Products related to Compounds:
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Transition Metal Compounds
Describing all aspects of the physics of transition metal compounds, this book provides a comprehensive overview of this unique and diverse class of solids.Beginning with the basic concepts of the physics of strongly correlated electron systems, the structure of transition metal ions, and the behaviours of transition metal ions in crystals, it goes on to cover more advanced topics such as metal-insulator transitions, orbital ordering, and novel phenomena such as multiferroics, systems with oxygen holes, and high-Tc superconductivity.Each chapter concludes with a summary of key facts and concepts, presenting all the most important information in a consistent and concise manner.Set within a modern conceptual framework, and providing a complete treatment of the fundamental factors and mechanisms that determine the properties of transition metal compounds, this is an invaluable resource for graduate students, researchers and industrial practitioners in solid state physics and chemistry, materials science, and inorganic chemistry.
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Coordination Chemistry of Macrocyclic Compounds
This book describes the coordination chemistry of macrocyclic ligands.Common types of ligands are introduced and strategies for the synthesis of the free ligands and their metal complexes are discussed.The unique thermodynamic and kinetic properties of macrocyclic complexes are introduced and applications of the ligands presented.The book is suitable for advanced undergraduate or graduate students and assumes a knowledge of organic and inorganic chemistry at the second year undergraduate level.
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The Chemistry of Organofluorine Compounds
PATAI's Chemistry of Functional Groups publishes comprehensive reviews on all aspects of specific functional groups.Each volume contains outstanding surveys on theoretical and computational aspects, NMR, MS, other spectroscopic methods and analytical chemistry, structural aspects, thermochemistry, photochemistry, synthetic approaches and strategies, synthetic uses and applications in chemical and pharmaceutical industries, biological, biochemical, and environmental aspects.To date, over 150 volumes have been published in the series. The present volume is the first in the series to survey the properties and chemical behavior of organofluorine compounds, as well as their use in small- and large-scale organic synthesis. Organofluorine compounds have important uses as reagents and reactive intermediates across the whole of organic chemistry, and as solvents, refrigerants, dyes, pesticides, and pharmaceuticals.
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Spectrometric Identification of Organic Compounds
First published over 40 years ago, this was the first text on the identification of organic compounds using spectroscopy.This text presents a unified approach to the structure determination of organic compounds based largely on mass spectrometry, infrared (IR) spectroscopy, as well as multinuclear and multidimensional nuclear magnetic resonance (NMR) spectroscopy.The key strength of this text is the extensive set of practice and real-data problems (in Chapters 7 and 8).Even professional chemists use these spectra as reference data.Spectrometric Identification of Organic Compounds is written by and for organic chemists, and emphasizes the synergistic effect resulting from the interplay of spectra.This text is characterized by its problem-solving approach with numerous practice problems and extensive reference charts and tables.
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How can one distinguish ionic compounds from molecular compounds?
Ionic compounds are formed from the attraction between positively and negatively charged ions, while molecular compounds are formed from the sharing of electrons between atoms. One way to distinguish between the two is to look at their chemical formulas. Ionic compounds typically consist of a metal and a nonmetal, while molecular compounds consist of nonmetals only. Additionally, ionic compounds tend to have higher melting and boiling points compared to molecular compounds due to their strong electrostatic attractions. Finally, conducting a simple solubility test can also help distinguish between the two types of compounds, as ionic compounds are often soluble in water while molecular compounds may not be.
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How do you distinguish determinative compounds and possessive compounds?
Determinative compounds are formed by combining two words to create a new concept, where the first word determines the meaning of the second word. For example, "blackboard" is a determinative compound where "black" determines the type of "board." Possessive compounds, on the other hand, indicate possession or relationship between the two words. For example, "John's car" is a possessive compound where "John" possesses the "car." In summary, determinative compounds determine the meaning of the second word, while possessive compounds indicate possession or relationship between the two words.
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Can you help me with chemistry? I need information about atomic compounds, metal compounds, and ionic compounds.
Of course! Atomic compounds are formed when two or more non-metal atoms are chemically bonded together, such as in molecules like water (H2O) and carbon dioxide (CO2). Metal compounds are formed when a metal atom is bonded to one or more non-metal atoms, such as in compounds like sodium chloride (NaCl) and iron oxide (Fe2O3). Ionic compounds are formed when a metal atom transfers one or more electrons to a non-metal atom, resulting in the formation of positively and negatively charged ions that are attracted to each other, such as in compounds like sodium chloride (NaCl) and calcium carbonate (CaCO3). Let me know if you need more specific information or examples!
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Why do molecular compounds have lower boiling points than ionic compounds?
Molecular compounds have lower boiling points than ionic compounds because the intermolecular forces holding the molecules together are generally weaker than the electrostatic forces holding ions together in ionic compounds. In molecular compounds, the intermolecular forces are typically van der Waals forces, dipole-dipole interactions, or hydrogen bonding, which are weaker than the strong ionic bonds in ionic compounds. As a result, less energy is required to overcome these weaker intermolecular forces, leading to lower boiling points for molecular compounds compared to ionic compounds.
