A three-quarter general chemistry sequence primarily for science, pre-professional, and engineering students. The CHEM& 161/162/163 series introduces the basic concepts of chemistry: atomic structure and bonding, periodicity, physical measurement, quantitative relationships, chemical reactivity, oxidation and reduction, stoichiometry, ideal gas laws, aqueous solutions, colligative properties, intermolecular forces, structure of matter, equilibrium, acid/base topics, kinetics, thermodynamics, electrochemistry, nuclear chemistry, qualitative analysis, d-block metals and coordination chemistry, and an introduction to organic chemistry.Login: guest_oclPassword: ocl

How to be a successful organic chemist is meant as an introductory text for undergraduates taking organic chemistry teaching labs. The text is a clear and practical introduction to safety, chemical handling, organic chemistry techniques, and lab reports.

General Chemistry is a two-semester course (General Chemistry I, SCC 201 and General Chemistry II, SCC 202) required for majors in Biology and Environmental Sciences.
This lab experiment, aligned to LaGuardia Community College‰Ûªs Inquiry and Problem Solving Core Competency and Written Communication Ability was designed for General Chemistry I (SCC 201 Honors) course. Honors courses in LaGuardia emphasize critical thinking, analytical writing, and introduce students to research. This lab experiment provides an opportunity for students to engage in hands-on laboratory work, to develop laboratory skills, and to conduct research in the classroom by using two water soluble porphyrins to detect transition metal ions in a solution and on a paper support. Overall, this experiment was designed to meet the demand for undergraduate research experiences and to engage all the students in addressing a research question or problem that is of interest to the scientific community.
In order to demonstrate their learning, students write a formal lab report which includes an understanding of experiment procedures (methods and techniques), safety hazards, instrumentation, understanding of concepts and theories gained by performing the experiment, collecting data through observation and/or experimentation, interpretation of the data (Ultraviolet-visible spectra), analysis of the data in tables and graphs, and drawing conclusions and perspective from the experiment. The knowledge students gain during this lab experiment will be useful to connect with future chemistry courses and can also be utilized to do research. The lab write-up is deposited for the assessment of the Written Communication Ability to which SCC 201 is aligned.
This experiment also raises awareness about a global concern. Students detect transition metal ions in aqueous solutions by use of porphyrins. Due to rapid growth in technology and industrialization, transition metals are used in large amounts in a variety of electronic products. The improper preservation of the industrial wastes leads to accumulation of these metals into water resources, which can create danger to human health and the environment. Therefore, there is a need to carefully monitor and frequently detect transition metal ions content in the environment.
This lab experiment was implemented in an Honors section of General Chemistry SCC 201 and was worth about 3.5% of the final grade. The students are likely to spend 3 hours completing the experiment in the lab and another 3-4 hours completing the lab write-up.
The Program Goals that this assignment targets:
1. To provide training to the students in various lab techniques and how to utilize these techniques to conduct research.
The Student Learning Objective (s) that this assignment targets:
1. Students will have an enhanced conceptual understanding of the theory to practice relationship and will achieve higher level reasoning skills.
2. Students will be able to develop their practical competence in laboratory work.
3. Students will be able to collect data through observation and/or experimentation, preparation of solutions of known concentration, characterize the compounds by UV-vis spectra, and draw conclusions and perspective of the experiment.
4. Communicate their results through the formal lab report format of: Introduction, Chemicals, Procedure, Data, Discussion and References.
LaGuardia‰Ûªs Core Competencies and Communication Abilities
The Course Objective (s) that this assignment targets:
1. Based on the principles of environmental chemistry, students will be able to detect the transition metal ions using a porphyrin as a sensor and explore the complex connections between chemistry and real world issues.
2. Observe, collect, analyze and interpret experimental data and graph the UV visible spectra using Microsoft Excel.

Inorganic chemistry is concerned with the properties and reactivity of all chemical elements. Advanced interests focus on understanding the role of metals in biology and the environment, the design and properties of materials for energy and information technology, fundamental studies on the reactivity of main group and transition elements, and nanotechnology. Synthetic efforts are directed at hydrogen storage materials and thermoelectrics, catalysts for solar hydrogen generation, fullerenes and metal porphyrins, metal clusters and compounds with element-element bonds, as well as nanowires and nanoparticles.

