Products related to Molecules:
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Tiny Science: Atoms and Molecules
Tiny Science - giving MINI-scientists MAXIMUM understanding of the MICROscopic - get to grips with atoms and molecules!A fun and visual series exploring the science of things we cannot see with the naked eye, zooming right in on the itty-bitty creatures, objects and machines that have an enormous impact on us and the world around us.Perfect for children keen to get up-close to the building blocks of our world. Tiny Science: Atoms and Molecules places these key parts of life UNDER THE MICROSCOPE to find answers to ATOMazing questions, such as ... - Aren't atoms un-splittable?- Why does chocolate melt? - How do lasers and atoms relate?Fun cartoon-style illustrations interact with real-life pictures of many amazing microscopic features, making this series ideal for engaging readers aged 8 and up. It's time to explore the infinitesimal!Other Tiny Science books in the series:GermsCellsGenes and DNAMicroscopic CreaturesNanotechnology
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Tiny Science: Atoms and Molecules
Tiny Science - giving MINI-scientists MAXIMUM understanding of the MICROscopic - get to grips with atoms and molecules!A fun and visual series exploring the science of things we cannot see with the naked eye, zooming right in on the itty-bitty creatures, objects and machines that have an enormous impact on us and the world around us.Perfect for children keen to get up-close to the building blocks of our world. Tiny Science: Atoms and Molecules places these key parts of life UNDER THE MICROSCOPE to find answers to ATOMazing questions, such as ... - Aren't atoms un-splittable?- Why does chocolate melt? - How do lasers and atoms relate?Fun cartoon-style illustrations interact with real-life pictures of many amazing microscopic features, making this series ideal for engaging readers aged 8 and up. It's time to explore the infinitesimal!Other Tiny Science books in the series:GermsCellsGenes and DNAMicroscopic CreaturesNanotechnology
Price: 8.99 £ | Shipping*: 3.99 £ -
Atkins' Molecules
Originally published in 2003, this is the second edition of a title that was called 'the most beautiful chemistry book ever written'.In it, we see the molecules responsible for the experiences of our everyday life - including fabrics, drugs, plastics, explosives, detergents, fragrances, tastes, and sex.With engaging prose Peter Atkins gives a non-technical account of an incredible range of aspects of the world around us, showing unexpected connections, and giving an insight into how this amazing world can be understood in terms of the atoms and molecules from which it is built.The second edition includes dozens of extra molecules, graphical presentation, and an even more accessible and enthralling account of the molecules themselves.
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Molecules of Murder : Criminal Molecules and Classic Cases
Molecules of Murder is about infamous murderers and famous victims; about people like Harold Shipman, Alexander Litvinenko, Adelaide Bartlett, and Georgi Markov.Few books on poisons analyse these crimes from the viewpoint of the poison itself, doing so throws a new light on how the murders or attempted murders were carried out and ultimately how the perpetrators were uncovered and brought to justice.Part I includes molecules which occur naturally and were originally used by doctors before becoming notorious as murder weapons.Part II deals with unnatural molecules, mainly man-made, and they too have been dangerously misused in famous crimes.The book ends with the most famous poisoning case in recent years, that of Alexander Litvinenko and his death from polonium chloride.The first half of each chapter starts by looking at the target molecule itself, its discovery, its history, its chemistry, its use in medicine, its toxicology, and its effects on the human body.The second half then investigates a famous murder case and reveals the modus operandi of the poisoner and how some were caught, some are still at large, and some literally got away with murder.Molecules of Murder will explain how forensic chemists have developed cunning ways to detect minute traces of dangerous substances, and explain why some of these poisons, which appear so life-threatening, are now being researched as possible life-savers.Award winning science writer John Emsley has assembled another group of true crime and chemistry stories to rival those of his highly acclaimed Elements of Murder.
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'Salts or molecules?'
Salts are compounds formed from the reaction of an acid and a base, while molecules are made up of atoms bonded together. Salts are ionic compounds, meaning they are made up of ions, while molecules can be either ionic or covalent compounds. Salts have a specific crystalline structure and are often soluble in water, while molecules can have a wide range of physical properties and solubilities. Overall, salts and molecules are distinct types of chemical compounds with different structures and properties.
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Which of the following molecules are dipole molecules and why?
Molecules that have a dipole moment are considered dipole molecules. A dipole moment occurs when there is an uneven distribution of electron density within a molecule, resulting in a partial positive and partial negative charge. For example, molecules like water (H2O) and ammonia (NH3) are dipole molecules because of their polar covalent bonds, which create a separation of charge within the molecule. On the other hand, molecules like carbon dioxide (CO2) and methane (CH4) are nonpolar and do not have a dipole moment because the electronegativity of the atoms cancel each other out, resulting in a symmetrical distribution of charge.
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What is the difference between compound molecules and element molecules?
Compound molecules are made up of two or more different elements chemically bonded together, such as water (H2O) or carbon dioxide (CO2). Element molecules, on the other hand, are made up of two or more atoms of the same element bonded together, such as oxygen (O2) or nitrogen (N2). In compound molecules, the atoms are different, while in element molecules, the atoms are the same.
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Why are water molecules permanent dipoles and carbon dioxide molecules not?
