Language : English
Published : 2014-01-01
Pages : 880
Physical Chemistry 2nd Edition
With its easy-to-read approach and focus on core topics, PHYSICAL CHEMISTRY, 2e provides a concise, yet thorough examination of calculus-based physical chemistry. The Second Edition, designed as a learning tool for students who want to learn physical chemistry in a functional and relevant way, follows a traditional organization and now features an increased focus on thermochemistry, as well as new problems, new two-column examples, and a dynamic new four-color design. Written by a dedicated chemical educator and researcher, the text also includes a review of calculus applications as applied to physical chemistry.
About the Author
David W. Ball is Professor of Chemistry at Cleveland State University. His research interests include computational chemistry of new high energy materials, matrix isolation spectroscopy, and various topics in chemical education. He has over 160 publications, equally split between research articles and educational articles, including five books currently in print. He has won recognition for the quality of his teaching, receiving several departmental and college teaching awards as well as the university’s Distinguished Faculty Teaching Award in 2002. He has been a contributing editor to “Spectroscopy” magazine since 1994, where he writes “The Baseline” column on fundamental topics in spectroscopy. He is also active in professional service, serving on the Board of Trustees for the Northeastern Ohio Science and Engineering Fair and the Board of Governors of the Cleveland Technical Societies Council. He is also very active in the American Chemical Society, serving the Cleveland Section as chair twice (in 1998 and 2009) and Councilor from 2001 to the present.
Annual Reports in Medicinal Chemistry provides timely and critical reviews of important topics in medicinal chemistry with an emphasis on emerging topics in the biological sciences that are expected to provide the basis for entirely new future therapies. * Reviews on hot topics of interest in small molecule drug discovery heavily pursued by industrial research organizations* Provides preclinical information in the context of chemical structures* Knowledgeable section editors who evaluate invited reviews for scientific rigor
About the Author
Dr. Manoj Desai began his career in the pharmaceutical industry at Pfizer Inc, Central Research Division, Groton, CT (1986-1994) before moving to Chiron Corporation (1994-2003) as Director of medicinal chemistry; he was promoted to Vice President, lead discovery and medicinal chemistry (2000). In October 2003, he was appointed Vice President of medicinal chemistry at Gilead Sciences. At Pfizer, he was responsible for the medicinal chemistry efforts that lead to the discovery of oral Substance P antagonist CP-99994 which became the basis for the discovery of the new anti-emetics. At Chiron he formulated macrobead technology for the synthesis and screening of compound libraries for HTS and built the medicinal chemistry department with focus on kinase inhibitors. At Gilead, he was an active proponent to develop a pharmacoenhancer devoid of antiviral activity to improve the pharmacokinetics of integrase inhibitor elvitegravir. These efforts led to the discovery of Cobicistat which is one of components of StribildTM that was approved by FDA in August 2012 for the treatment of HIV infection. He is co-inventor on patents of Cobicistat (US 8,148,374), StribildTM and Ledipasvir (US 8,273,341; Phase III). Furthermore, his group at Gilead has advanced numerous compounds into clinical development for the treatment of antiviral diseases, cancer and cardiovascular diseases. Dr. Desai obtained Ph.D. in organic chemistry from the M.S. University of Baroda in 1981 working with Dr. Sukh Dev and then carried out post-doctoral fellowships at Purdue University working with Professor Herbert C. Brown (19981-1983) and at Harvard University with Professor Elias J. Corey (1983-1986). During his postdoctoral studies, he worked on natural product isolation, development of asymmetric synthetic methods using organoboranes and total synthesis of complex natural products such as retigeranic acid, ?-trans bergamotene and ginkgolide B. He has co-authored >60 publications in peer reviewed journals and is an inventor on >25 issued patents. Furthermore, Dr. Desai is Editor-in-Chief for Annual Reports in Medicinal chemistry (2012-current), and have co-edited Comprehensive Medicinal Chemistry II (volume 7). In 2013, he co-edited book titled “Successful Strategies for the Discovery of Antiviral Drugs .
Discover a new generation of organic nanomaterials and their applications
Recent developments in nanoscience and nanotechnology have given rise to a new generation of functional organic nanomaterials with controlled morphology and well-defined properties, which enable a broad range of useful applications. This book explores some of the most important of these organic nanomaterials, describing how they are synthesized and characterized. Moreover, the book explains how researchers have incorporated organic nanomaterials into devices for real-world applications.