From consumer products to space-age technologies, chemistry affects our daily lives. In this course, students will learn the structure of matter and how it behaves under various conditions in order to better understand the chemical world. Designed for students with little or no chemistry background. Laboratory activities extend lecture concepts and introduce students to the experimental process. This course is designed for a face-to-face mode of instruction using online resources. Course content is divided into units. Each unit may include text readings, laboratory preparation, study questions, thought-provoking discussions, written assignments, learning activities, and group projects.Login: guest_oclPassword: ocl

This open text is disseminated via the Open Education Resource (OER) LibreTexts Project (https://LibreTexts.org) and like the hundreds of other open texts available within this powerful platform, it is licensed to be freely used, adapted, and distributed.

Contributors
Paul Flowers (University of North Carolina - Pembroke), Klaus Theopold (University of Delaware) and Richard Langley (Stephen F. Austin State University) with contributing authors. Textbook content produced by OpenStax College is licensed under a Creative Commons Attribution License 4.0 license. Download for free at http://cnx.org/contents/85abf193-2bd...a7ac8df6@9.110)

CHE 101
A brief presentation of introductory chemical concepts including atomic structure, the chemical equation, the behavior of gases, the chemistry of solution, and acid-base chemistry.

David W. Ball of Cleveland State University brings his new survey of general chemistry text, Introductory Chemistry, to the market with a fresh theme that will be sure to hold student interest: "Chemistry is Everywhere." Introductory Chemistry is intended for a one-semester introductory or preparatory chemistry course. Throughout the chapters, David presents two features that reinforce the theme of the textbook, that chemistry is everywhere.The first is the boxed feature titled, appropriately, “Chemistry is Everywhere”. This feature takes a topic of the chapter and demonstrates how this topic shows up in everyday life. In the introductory chapter, “Chemistry is Everywhere” focuses on the personal hygiene products that students may use every morning: toothpaste, soap, shampoo among others. These products are chemicals, aren’t they? This book explores some of the chemical reactions like the ones that give students clean and healthy teeth, and shiny hair. This feature makes it clear to students that chemistry is, indeed, everywhere, and it will promote student retention in what is sometimes considered an intimidating course.The second boxed feature focuses on chemistry that students likely indulge in every day: eating and drinking. In the “Food and Drink App”, David discusses how the chemistry of the chapter applies to things that students eat and drink every day. Carbonated beverages depend on the behavior of gases, foods contain acids and bases, and everyone actually eats certain rocks. (Yikes!) Cooking, eating, drinking, metabolism – all chemical processes students are involved with all the time. These features allow students to see the things we interact with every day in a new light – as chemistry.Just like many of the one-semester chemistry books you may be used to, each section in David Ball's <="" em=""> starts with one or more Learning Objectives, which list the main points of the section. Each section ends with Key Takeaways, which are reviews of the main points of the section. Each chapter is full of examples to illustrate the key points of the materials, and each example is followed with a similar “Test Yourself” exercise to see if the student understands the concept. Each section ends with its own set of paired exercises to practice the material from that section, and each chapter ends with a section of “Additional Exercises” that are more challenging or require multiple steps or skills to answer.David took the time to treat mathematical problems in Introductory Chemistry one of two ways, either as a conversion-factor problem or as a formula problem. David believes having two basic mathematical approaches (converting and formulas) allows the text to focus on the logic of the approach and not tricks or shortcuts; which speaks to the final point about Introductory Chemistry.You'll notice that David took no shortcuts with the material in this text, his inviting writing style, concise approach, consistent presentation, and interesting pedagogy have given it some of the best peer reviews we've seen at Flat World. So, order a desk copy or dive in now to see for yourself.

The goal of this textbook is not to make you an expert. True expertise in any field is a years-long endeavor. Here I will survey some of the basic topics of chemistry. This survey should give you enough knowledge to appreciate the impact of chemistry in everyday life and, if necessary, prepare you for additional instruction in chemistry.

This course provides an opportunity for students to learn the core concepts of chemistry and understand how those concepts apply to their lives and the world around them, meeting the scope and sequence of most general chemistry courses.

