Richard H. Waring

Last updated

Richard Harvey Waring (born 17 May, 1935), is an American scientist, educator, and author. Born in Chicago, Illinois, he completed his BSc and MSc at the University of Minnesota, and his Ph.D. at the University of California, Berkeley. His research focuses on the physiological ecology of trees, their health and distribution in response to climatic variation across regions. He has made significant contributions to the understanding of the physiology of stressed trees, the ecology of forests, and the functioning of vegetation across regions. As a co-developer of the forest growth model 3-PG (Physiological Processes Predicting Growth), [1] [2] he won the 2020 Marcus Wallenberg Prize together with Joseph Landsberg and Nicholas Coops. [3] [4] [5]

Contents

Waring has published 245 scientific papers and has an h-index of 74. [6] The original paper on the 3-PG model has attracted almost 2,000 citations. [7]

Career

Waring was a distinguished professor at Oregon State University [8] [9] and held guest professorships and visiting scientist appointments at the Botanical Institute, University of Innsbruck, Austria (1969-70); School of Forestry and Natural Resources, University of Edinburgh, Scotland (1976-77); Swedish University of Agricultural Sciences, Uppsala, Sweden (1981-82); Ecosystem Center, Marine Biological Laboratory, Woods Hole, Massachusetts (1986-87); University of Waikato, Christchurch, New Zealand (part of 1990); Land-Atmosphere Interactions, National Aeronautics and Space Administration (NASA), [10] [11] [12] Washington, D.C. (acting program manager, 1992-93); Centre for Environmental Mechanics, CSIRO, Canberra, Australia (1996-97); Scottish Forestry Trust, Edinburgh, Scotland (part of 1998); and Centre for Water Research, University of Western Australia, Perth, Australia (part of 2007).[ citation needed ]

Books

Related Research Articles

<span class="mw-page-title-main">Ecology</span> Study of organisms and their environment

Ecology is the natural science of the relationships among living organisms, including humans, and their physical environment. Ecology considers organisms at the individual, population, community, ecosystem, and biosphere levels. Ecology overlaps with the closely related sciences of biogeography, evolutionary biology, genetics, ethology, and natural history.

<span class="mw-page-title-main">Human ecology</span> Study of the relationship between humans and their natural, social, and built environments

Human ecology is an interdisciplinary and transdisciplinary study of the relationship between humans and their natural, social, and built environments. The philosophy and study of human ecology has a diffuse history with advancements in ecology, geography, sociology, psychology, anthropology, zoology, epidemiology, public health, and home economics, among others.

<span class="mw-page-title-main">Conservation biology</span> Study of threats to biological diversity

Conservation biology is the study of the conservation of nature and of Earth's biodiversity with the aim of protecting species, their habitats, and ecosystems from excessive rates of extinction and the erosion of biotic interactions. It is an interdisciplinary subject drawing on natural and social sciences, and the practice of natural resource management.

<span class="mw-page-title-main">Landscape ecology</span> Science of relationships between ecological processes in the environment and particular ecosystems

Landscape ecology is the science of studying and improving relationships between ecological processes in the environment and particular ecosystems. This is done within a variety of landscape scales, development spatial patterns, and organizational levels of research and policy. Concisely, landscape ecology can be described as the science of "landscape diversity" as the synergetic result of biodiversity and geodiversity.

<span class="mw-page-title-main">Ecosystem engineer</span> Ecological niche

An ecosystem engineer is any species that creates, significantly modifies, maintains or destroys a habitat. These organisms can have a large impact on species richness and landscape-level heterogeneity of an area. As a result, ecosystem engineers are important for maintaining the health and stability of the environment they are living in. Since all organisms impact the environment they live in one way or another, it has been proposed that the term "ecosystem engineers" be used only for keystone species whose behavior very strongly affects other organisms.

Adaptive management, also known as adaptive resource management or adaptive environmental assessment and management, is a structured, iterative process of robust decision making in the face of uncertainty, with an aim to reducing uncertainty over time via system monitoring. In this way, decision making simultaneously meets one or more resource management objectives and, either passively or actively, accrues information needed to improve future management. Adaptive management is a tool which should be used not only to change a system, but also to learn about the system. Because adaptive management is based on a learning process, it improves long-run management outcomes. The challenge in using the adaptive management approach lies in finding the correct balance between gaining knowledge to improve management in the future and achieving the best short-term outcome based on current knowledge. This approach has more recently been employed in implementing international development programs.

Sustainable yield is the amount of a resource that humans can harvest without over-harvesting or damaging a potentially renewable resource.

