We use cookies to distinguish you from other users and to provide you with a better experience on our websites. Close this message to accept cookies or find out how to manage your cookie settings.
To save content items to your account,
please confirm that you agree to abide by our usage policies.
If this is the first time you use this feature, you will be asked to authorise Cambridge Core to connect with your account.
Find out more about saving content to .
To save content items to your Kindle, first ensure no-reply@cambridge.org
is added to your Approved Personal Document E-mail List under your Personal Document Settings
on the Manage Your Content and Devices page of your Amazon account. Then enter the ‘name’ part
of your Kindle email address below.
Find out more about saving to your Kindle.
Note you can select to save to either the @free.kindle.com or @kindle.com variations.
‘@free.kindle.com’ emails are free but can only be saved to your device when it is connected to wi-fi.
‘@kindle.com’ emails can be delivered even when you are not connected to wi-fi, but note that service fees apply.
We know that the Earth’s climate has changed in the past, including times when humans had yet to put in an appearance. These changes must, therefore, have been the result of ’natural processes’. So how do we know that current changes are not similarly natural? The challenge this poses for science is to understand the processes that were at work in the past, and compare them with the climate drivers, both natural and anthropogenic, at work today. There are two reasons to try to unravel the climatic history of our planet. The first might be described as its intrinsic interest. The more important reason is to see what lessons we can learn that might help us think about potential future climate change, and especially the much slower response of sea level to changes in temperature. This is the reason that it is now an important component of the IPCC process.
This compelling textbook provides a broad overview of the science underpinning our understanding of our climate, and how it is changing. Presented in clear and accessible language, and requiring only minimal algebra, it enables students to understand how our planet “behaves” under “normal conditions” and how human activity has moved us away from that normal. It walks the student comprehensively through the basic science, including how greenhouse gases absorb radiation and, crucially, a chapter on aerosols, major players in climate change. Diverse case studies and examples illuminate the impact and connections to real world events while review questions and exercises consolidate knowledge. Including the latest results from the IPCC 6th Assessment Report, it concludes by exploring climate modelling, equipping students with an understanding of how to simulate both past climate changes and projections of future climate change. Online resources include lecture slides, solutions and Excel code.
Planting trees for climate services – storing carbon, cooling surface climate, enhancing rainfall, providing aerosols that reflect solar radiation, creating favorable microclimate refuges, or other benefits – is not small-scale or immediate. It requires vast tracts of healthy and thriving forests and setting aside the land to grow forests for 50 to 100 years or longer. Achieving the climate benefits of forests requires a permanent forest presence over many decades. Climate will change during that time, and a forest planted today may not thrive in the climate of tomorrow. The forests of the future will grow in a climate different from today's and likely in regions of the world that differ from today's. They will be stressed by climate change, increased wildfires, disease, and insects. Asking forests to solve the climate problem requires a long-term commitment to and investment in forests and their health. Forest growth, too, is not one-directional. Wildfires, droughts, insects, and wind storms continually reset forests back to young stages of development. An old-growth forest that has accumulated enormous stores of carbon in its trees and soil becomes a young, regenerating forest.
Chapter 6 presents data about the first members of our own species, Homo sapiens, and how they lived and shared the planet with at least five other species of Homo. It presents the cultural succession of the Upper Paleolithic and the repercussions that our species had on the planet and other life forms as members spread out into virgin territories of the world.
Scott’s lifelong passion for trees is the subject of this chapter. Trees in Scotland’s folklore and mythology, as individual living species, and collectively in the environments that once were the nation’s great forests, are shown to be of paramount importance to his literary and personal writing. Articles for the Quarterly Review and other periodicals, letters to correspondents, including poet Joanna Baillie, and his unpublished personal planting journal Sylva Abbotsfordiensis are explored for their record of Scott’s nationally acknowledged expertise in silviculture, his planting programmes at Abbotsford and his experiments with growing conditions. Using a deep-time framework and recent scientific discovery, the chapter looks back to the first tree species to colonize Scotland after the last great glaciation. Scott’s planting of native species and advocacy of their value to the nation is revealed as a form of environmental reconstitution. Tensions between the aesthetics of planting and agrarian economics are investigated.
Expansion of the Human System began with divergence and migration of speaking communities in their homeland. Then, up to 45,000 years ago, migrants moved southwest across Africa and eastward along the Indian Ocean littoral, as documented through archaeology, genomics, and climate. Language evidence, supplemented by an accompanying website, confirms the value of Joseph H. Greenberg’s tradition of large-scale linguistic analysis. African migration included multiple settlements among preexisting hominin populations. The parallel migration into Asia, now identified genetically as a single migration, relied on watercraft at most stages. Surviving language groups indicate the path of migrants along the Indian Ocean littoral. Only after 45,000 years ago were migrants able to move northward, into the ecologically distinctive temperate zone. Once in the steppes, migrants moved east to Northeast Asia and west to the Black Sea. As networks facilitated exchange of dogs, religious ideas, bows and arrows, the Human System thus expanded from its initial locality to become a hemispheric network of communities in contact.
After millennia of cooling, the Last Glacial Maximum reached an extreme. Every species adjusted, even in the tropics. Humans responded with new social organization: communities pooled resources to face issues of leadership, forming confederations that pooled resources. After the coldest moment – 21,500 years ago – migrants moved to newly fertile lands as temperature rose almost ceaselessly for millennia. Intensive food gathering was accompanied by productive institutions: architecture for permanent homes, textiles, ceramics, and workshops for visual representation. Eurasiatic-speakers moved westward across Siberia; others moved both north and south in eastern Asia and between Africa and western Asia. New details on American settlement now reveal two groups of Asian voyagers who followed the “kelp highway” just offshore. The main group formed settlements along the Pacific littoral, expanding inland from points as far as southern Chile by 19,000 years ago. By the end of the Pleistocene, the achievements of early humanity included occupying most of Earth, supplementing foraging with production, exquisite visual representations, and dependable adaptability.
The tale of human habitation of the Nile Valley is a long one and includes famine, disaster, global environmental events, and human resolve told against a background of ever-changing landscape. In this volume, Judith Bunbury examines the region over a 10,000 year period, from the Neolithic to the Roman conquest. Charting the progression of the river as it meanders through the region and over the ages, she demonstrates how ancient Egyptians attempted to harness the Nile's power as a force for good. Over the generations, they learned how to farm and build on its banks, and also found innovative solutions to cope in a constantly evolving habitat. Using the latest theories and evidence, this richly illustrated volume also provides a blueprint for the future management of the Nile.
Recommend this
Email your librarian or administrator to recommend adding this to your organisation's collection.