Green chemistry, in addition to being a science, it is also a philosophy and nearly a religion. Attendance at American Chemical Society Green Chemistry & Engineering Conferences will instill such an ideal into any attendant because of the nearly universal appeal and possibilities in this novel approach to radicalizing the business of doing science and engineering.

Ce manuel a été conçu pour les étudiants inscrits au cours CHM1711 Principes de chimie à l'Université d'Ottawa.

The job of a synthetic chemist is akin to that of an architect. While the architect could actually see the building he is constructing, a molecular architect called chemist is handicapped by the fact that the molecule he is synthesizing is too small to be seen. With such a limitation, how does he ‘see’ the developing structure? For this purpose, a chemist makes use of spectroscopic tools. How does he cut, tailor and glue the components on a molecule that he cannot see? For this purpose chemists have developed molecular level tools called Reagents and Reactions. How does he clean the debris and produce pure molecules? This feat is achieved by crystallization, distillation and extensive use of Chromatography techniques. A mastery over several such techniques enables the molecular architect (popularly known as organic chemist) to achieve the challenging task of synthesizing the myriade of molecular structures encountered in Natural Products Chemistry, Drug Chemistry and modern Molecular Materials. In this task, organic chemists are further guided by several ‘thumb rules’ that chemists have evolved over the past two centuries.

Organic chemistry is a two-semester course (Organic Chemistry I, SCC 251 and Organic Chemistry II, SCC 252) required for majors in Biology. The SCC 251 course has been designated for the Integrative Learning Core Competency as well the Digital Communication Ability. This course emphasizes the synthesis, structure, reactivity, and mechanisms of reaction of organic compounds. Laboratory stresses various organic synthetic and analytic techniques (distillation, extraction, chromatography and spectroscopy).
This lab provided an opportunity for students to go deeper with the chemistry content by correlating to the concepts they learned in General Chemistry courses such as Valence shell electron pair repulsion theory (VSEPR), resonance, polarity, dipole moment, acid-base reactions, mole concept, thermochemistry and chemical kinetics. In addition, for the experimental part, applying the techniques such as qualitative analysis of ions, filtration, melting point, optical spectroscopy, and molecular modelling. This lab was performed at the end of the semester when students are familiar with basic organic techniques such as distillation, crystallization, thin layer chromatography (TLC) and column chromatography--techniques they learned previously in this lab. Overall, this lab was designed to develop critical thinking and integrative learning skills while introducing students to the porphyrin and green chemistry concepts. This experiment illustrates the several principles of green chemistry and is easily extendable to introduce topics in other chemistry courses such as NMR spectroscopy (1H, 13C and 19F NMR), material chemistry, click chemistry, coordination chemistry and environmental chemistry.
Learning outcomes that can be assessed using this lab include an understanding of laboratory procedures (methods and techniques), safety hazards, and instrumentation, understanding of concepts and theories gained by performing the experiment, collecting data through observation and/or experimentation (TLC and column chromatography), interpretation of the data (percent yield, UV-vis spectra), drawing conclusions and perspective of the experiment. The knowledge students gain during this process will be useful to connect with future chemistry courses and can also be utilized to do research.
LaGuardia‰Ûªs Core Competencies and Communication Abilities
Main Course Learning Objectives: Based on the principles and methods of green chemistry concept, students will be able to develop the ability to analyze and evaluate organic chemical reactions and processes. Gather, analyze, and interpret experimental data and graph the UV visible spectra using Microsoft excel. The ChemDraw program is used to increase classroom experiences in the preparation of high quality chemical drawings. This software is used to draw and submit chemical compound. ChemDraw Professional can also be used to predict properties, generate spectra, construct correct IUPAC names, and calculate reaction stoichiometry.

Organic chemistry is the chemistry of carbon and carbon-containing compounds. Since the core structural, catalytic, information storage, and retrieval systems of organisms are carbon-based macromolecules, organic chemistry is of direct relevance to the life sciences. Just as importantly, the properties of carbon make possible an amazing range of molecules with unique properties, from small molecules to complex plastics and even more complex biomolecules.