<span class="mw-page-title-main">Ecological restoration</span> Scientific study of renewing and restoring ecosystems

Ecological restoration, or ecosystem restoration, is the process of assisting the recovery of an ecosystem that has been degraded, damaged, or destroyed. It is distinct from conservation in that it attempts to retroactively repair already damaged ecosystems rather than take preventative measures. Ecological restoration can reverse biodiversity loss, combat climate change, and support local economies. Habitat restoration involves the deliberate rehabilitation of a specific area to reestablish a functional ecosystem. To achieve successful habitat restoration, it's essential to understand the life cycles and interactions of species, as well as the essential elements such as food, water, nutrients, space, and shelter needed to support species populations. When it's not feasible to restore habitats to their original size or state, designated areas known as wildlife corridors can be established. These corridors connect different habitats and open spaces, facilitating the survival of species within human-dominated landscapes. For instance, marshes serve as critical stopover sites for migratory birds, wildlife overpasses enable animals to safely cross over highways, and protected riparian zones within urban settings provide necessary refuges for flora and fauna. The United Nations named 2021-2030 the Decade on Ecosystem Restoration.

In ecology, an ecosystem is said to possess ecological stability if it is capable of returning to its equilibrium state after a perturbation or does not experience unexpected large changes in its characteristics across time. Although the terms community stability and ecological stability are sometimes used interchangeably, community stability refers only to the characteristics of communities. It is possible for an ecosystem or a community to be stable in some of their properties and unstable in others. For example, a vegetation community in response to a drought might conserve biomass but lose biodiversity.

Bacteriophages (phages), potentially the most numerous "organisms" on Earth, are the viruses of bacteria. Phage ecology is the study of the interaction of bacteriophages with their environments.

Ecological forecasting uses knowledge of physics, ecology and physiology to predict how ecological populations, communities, or ecosystems will change in the future in response to environmental factors such as climate change. The goal of the approach is to provide natural resource managers with information to anticipate and respond to short and long-term climate conditions.

<span class="mw-page-title-main">Ecosystem management</span> Natural resource management

Ecosystem management is an approach to natural resource management that aims to ensure the long-term sustainability and persistence of an ecosystem's function and services while meeting socioeconomic, political, and cultural needs. Although indigenous communities have employed sustainable ecosystem management approaches implicitly for millennia, ecosystem management emerged explicitly as a formal concept in the 1990s from a growing appreciation of the complexity of ecosystems and of humans' reliance and influence on natural systems.

Land restoration, which may include renaturalisation or rewilding, is the process of restoring land to a different or previous state with an intended purpose. That purpose can be a variety of things such as what follows: being safe for humans, plants, and animals; stabilizing ecological communities; cleaning up pollution; creating novel ecosystems; or restoring the land to a historical condition, for example how indigenous people managed the land. Ecological destruction or degradation, to which land restoration serves as an antidote, is usually the consequence of human influence's intended or unintended consequences. This can include pollution, deforestation, salination, or species endangerment, among many more. Land restoration is not the same as land reclamation, where existing ecosystems are altered or destroyed to give way for cultivation or construction. Land restoration can enhance the supply of valuable ecosystem services that benefit people.

<span class="mw-page-title-main">Nutrient cycle</span> Set of processes exchanging nutrients between parts of a system

A nutrient cycle is the movement and exchange of inorganic and organic matter back into the production of matter. Energy flow is a unidirectional and noncyclic pathway, whereas the movement of mineral nutrients is cyclic. Mineral cycles include the carbon cycle, sulfur cycle, nitrogen cycle, water cycle, phosphorus cycle, oxygen cycle, among others that continually recycle along with other mineral nutrients into productive ecological nutrition.

<span class="mw-page-title-main">Complex early seral forest</span> Type of ecosystem present after a major disturbance

Complex early seral forests, or snag forests, are ecosystems that occupy potentially forested sites after a stand-replacement disturbance and before re-establishment of a closed forest canopy. They are generated by natural disturbances such as wildfire or insect outbreaks that reset ecological succession processes and follow a pathway that is influenced by biological legacies that were not removed during the initial disturbance. Complex early seral forests develop with rich biodiversity because the remaining biomass provides resources to many life forms and because of habitat heterogeneity provided by the disturbances that generated them. In this and other ways, complex early seral forests differ from simplified early successional forests created by logging. Complex early seral forest habitat is threatened from fire suppression, thinning, and post-fire or post-insect outbreak logging.

Nancy Huntly is an American ecologist based at Utah State University, where she is a Professor in the Department of Biology and director of the USU Ecology Center. Her research has been on biodiversity, herbivory, and long-term human ecology. She started her position at USU in 2011, after serving as a Program Officer in the Division of Environmental Biology at the National Science Foundation. Prior to that she was a faculty member in the Department of Biological Sciences at Idaho State University (Pocatello).