Water molecules are permanent dipoles because they have a bent molecular shape with unequal sharing of electrons between the oxygen and hydrogen atoms. This results in a partial negative charge on the oxygen atom and partial positive charges on the hydrogen atoms, creating a permanent dipole moment. On the other hand, carbon dioxide molecules are not permanent dipoles because they have a linear molecular shape with symmetrical distribution of the two oxygen atoms and the carbon atom. This results in equal sharing of electrons and no permanent dipole moment.
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Encyclopedia of Signaling Molecules
The second edition of this encyclopedia presents about 1000 chapters and includes thousands of biologically important signaling molecules and the content is built on the core concepts of their functions along with early findings written by some of the world’s foremost experts.The molecules are described by recognized leaders in each molecule.The interactions of these single molecules in signal transduction networks will also be explored.This encyclopedia marks a new era in overview of current cellular signaling molecules for the specialist and the interested non-specialist alike. Currently, there are more than 30,000 genes in human genome.However, not all the proteins encoded by these genes work equally in order to maintain homeostasis.Understanding the important signaling molecules as completely as possible will significantly improve our research-based teaching and scientific capabilities.
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Atoms and Molecules Meet
In the Atoms and Molecules Meet leveled reader, fundamental science facts in chemistry are explained through simply written text and colorful, fun illustrations. Children will discover that everything we see, touch, and taste is made of atoms. Atoms are the fundamental building blocks of matter and can link together to make molecules. Electrons on the atoms form the links, or bonds, in molecules, and atoms and molecules can bond to make more molecules.Children will learn that chemical reactions occur when atoms and molecules link together and also when molecules break apart. These chemical reactions must follow rules that state which atoms and molecules are able to link. Several examples of reactions are given, showing some different atoms and molecules they can form. Examples are also given of ways in which some chemical reactions can been seen; for example, as indicated by bubbles, fire, small particles forming, or color change. Chemical reactions are occurring all the time, and examples of reactions that happen in everyday life are shown.A pronunciation guide of scientific terms is included. 24 pages filled with engaging, colorful illustrations. Reading Level 1-3, Interest Level 2-5.
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The Molecules of Life
This textbook provides an integrated physical and biochemical foundation for undergraduate students majoring in biology or health sciences.It is particularly suitable for students planning to enter the pharmaceutical industry.This new generation of molecular biologists and biochemists will harness the tools and insights of physics and chemistry to exploit the emergence of genomics and systems-level information in biology, and will shape the future of medicine.
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Small Molecules in Neurodegeneration
Neurodegenerative diseases, like Alzheimer's, Parkinson's, and Huntington's, cast a long shadow over millions of lives, stealing memories, independence, and futures.The rising tide of these age-related disorders threatens to overwhelm healthcare systems worldwide, prompting an urgent search for effective treatments.While current options offer temporary relief, they fail to halt the relentless march of these devastating conditions.However, a beacon of hope shines at the intersection of cutting-edge neuroscience and the world of small molecules.These tiny chemical warriors, with their inherent advantages of cost-effectiveness, scalability, and diverse functionalities, are emerging as powerful weapons in the fight against neurodegeneration.This book stands as a testament to this increasing revolution.It investigates deep into the intricacies of small molecules, exploring their potential to unravel the mysteries of neurodegenerative diseases and pave the way for innovative therapeutic interventions. Key FeaturesProvides a comprehensive and accessible overview of the emerging field of small molecules in neurodegenerative diseases. Bridges the gap in current literature by addressing the specific impact of small molecules on these devastating conditions. Offers an in-depth exploration of the various mechanisms by which small molecules can combat neurodegeneration. Serves as a valuable resource for a wide audience, from students to professionals in the fieldLays the foundation for a deeper understanding of neurodegenerative diseases and unlocks new avenues for the development of effective therapies.
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Why do heptan-1-ol molecules and water molecules not mix?
Heptan-1-ol molecules and water molecules do not mix well because heptan-1-ol is a nonpolar molecule, while water is a polar molecule. Nonpolar molecules are not attracted to polar molecules, so they do not easily mix. Additionally, heptan-1-ol is hydrophobic, meaning it repels water, further preventing the two substances from mixing. This is due to the difference in the polarity and intermolecular forces between the two substances.
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How are molecules recognized?
Molecules are recognized through specific interactions between their chemical structures and complementary binding sites on other molecules. This recognition process involves the formation of non-covalent bonds such as hydrogen bonds, van der Waals forces, and electrostatic interactions. The shape, size, and charge distribution of molecules play a crucial role in determining their recognition by other molecules. Additionally, specific functional groups and chemical properties can also contribute to the recognition process.
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See description, which molecules?
The description does not specify which molecules are being referred to. It would be helpful to have more context or specific information in order to accurately identify the molecules in question. Without further details, it is difficult to provide a specific answer.
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Search for dipole molecules.
Dipole molecules are molecules that have a separation of positive and negative charges within the molecule. This separation creates a dipole moment, which results in the molecule having a positive end and a negative end. Examples of dipole molecules include water (H2O), hydrogen chloride (HCl), and ammonia (NH3). These molecules are important in various chemical reactions and interactions due to their polar nature.
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