Images and text capture the astonishing beauty of the chemical processes that create snowflakes, bubbles, flames, and other wonders of nature. Chemistry is not just about microscopic atoms doing inscrutable things; it is the process that makes flowers and galaxies. We rely on it for bread-baking, vegetable-growing, and producing the materials of daily life. In stunning images and illuminating text, this book captures chemistry as it unfolds. Using such techniques as microphotography, time-lapse photography, and infrared thermal imaging, The Beauty of Chemistry shows us how chemistry underpins the formation of snowflakes, the science of champagne, the colors of flowers, and other wonders of nature and technology. We see the marvelous configurations of chemical gardens; the amazing transformations of evaporation, distillation, and precipitation; heat made visible; and more.
Integrate chemistry and art with hands-on activities and fascinating demonstrations that enable students to see and understand how the science of chemistry is involved in the creation of art. Investigate such topics as color integrated with electromagnetic radiation, atoms, and ions; paints integrated with classes of matter, specifically solutions; three-dimensional works of art integrated with organic chemistry; photography integrated with chemical equilibrium; art forgeries integrated with qualitative analysis; and more. This is a complete and sequential introduction to General Chemistry and Introductory Art topics. In this newly revised edition, the author, a retired Chemistry teacher, gives extensive and in-depth new explanations for the experiments and demonstrations, as well as expanded safety instructions to insure student safety. Grades 7-12.
In this book Kovac and Weisberg bring together twenty-eight of Hoffmann' s most philosophically significant and interesting pieces, many of which are not easily found in print.
Science and art are increasingly interconnected in the activities of the study and conservation of works of art. Science plays a key role in cultural heritage, from developing new analytical techniques for studying the art, to investigating new ways of preserving the materials for the future. For example, high resolution multispectral examination of paintings allows art historians to view underdrawings barely visible before, while the use of non-invasive and micro-sampling analytical techniques allow scientists to identify pigments and binders that help art conservators in their work. It also allows curators to understand more about how the artwork was originally painted. Through a series of case studies written by scientists together with art historians, archaeologists and conservators, Science and Art: The Painted Surface demonstrates how the cooperation between science and humanities can lead to an increased understanding of the history of art and to better techniques in conservation. The examples used in the book cover paintings from ancient history, Renaissance, modern, and contemporary art, belonging to the artistic expressions of world regions from the Far East to America and Europe. Topics covered include the study of polychrome surfaces from pre-Columbian and medieval manuscripts, the revelation of hidden images below the surface of Van Gogh paintings and conservation of acrylic paints in contemporary art. Presented in an easily readable form for a large audience, the book guides readers into new areas uncovered by the link between science and art. The book features contributions from leading institutions across the globe including the Metropolitan Museum of Art, New York; Art Institute of Chicago; Getty Conservation Institute; Opificio delle Pietre Dure, Firenze; National Gallery of London; Tate Britain; Warsaw Academy of Fine Art and the National Gallery of Denmark as well as a chapter covering the Thangka paintings by Nobel Prize winner Richard Ernst.
The story of this little-known Dutch physician “will interest students and practitioners of history, chemistry, and philosophy of science” (Choice). In Inventing Chemistry, historian John C. Powers turns his attention to Herman Boerhaave (1668–1738), a Dutch medical and chemical professor whose work reached a wide, educated audience and became the template for chemical knowledge in the eighteenth century. The primary focus of this study is Boerhaave’s educational philosophy, and Powers traces its development from Boerhaave’s early days as a student in Leiden through his publication of the Elementa chemiae in 1732. Powers reveals how Boerhaave restructured and reinterpreted various practices from diverse chemical traditions (including craft chemistry, Paracelsian medical chemistry, and alchemy), shaping them into a chemical course that conformed to the pedagogical and philosophical norms of Leiden University’s medical faculty. In doing so, Boerhaave gave his chemistry a coherent organizational structure and philosophical foundation, and thus transformed an artisanal practice into an academic discipline. Inventing Chemistry is essential reading for historians of chemistry, medicine, and academic life.
This unique book presents an integrated approach to the chemistry of art materials, exploring the many chemical processes involved. The Chemistry and Mechanism of Art Materials: Unsuspected Properties and Outcomes engages readers with historical vignettes detailing examples of unexpected outcomes due to materials used by known artists. The book discusses artists’ materials focusing on relevant chemical mechanisms which underlie the synthesis and deterioration of inorganic pigments in paintings, the ageing of the binder in oil paintings, and sulfation of wall paintings as well as the toxicology of these pigments and solvents used by artists. Mechanisms illustrate the stepwise structural transformation of a variety of art materials. Based on the author’s years of experience teaching college chemistry, the approach is descriptive and non-mathematical throughout. An introductory section includes a review of basic concepts and provides concise descriptions of analytical methods used in contemporary art conservation. Additional features include: Illustrations of chemical reactivity associated with art materials Includes a review of chemical bonding principles, redox and mechanism writing Covers analytical techniques used by art conservation scientists Accessible for readers with a limited science background Provides numerous references for readers seeking additional information