<span class="mw-page-title-main">Jill S. Baron</span> American ecologist

Jill S. Baron is an American ecosystem ecologist specializing in studying the effects of atmospheric nitrogen deposition in mountain ecosystems. She is a senior scientist at the United States Geological Survey and a senior research ecologist at the Natural Resource Ecology Laboratory at Colorado State University.

Jeannine Cavender-Bares is a Distinguished McKnight University Professor at the University of Minnesota in the Department of Ecology, Evolution & Behavior. Her research integrates evolutionary biology, ecology, and physiology by studying the functional traits of plants, with a particular focus on oaks.

Bruce Pettit McCune is an American lichenologist, botanist, plant ecologist, and software developer for analysis of ecological data.

<span class="mw-page-title-main">Joseph Landsberg</span> Australian Forestry Scientist

Joseph John Landsberg, is an Australian scientist, author, science administrator and consultant. Born in Zimbabwe he completed his BSc and MSc at Natal University, South Africa, and his Ph.D. at the University of Bristol, UK., where his research focused on the interactions between climate, weather, and forests around the world.

References

  1. "3-PG Forest Growth Model | Process Introduction". The University of British Columbia . Retrieved 2024-01-21.
  2. Landsberg, J. J.; Waring, R. H. (1997-08-01). "A generalised model of forest productivity using simplified concepts of radiation-use efficiency, carbon balance and partitioning". Forest Ecology and Management. 95 (3): 209–228. doi:10.1016/S0378-1127(97)00026-1. ISSN   0378-1127.
  3. Marcus Wallenberg Prize - MWP (2021-10-27). "MWP Symposium 2021 - Prof. Richard H Waring". YouTube . Retrieved 2024-01-23.
  4. Kirkland, Jacqlyn (2020-05-01). "OSU's Waring Shares Marcus Wallenberg Prize". Panel World. Retrieved 2024-01-22.
  5. Kerstin (2020-04-28). "Model for forest growth during climate change". MWP. Retrieved 2024-01-21.
  6. "Richard H Waring". Google Scholar . Retrieved 2024-01-21.
  7. "A generalised model of forest productivity using simplified concepts of radiation-use efficiency, carbon balance and partitioning". Google Scholar . Retrieved 2024-01-21.
  8. "Bio: Richard (Dick) Waring". Oregon State University . Retrieved 2024-01-21.
  9. "Dick Waring Oral History Interview". Oregon State University Libraries. 2015-12-18. Retrieved 2024-01-21.
  10. Goward, Samuel N.; Waring, Richard H.; Dye, Dennis G.; Yang, Jingli (May 1994). "Ecological Remote Sensing at OTTER: Satellite Macroscale Observations". Ecological Applications. 4 (2): 322–343. doi:10.2307/1941937. ISSN   1051-0761.
  11. Runyon, J.; Waring, R. H.; Goward, S. N.; Welles, J. M. (May 1994). "Environmental Limits on Net Primary Production and Light‐Use Efficiency Across the Oregon Transect". Ecological Applications. 4 (2): 226–237. doi:10.2307/1941929. ISSN   1051-0761.
  12. "NASA". Research Office. 2014-10-28. Retrieved 2024-01-21.
  13. Roberts, J. (March 1987). "Forest ecosystems: Concepts and management. Richard H. Waring and William H. Schlesinger. Academic Press, London, 340pp. ISBN 0‐12‐735441‐7. Price: £21 (Soft Cover)". Hydrological Processes. 1 (2): 221–224. doi:10.1002/hyp.3360010209. ISSN   0885-6087.
  14. Zedaker, Shepard M. "Forest Ecosystems: Concepts and Management". Forest Science. 32 (3): 841–842. doi:10.1093/forestscience/32.3.841 via Oxford Academic.
  15. Rastetter, Edward B. (1999). "Forest Ecosystems: Analysis at Multiple Scales, 2nd edition". Tree Physiology. 19 (2): 138.
  16. Ågren, Göran I. (1998). "Review of Forest ecosystems. Analysis at multiple scales. 2nd edn". Annals of Botany . 82 (6): 901–902. ISSN   0305-7364 via JSTOR.
  17. Apostol, Dean (November 2015). "Forests in Our Changing World: New Principles for Conservation and Management". Restoration Ecology. 23 (6): 966–966. doi:10.1111/rec.12298. ISSN   1061-2971.
  18. Horton, Bryony (May 2016). "Forests in Our Changing World. New Principles for Conservation and ManagementLandsbergJoe and WaringRichard, Island Press, Washington DC, 2014. xii + 209 pp. Price AUD $49.99. ISBN: 9781610914963 (paperback)". Ecological Management & Restoration. 17 (2). doi:10.1111/emr.12218. ISSN   1442-7001.