Featuring contributions from an international team of leading nanoscientists, Organic Nanomaterials is divided into five parts:
- Part One introduces the fundamentals of nanomaterials and self-assembled nanostructures
- Part Two examines carbon nanostructures—from fullerenes to carbon nanotubes to graphene—reporting on properties, theoretical studies, and applications
- Part Three investigates key aspects of some inorganic materials, self-assembled monolayers, organic field effect transistors, and molecular self-assembly at solid surfaces
- Part Four explores topics that involve both biological aspects and nanomaterials such as biofunctionalized surfaces
- Part Five offers detailed examples of how organic nanomaterials enhance sensors and molecular photovoltaics
Most of the chapters end with a summary highlighting the key points. References at the end of each chapter guide readers to the growing body of original research reports and reviews in the field.
Reflecting the interdisciplinary nature of organic nanomaterials, this book is recommended for researchers in chemistry, physics, materials science, polymer science, and chemical and materials engineering. All readers will learn the principles of synthesizing and characterizing new organic nanomaterials in order to support a broad range of exciting new applications.
About the Author
Tomás Torres is Full Professor of Organic Chemistry at the Universidad Autónoma de Madrid and Associated Senior Scientist at IMDEA Nanoscience in Madrid. He has published 370 papers and reviews and holds forty patents.
Giovanni Bottari is Associate Professor of Organic Chemistry at the Universidad Autónoma de Madrid and Associated Scientist at IMDEA Nanoscience in Madrid. He has published thirty-six papers and reviews and two book chapters.
Explains how GIS enhances the development of chemical fate and transport models
Over the past decade, researchers have discovered that geographic information systems (GIS) are not only excellent tools for managing and displaying maps, but also useful in the analysis of chemical fate and transport in the environment. Among its many benefits, GIS facilitates the identification of critical factors that drive chemical fate and transport. Moreover, GIS makes it easier to communicate and explain key model assumptions.
Based on the author’s firsthand experience in environmental assessment, GIS Based Chemical Fate Modeling explores both GIS and chemical fate and transport modeling fundamentals, creating an interface between the two domains. It then explains how GIS analytical functions enable scientists to develop simple, yet comprehensive spatially explicit chemical fate and transport models that support real-world applications. In addition, the book features:
- Practical examples of GIS based model calculations that serve as templates for the development of new applications
- Exercises enabling readers to create their own GIS based models
- Accompanying website featuring downloadable datasets used in the book’s examples and exercises
- References to the literature, websites, data repositories, and online reports to facilitate further research
- Coverage of important topics such as spatial decision support systems and multi-criteria analysis as well as ecological and human health risk assessment in a spatial context
GIS Based Chemical Fate Modeling makes a unique contribution to the environmental sciences by explaining how GIS analytical functions enhance the development and interpretation of chemical fate and transport models. Environmental scientists should turn to this book to gain a deeper understanding of the role of GIS in describing what happens to chemicals when they are released into the environment.
About the Author
ALBERTO PISTOCCHI, MSc Eng, MSc Phil, PhD, is Adjunct Professor of Spatial Decision Support Systems at the University of Trento, Italy, and the author of several scientific contributions to the fields of hydrology, environmental assessment, chemical fate and transport modeling, and spatial decision support systems. As a researcher, environmental analyst, and project manager, he has been working for the European Commission’s Joint Research Centre, the Emilia Romagna regional government, and other private and public organizations. He is a founding partner (2001) and the scientific director of GECOsistema, a research spin-off from the University of Bologna, Italy.
This Cengage Technology Edition is the result of an innovative and collaborative development process. The textbook retains the hallmark approach of this respected text, whilst presenting the content in a print and digital hybrid that has been tailored to meet the rapidly developing demands of today’s lecturers and students. This blended solution offers a streamlined textbook for greater accessibility and convenience, complemented by a bolstered online presence, for a truly multi-faceted learning experience. Skoog and West’s Fundamentals of Analytical Chemistry provides a thorough background in the chemical principles that are particularly important to analytical chemistry. Students using this book will develop an appreciation for the difficult task of judging the accuracy and precision of experimental data and to show how these judgements can be sharpened by applying statistical methods to analytical data. The book introduces a broad range of modern and classic techniques that are useful in analytical chemistry; as well as giving students the skills necessary for both obtaining data in the laboratory and solving quantitative analytical problems.