Princeton University Press
Aquatic Photosynthesis
Key Metrics
- Paul G Falkowski
- Princeton University Press
- Paperback
- 9780691115511
- 9.96 X 6.86 X 1.09 inches
- 2.25 pounds
- Science > Life Sciences - Botany
- English
Secure TransactionBook Description
Aquatic Photosynthesis is a comprehensive guide to understanding the evolution and ecology of photosynthesis in aquatic environments. This second edition, thoroughly revised to bring it up to date, describes how one of the most fundamental metabolic processes evolved and transformed the surface chemistry of the Earth. The book focuses on recent biochemical and biophysical advances and the molecular biological techniques that have made them possible.
In ten chapters that are self-contained but that build upon information presented earlier, the book starts with a reductionist, biophysical description of the photosynthetic reactions. It then moves through biochemical and molecular biological patterns in aquatic photoautotrophs, physiological and ecological principles, and global biogeochemical cycles. The book considers applications to ecology, and refers to historical developments. It can be used as a primary text in a lecture course, or as a supplemental text in a survey course such as biological oceanography, limnology, or biogeochemistry.
Author Bio
After graduating from the University of British Columbia and doing a 9 month post-doc at the University of Rhode Island, I was hired at the Brookhaven National Laboratory as staff scientist in the newly formed Oceanographic and Atmospheric Sciences Division. I worked there for 23 years and developed the field of environmental biophysics. In 1998 I moved my research group to Rutgers University. In 2007 I was elected to the National Academy of Science for my research on the global carbon cycle.
Research Interests
My research interests are focused on three areas – origins of life, how electron transfer reactions are mediated, and how organisms transformed the geochemistry of Earth. In the evolution of Earth, microbes became a major force in transforming this planet to make it habitable for animals, including humans.
I seek to understand the basic chemical reactions that enabled microbes to transform Earth’s goechemistry. I work at the molecular level of proteins and fundamental chemical reactions of minerals, and the global scale of how this planet came to have oxygen as the second most abundant gas. I am most interested in understanding how these kinds of processes have transformed our planet and may evolve on planetary bodies in our solar system and on extra-solar planets. There are only two questions I address: Where did we come from? And are we alone?
Source: Rutgers, The State University of New Jersey
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