MacArthur was a professor at the
University of Pennsylvania, 1958–65, and professor of biology at
Princeton University, 1965–72. He played an important role in the development of
niche partitioning, and with
E.O. Wilson he co-authored
The Theory of Island Biogeography (1967), a work which changed the field of
biogeography, drove
community ecology and led to the development of modern
landscape ecology. His emphasis on
hypothesis testing helped change ecology from a primarily descriptive field into an experimental field, and drove the development of
theoretical ecology. He also wrote
Geographical Ecology: Patterns in the Distribution of Species (1972), which summarizes much of his life's work.
The theory of island biogeography Robert MacArthur, in collaboration with Edward O. Wilson, developed the influential
theory of island biogeography, which revolutionized how ecologists understand species diversity and distribution. Their seminal 1967 book,
The Theory of Island Biogeography, introduced the concept of a dynamic equilibrium between immigration and extinction rates as determinants of species richness on islands. They also coined the
r- and K-selection theory, which describes contrasting reproductive strategies:
r-selected species maximize growth rates in unpredictable environments, while
K-selected species emphasize efficiency and competition in stable environments. Their equilibrium theory has been extensively tested and generally supported by empirical studies. For instance, researchers have validated the predictions regarding the effects of island size and isolation on species diversity through observations in archipelagos like the
Galápagos and experimental work on
mangrove islands. The theory also laid the foundation for
metapopulation and
landscape ecology, broadening its influence far beyond island studies.
Niche theory In their 1967 paper, MacArthur and Richard Levins formalized the concept of
limiting similarity, showing mathematically that there is an upper limit to how similar coexisting species can be in their resource use. This work provided a theoretical foundation for understanding the conditions under which species with overlapping niches can coexist. Earlier, MacArthur had demonstrated niche partitioning empirically in his groundbreaking 1958 paper on
warblers (
Dendroica species) in northeastern forests. By observing how different warbler species foraged at varying heights and parts of trees, he provided one of the first clear examples of how
niche differentiation allows species to coexist. MacArthur also contributed to the theory of
species abundance distributions with his "broken stick model," first proposed in 1957. This model likens the division of resources in an ecosystem to breaking a stick into randomly sized pieces, predicting the relative abundance of species in a community. While later models (e.g., the log-normal distribution) gained prominence, the broken stick model remains a landmark in the history of ecological theory.
Consumer-resource theory MacArthur was a pioneer in developing mathematical models for consumer-resource dynamics, aiming to explain how interactions between species shape
ecological communities. He introduced a general framework for consumer-resource interactions, which is widely used by theoretical modelers today and forms the basis of
modern coexistence theory. He also used his model to demonstrate that increasing the number of species reduces a community's stability, a precursor to debates on the "diversity-stability" hypothesis. One of his key contributions was identifying a minimization principle for consumer-resource dynamics. He showed that these systems tend to minimize a quantity related to resource overlap, providing a theoretical foundation for understanding competitive exclusion and coexistence. In collaboration with
Michael Rosenzweig, MacArthur helped develop the
Rosenzweig-MacArthur model in the early 1960s. This
predator-prey model incorporates a
type II functional response, where the predator’s consumption rate saturates with increasing prey density. Their model is notable for predicting
population cycles in predator-prey interactions, which occur due to the lag between prey growth and predator consumption. This work remains central to the study of ecological dynamics. ==See also==