to humidity.Basic Organic Chemistry factory website:http://www.eastchemy.com/basic-organic-chemistry/
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