Abstract
AbstractSalps are marine pelagic tunicates with a complex life cycle including a solitary and colonial stage. Salp colonies are composed of asexually budded individuals that coordinate their swimming by multi-jet propulsion. Colonies develop into species-specific architectures with distinct zooid orientations. We hypothesize that colonial architecture drives differences in swimming performance between salps due to differences in how frontal drag scales with the number of propeller zooids in the colony. Moreover, we hypothesize that faster-swimming taxa are more energetically efficient in their locomotion since less energy would be devoted to overcoming drag forces. We (1) compare swimming speed across salp species and architectures, (2) evaluate how swimming speed scales with the number of zooids in the colony in architectures with constant and scaling frontal cross-sectional area, and (3) compare the metabolic cost of transport across different species and how it scales with swimming speed. To measure their swimming speeds, we recorded swimming salp colonies using in situ videography while SCUBA diving in the open ocean. To estimate the cost of transport, we measured the respiration rates of swimming and anesthetized salps collected in situ using jars equipped with non-invasive oxygen sensors. We found that linear colonies generally swim faster and with a lower cost of transport due to their differential advantage in frontal drag scaling with an increasing number of zooids. These findings underscore the importance of considering propeller arrangement to optimize speed and energy efficiency in bioinspired underwater vehicle design, leveraging lessons learned from the diverse natural laboratory provided by salp diversity.Summary StatementLinear arrangements in multi-jet propelled marine colonial invertebrates are faster and more energetically efficient than less streamlined architectures, offering insights for bioinspired underwater vehicle design.
Publisher
Cold Spring Harbor Laboratory