Learn Organic Chemistry Online: Courses, Videos, and Resources
Organic chemistry is the study of the structure, properties, composition, reactions, and preparation of carbon-containing compounds. Most organic compounds contain carbon and hydrogen, but they may also include any number of other elements (e.g., nitrogen, oxygen, halogens, phosphorus, silicon, sulfur).
Organic chemistry is a highly creative science that allows chemists to create and explore molecules and compounds. Organic chemists spend much of their time developing new compounds and finding better ways of synthesizing existing ones.
Most consumer products we use involve organic chemistry. Take the cosmetics industry as an example. Organic chemistry examines how the skin responds to metabolic and environmental factors, and chemists formulate products accordingly.
Today, organic industrial chemistry is based mainly on petroleum and natural gas. Because these are finite raw materials, a lot of industry focus is on learning how to convert renewable resources (e.g., plants) into industrial organic chemicals.
Find the most important name reactions in organic chemistry, stability datafor the most frequently used protective groups, protection and deprotection methods; browsesynthetic transformationsAbstractsAbstracts of articles in the field of organic synthesis, published in the most highly regarded organic chemistry journalsChemicalsA searchable index of more than 1 million chemicals from suppliers worldwide, basic information on widely-used chemical reagents in organic synthesis such as oxidizing and reducing agents.Chemistry Tools
Chemistry ConferencesInformation about upcoming conferencesInternet ChemistryLinks and NewsOrganische ChemieInformation in German concerning Organic Synthesis and ChemistryOrganic Chemistry - A DefinitionOrganic chemistry focuses on molecules mainly composed of carbon and hydrogen, along with a handful of other elements - such as oxygen, nitrogen, silicon, sulfur, and phosphorus. Organic chemistry deals with synthetic methods, reaction mechanisms and kinetics, and uses analytical methods for reaction control and purification such as chromatography (TLC, GC, HPLC), and structure confirmation such as NMR and IR, but also structure determination such as NMR and X-ray crystallography. New fields of organic chemistry for example include organometallic chemistry,which is the study of carbon-based compounds that contain metals, and bioorganic chemistry, which combines organic chemistry and biochemistry.Methods of organic chemistry are used in medicinal chemistry, natural product chemistry, and materials science. In the industry, organic chemistswork in discovery chemistry (making new molecules) and process optimization (finding better synthetic methods for large scale production).
The Organic Chemistry Graduate Program is designed to prepare students to address emerging research opportunities at the crossroads of modern chemistry, biological chemistry, and materials science as it relates to problems of biomedical importance.
Students participate in dynamic research led by faculty that are world leaders in the field of chemistry and experience the satisfaction of making original contributions to the advancement of chemistry and related disciplines. Students in the program benefit from working collaboratively across disciplines to solve complex health challenges, a hallmark of an education at UT Southwestern Medical Center.
Organic Chemistry Frontiers publishes high-quality research from across organic chemistry. Emphases are placed on studies that make significant contributions to the field of organic chemistry by reporting either new or significantly improved protocols or methodologies.
Reviews provide a critical and in-depth discussion of a particularly relevant or interesting topic in organic chemistry. They aim to provide the reader with an authoritative, balanced and up-to-date overview, not a comprehensive list of all possible references. Authors should aim to identify areas in the field where further developments are needed. Critical reviews do not describe any unpublished results.
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Highlights are short, easy-to-read articles that focus on important new developments in the field of organic chemistry. They highlight and provide insight into the significance of the chosen topic, as well as speculating on the future potential and challenges of that field. Highlights are generally four-five journal pages in length, and new results should not be presented.
Highlights are generally contributed by leading experts in organic chemistry, discussing the state of the art and prospects for significant progress in a specific subject area. Direct submissions from authors are also welcome. All Highlights are subject to a rigorous and full peer review procedure.
Tutorial accounts describe recently established methodologies or protocols that lead to new compounds, chemistry or theories with wide and strong interest in the field of organic chemistry. The authors should provide a concise and practical account of their previously established methodologies, chemistry or theories and instruct the readers on how to reproduce those reactions on larger scales if synthetically related. At least one of the described reactions in a Tutorial account should be at the level of 10 mmol. Reactions on a scale of 10 grams are strongly encouraged.
It is recommended that a comprehensive graphic demonstration is presented at the beginning of a Tutorial account to provide an overview of the reported chemistry. Suggestions or comments concerning optimal conditions for reactions, purification of reagents, etc, are welcome in the main text. Further uses and advances in the chemistry reported since the original publication should be discussed. Experimental details of the key and representative reactions should be included.
A Method is a different article type from the current Tutorial account, being technical notes that focus on the practicality of previously published methodologies. Use of unpublished results should be extremely limited. Methodologies in the field of synthetic organic chemistry, natural products purification, spectroscopy, chemical modification and assembly of organic molecules are encouraged as this article type.
Organic Chemistry Frontiers belongs to the Frontiers journal portfolio, an enterprising collaboration between the Chinese Chemical Society and the Royal Society of Chemistry. The Frontiers project aims to publish a series of high impact, quality chemistry journals that showcase the very best research from China, Asia and the rest of the world to an international audience.
Academic and industrial scientists from organic chemistry, natural products research, material science, catalysis, medicinal chemistry, biochemistry, catalysis, supramolecular chemistry, theoretical chemistry, and other disciplines where involve knowledge in organic chemistry.
The traditional approach to teaching Organic Chemistry, taken by most of the textbooks that are currently available, is to focus primarily on the reactions of laboratory synthesis, with much less discussion - in the central chapters, at least - of biological molecules and reactions. This is despite the fact that, in many classrooms, a majority of students are majoring in Biology or Health Sciences rather than in Chemistry, and are presumably taking the course in order to learn about the chemistry that takes place in living things.
In an effort to address this disconnect, I have developed a textbook for a two-semester, sophomore-level course in Organic Chemistry in which biological chemistry takes center stage. For the most part, the text covers the core concepts of organic structure, structure determination, and reactivity in the standard order. What is different is the context: biological chemistry is fully integrated into the explanation of central principles, and as much as possible the in-chapter and end-of-chapter problems are taken from the biochemical literature. Many laboratory synthesis reactions are also covered, generally in parallel with their biochemical counterparts - but it is intentionally the biological chemistry that comes first.
Energy released from molecules under strain can promote difficult chemical reactions. A practical method has been developed that uses an overlooked, highly strained compound to rapidly construct complex organic products.
Cyclic iminium salts are used as versatile intermediates in the synthesis of diverse N-(hetero)aryl piperidines. This method facilitates the C2 and/or C3 functionalization of the piperidine backbone with motifs relevant to medicinal chemistry, enabling the exploration of previously inaccessible chemical space for the discovery of medicines.
Amide-bearing organic compounds are important building blocks in organic synthesis, however, the ambident reactivities of the nitrogen and oxygen atoms in the amide moiety requires catalysts and reagents that are able to control the reaction selectivity. Here, hypervalent iodine reagents are shown to mediate the intramolecular cycloisomerization of O-alkenylbenzamides to selectively generate isoquinolinone and iminoisocoumarin derivatives.
The development of selective multifunctionalization of alkynes is essential for organic synthesis with alkyne units as building blocks. Here the authors report a gold-catalyzed, four-component reaction that achieves the oxo-arylfluorination or oxo-arylalkenylation of internal aromatic or aliphatic alkynes