Organic Chemistry research involves the synthesis of organic molecules and the study of their reaction paths, interactions, and applications. Advanced interests include diverse topics such as the development of new synthetic methods for the assembly of complex organic molecules and polymeric materials, organometallic catalysis, organocatalysis, the synthesis of natural and non-natural products with unique biological and physical properties, structure and mechanistic analysis, natural product biosynthesis, theoretical chemistry and molecular modeling, diversity-oriented synthesis, and carbohydrate synthesis.

Organic Chemistry is renowned as the most clearly written book available for organic chemistry. In John McMurry's words, "I wrote this book because I love writing. I get great pleasure and satisfaction from taking a complicated subject, turning it around until I see it clearly from a new angle, and then explaining it in simple words." In Organic Chemistry: A Tenth Edition from OpenStax, McMurry continues this tradition while updating scientific discoveries, highlighting new applications, scrutinizing every piece of art, and providing example problems to assist students. Organic Chemistry: A Tenth Edition continues to meet the scope and sequence of a two-semester organic chemistry course that follows a functional group approach. A highlighted list of changes along with a detailed table of contents and ancillary descriptions can be found on the Instructor and Student resources sections.

Table of Contents:
Chapter 1 Structure and Bonding
Chapter 2 Polar Covalent Bonds; Acids and Bases
Chapter 3 Organic Compounds: Alkanes and Their Stereochemistry
Chapter 4 Organic Compounds: Cycloalkanes and Their Stereochemistry
Chapter 5 Stereochemistry at Tetrahedral Centers
Chapter 6 An Overview of Organic Reactions
Chapter 7 Alkenes: Structure and Reactivity
Chapter 8 Alkenes: Reactions and Synthesis
Chapter 9 Alkynes: An Introduction to Organic Synthesis
Chapter 10 Organohalides
Chapter 11 Reactions of Alkyl Halides: Nucleophilic Substitutions and Eliminations
Chapter 12 Structure Determination: Mass Spectrometry and Infrared Spectroscopy
Chapter 13 Structure Determination: Nuclear Magnetic Resonance Spectroscopy
Chapter 14 Conjugated Compounds and Ultraviolet Spectroscopy
Chapter 15 Benzene and Aromaticity
Chapter 16 Chemistry of Benzene: Electrophilic Aromatic Substitution
Chapter 17 Alcohols and Phenols
Chapter 18 Ethers and Epoxides; Thiols and Sulfides
Chapter 19 Aldehydes and Ketones: Nucleophilic Addition Reactions
Chapter 20 Carboxylic Acids and Nitriles
Chapter 21 Carboxylic Acid Derivatives: Nucleophilic Acyl Substitution Reactions
Chapter 22 Carbonyl Alpha-Substitution Reactions
Chapter 23 Carbonyl Condensation Reactions
Chapter 24 Amines and Heterocycles
Chapter 25 Biomolecules: Carbohydrates
Chapter 26 Biomolecules: Amino Acids, Peptides, and Proteins
Chapter 27 Biomolecules: Lipids
Chapter 28 Biomolecules: Nucleic Acids
Chapter 29 The Organic Chemistry of Metabolic Pathways
Chapter 30 Orbitals and Organic Chemistry: Pericyclic Reactions
Chapter 31 Synthetic Polymers

This 7-minute video lesson looks at naming alcohols. [Organic Chemistry playlist: Lesson 45 of 73].

This resource was contributed by Gamini Gunawardena, Associate Professor (Chemistry) at Utah Valley University. The materials provided with different topics will be highly useful for for undergraduate students.

This is the first course taken in a two sequence Organic Chemistry Course for science majors.

This course examines the behavior of hydrocarbons and their derivatives. Topics covered include alkanes, halides, alcohols, alkynes and stereochemistry.

Upon completion of this course the student will be able to perform the following: (1) Name organic compounds using both the IUPAC and Common System, (2) Determine the Stereochemistry of a compound, (3) Predict the products that will be formed from specific reactions, (4) Predict how changes in the structure of a compound can influence physical properties and reactivity, and (5) Understand the Importance of Mechanisms.

An open textbook that is suitable for the first semester of Organic Chemistry. Basic concepts of the structures and reactivities of organic molecules are covered in this open textbook. Besides the fundamental discussions of organic acids-bases, stereochemistry, IR and NMR, this book also includes the topics of substitution and elimination reactions, radical substitution of alkanes, preparation and reactions of alkenes and alkynes.