Fission-fusion society is a complex social structure that is often found in animals, particularly among those living in large groups. It is characterized by the formation of temporary subgroups (fissions) that periodically merge back together (fusions) with the larger group, creating a dynamic and fluid social system. This type of society is commonly observed in primates, dolphins, elephants, and some bird species, and serves as a means to maintain social relationships, facilitate cooperation and communication, and manage conflict within the group. The fission-fusion society is an intriguing model of social organization that offers insights into the evolution of complex social systems and the intricate ways in which animals interact with one another.

Chimpanzees Live In Fission-Fusion Social Systems Characterized By Females

Chimpanzees live in fission-fusion social systems characterized by females. This means that they have fluid associations and social dynamics that shift over time depending on factors such as food availability, mating opportunities, and the composition of the group.

Fission-fusion social systems refer to groups of individuals that have the ability to split up and come back together as a cohesive unit when necessary. Chimpanzees exhibit this type of social system because they have a tendency to form subgroups as they move through the forest to forage, and then reunite with other individuals later on.

Females play a crucial role in chimpanzee fission-fusion social systems because they are the ones who ultimately determine where the group goes and with whom they associate. Females are generally the ones who initiate the formation of subgroups and decide when to rejoin the main group.

The ability to form fission-fusion social systems allows chimpanzees to adapt to changing environmental conditions and capitalize on new resources. By constantly shifting their social dynamics, they are able to respond to changing circumstances in an agile and flexible manner.

Overall, the fission-fusion social systems characterized by females are a defining feature of chimpanzee societies and play a critical role in their survival and adaptation.

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Fission–fusion society

Social organization

In ethology, a fission–fusion society is one in which the size and composition of the social group change as time passes and animals move throughout the environment; animals merge into a group (fusion)—e.g. sleeping in one place—or split (fission)—e.g. foraging in small groups during the day. For species that live in fission–fusion societies, group composition is a dynamic property. The change in composition, subgroup size, and dispersion of different groups are 3 main elements of a fission-fusion society.

This social organization is found in several primates, elephants, cetaceans, ungulates, social carnivores, some birds and some fish.

Species

Fission-fusion societies occur among many different species of primates (e.g. chimpanzees, orangutans, and humans), elephants (e.g. forest elephants, African elephants), and bats (e.g. northern long-eared bats). The change in composition, subgroup size, and dispersion of different groups are 3 main elements of a fission-fusion society.

Primates

Chimpanzees

Chimpanzees often form smaller subgroups when travelling for longer periods at a time in between each food patch. When obtaining food, the size of subgroups can change depending on how much food is available and how far away the food may be. If food is worth retrieving due to little travel costs, subgroup size will enlarge. So among chimpanzees, the abundance of food and how dense it may be are factors that contribute to the changes of subgroup sizes.

Orangutans

Orangutans are one type of primates that model individual-based fission-fusion. Travel parties are established among this species inhabiting specifically in a Sumatran forest, and there are several benefits. Mating opportunities are a large benefit of grouping, as parties are most substantial during high mating activity. Infant socialization also contains benefits as well as costs, due to their needs to be cared for. Females are required to carry their infants, and those with infants of mid-size experience greater costs than those of small sizes. Carrying a small infant does not require much, and they become less dependent as they begin to wean. Mid-sized infants on the other hand, require the most energy. When travelling, females are required to support their mid-sized infants by carrying them, and waiting for them if they’ve fallen behind.

Humans

Humans also form fission-fusion societies. In hunter-gatherer societies, humans form groups which are made up of several individuals that may split up to obtain different resources. Another example of a fission-fusion society in hunter-gatherer societies is communication among the group. Groups may begin to split due to arguments and disagreements. Among humans, gossip and language in general is also an important feature involved in fission-fusion. Communication keeps distant groups together although they may not be within close distances of each other.

Elephants

Forest elephants socializing at a clearing

Elephants display grouping as it helps to minimize risks and enhance benefits. Forest elephants often fuse into larger groups throughout forest clearings, to exchange information and maximize social opportunities. Elephants are drawn to large parties present at forest clearings, and remain in the clearing for a longer period of time if there are individuals outside of their party present. Young African male elephants display a preference for larger groups, in order to communicate with other elephants and to explore dominance. Adolescent males can gain knowledge from adult males and acquire information about their new social methods.

Bats

Bats are one of the orders of animals which shows an advanced fission-fusion society. Among female northern long-eared bats, switching roosts is common. There are several factors involved when switching roosts, which can include canopy cover and height, decay stage of the roost, and tree height. Geographic regions contribute to the switching of roosts, as females have been shown to switch when temperatures rise in Kentucky, and less when in a colder climate in Nova Scotia. There are also three important behaviours involved in roost-switching, which are fission-fusion grouping, synchronized movement, and settlement behaviour. Settlement behaviour is when bats remain in the most desirable roost possible, synchronized movement is when bats choose to move to another roost in a synchronized manner, and fission-fusion behaviour is when a bat colony separates into sub-colonies which then combine back together to form a large colony. A reason that bats can display fission-fusion behaviours is due to the risk of infection. Increased risk of disease can occur from settlement and synchronized behaviours, but fission-fusion societies are capable of reducing the risk of disease. Fission-fusion societies are capable of reducing the risk because of the frequent separation into subgroups.

Structure

These societies change frequently in their size and composition, making up a permanent social group called the “parent group”. Permanent social networks consist of all individual members of a faunal community and often varies to track changes in their environment and based on individual animal dynamics.

In a fission–fusion society, the main parent group can fracture (fission) into smaller stable subgroups or individuals to adapt to environmental or social circumstances. For example, a number of males may break off from the main group in order to hunt or forage for food during the day, but at night they may return to join (fusion) the primary group to share food and partake in other activities.

Overlapping of so-called “parent groups” territorially is also frequent, resulting in more interaction and mingling of community members, further altering the make-up of the parent group. This results in instances where, say, a female chimpanzee may generally belong to one parent group, but encounters a male who belongs to a neighboring community. If they copulate, the female may stay with the male for several days and come into contact with his parent group, temporarily “fusing” into the male’s community. In some cases, animals may leave one parent group to associate themselves with another, usually for reproductive reasons.

See also

  • Pair bonding
  • Human bonding

References

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