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The Chemical Transformations of C1 Compounds
The Chemical Transformations of C1 Compounds A comprehensive exploration of one-carbon molecule transformations The chemistry of one-carbon molecules has recently gained significant prominence as the world transitions away from a petroleum-based economy to a more sustainable one.In The Chemical Transformations of C1 Compounds, an accomplished team of chemists delivers an in-depth overview of recent developments in the field of single-carbon chemistry.The three-volume book covers all major C1 sources, including carbon monoxide, carbon dioxide, methane, methanol, formic acid, formaldehyde, carbenes, C1 halides, and organometallics.The editors have included resources discussing the main reactions and transformations into feedstock chemicals of each of the major C1 compounds reviewed in dedicated chapters.Readers will discover cutting-edge material on organic transformations with MeNO2, DMF, DCM, methyl organometallic reagents, CCl4, CHCl3, and CHBr3, as well as recent achievements in cyanation reactions via cross-coupling.The book also offers: Thorough introductions to chemical transformations of CH4, methods of CH4 activation, chemical transformations of CH3OH and synthesis alkenes from CH3OHComprehensive explorations of the carbonylation of MeOH, CH2O in organic synthesis, organic transformations of HCO2H, and hydrogen generation from HCO2HPractical discussions of the carbonylation of unsaturated bonds with heterogeneous and homogeneous catalysts, as well as the carbonylation of C(sp2)-X bonds and C(sp3)-X bondsIn-depth examinations of carbonylative C-H bond activation and radical carbonylation Perfect for organic and catalytic chemists, The Chemical Transformations of C1 Compounds is also an ideal resource for industrial chemists, chemical engineers, and practitioners at energy supply companies.
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Organometallic Compounds : Synthesis, Reactions, and Applications
Organometallic Compounds An up-to-date overview of the fundamentals, synthesis, and applications of organometallic compounds Organometallic Compounds: Synthesis, Reactions, and Applications delivers an accessible and robust introduction to the fundamentals of organometallic compounds, including their reactions, catalytic mechanisms, and modern applications, including carbon-dioxide fixation, reduction, gas adsorption and purification, drug delivery, renewable energy, and wastewater treatment.The book also covers toxicological and computational studies.The authors address the current challenges confronting researchers seeking to sustainably synthesize and process organometallic compounds and offer complete coverage on the most recent advancements in applications relating to the fields of environmental science, electronics, fossil fuels, and more.Readers will also find: Introduces to fundamentals, nomenclature, properties, and classification of organometallic compounds Discusses methods of synthesis of organometallic compounds Practical discussions of organometallic complexes of the lanthanoids and actinoids, as well as bio-organometallic chemistry Includes characterization techniques of organometallic compounds Perfect for organic, environmental, inorganic, water, and catalytic chemists, Organometallic Compounds: Synthesis, Reactions, and Applications will also benefit chemical engineers and industrial chemists.
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Cytotoxicity : Definition, Identification, and Cytotoxic Compounds
Compensating for cytotoxicity in the multicellular organism by a certain level of cellular proliferation is the primary aim of homeostasis.In addition, the loss of cellular proliferation control (tumorigenesis) is at least as important as cytotoxicity, however, it is a contrasting trauma.With the disruption of the delicate balance between cytotoxicity and proliferation, confrontation with cancer can inevitably occur.This book presents important information pertaining to the molecular control of the mechanisms of cytotoxicity and cellular proliferation as they relate to cancer.It is designed for students and researchers studying cytotoxicity and its control.
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The Systematic Identification of Organic Compounds
The Systematic Identification of Organic Compounds A comprehensive introduction to the identification of unknown organic compounds Identifying unknown compounds is one of the most important parts of the study of chemistry.From basic characteristics such as melting and/or boiling point to more complex data generated through cutting-edge techniques, the range of possible methods for identifying unknown organic compounds is substantial.The utility of a research reference which compiles known techniques and characteristics of possible compounds is clear. The Systematic Identification of Organic Compounds provides such a reference, designed to teach a hands-on approach in the chemistry lab.It takes readers step-by-step through the process of identifying an unknown compound and elucidating its structure from infrared, nuclear magnetic resonance, and mass spectra in addition to solubility characteristics, melting point, boiling point, and classification tests.The result is an essential overview for advanced chemistry students looking to understand this exciting area of laboratory work. Readers of the ninth edition of The Systematic Identification of Organic Compounds will also find: A detailed chapter on safety, personal protection equipment, chemical storage, safety data sheets, and other safety concernsNew NMR, IR, and mass spectra with detailed explanations on interpretationQuestions at the end of each chapter designed to facilitate and reinforce progression, keyed to a companion website for instructorsTables of known compounds including data relevant for identificationCompanion website with structural problems from experimental data for students to practice how to reason and solve The Systematic Identification of Organic Compounds is a useful reference for advanced undergraduates and graduate students studying organic chemistry, organic spectroscopy, and related subjects.
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Name the isomeric compounds.
Isomers are compounds that have the same molecular formula but different structural arrangements. Some examples of isomeric compounds include butane and isobutane, which both have the molecular formula C4H10 but differ in their structural arrangement. Another example is glucose and fructose, which both have the molecular formula C6H12O6 but have different structural arrangements and properties.
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What are sodium compounds?
Sodium compounds are chemical compounds that contain sodium as one of their elements. These compounds can be found in various forms, such as sodium chloride (table salt), sodium hydroxide (lye), and sodium bicarbonate (baking soda). Sodium compounds are widely used in industry, agriculture, and everyday life due to their diverse properties and applications.
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What are atomic compounds?
Atomic compounds are chemical compounds that are composed of individual atoms of different elements bonded together. These compounds are held together by chemical bonds, such as ionic or covalent bonds, and do not contain any molecules. Examples of atomic compounds include sodium chloride (NaCl) and water (H2O). Unlike molecular compounds, which are made up of molecules, atomic compounds are made up of individual atoms.
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What are molecular compounds?
Molecular compounds are chemical compounds formed by the combination of two or more non-metal atoms. These atoms are held together by covalent bonds, which involve the sharing of electrons. Molecular compounds can exist as discrete molecules, such as water (H2O) and carbon dioxide (CO2), and they typically have lower melting and boiling points compared to ionic compounds. Examples of molecular compounds include methane (CH4), ammonia (NH3), and sulfur dioxide (SO2).
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