The Rapid Rise of Next-Generation Natural History

Tosa, Marie I.; Dziedzic, Emily; Appel, Cara L.; Urbina, Jenny; Massey, Aimee; Ruprecht, Joel; Eriksson, Charlotte E.; Dolliver, Jane; Lesmeister, Damon B.; Betts, Matthew G.; Peres, Carlos A.; Levi, Taal

doi:10.3389/fevo.2021.698131

Cited by 44 publications

(40 citation statements)

References 224 publications

(240 reference statements)

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“…This staggering diversity (with at least 80% of insect species remaining undescribed), combined with our poor knowledge of their distributions and ecology [2] and the spatiotemporal heterogeneity of their occurrence [3], form major challenges to the study of insects and their responses to environmental changes. Recent reports of long-term declines in insect biomass and abundances [4,5], in combination with the emergence of new technologies [6][7][8], have led to calls for [9], and the establishment of, new research projects for monitoring populations and assemblages of insects and other invertebrates [10,11].…”

Section: Technological Advancement For Insect Monitoringmentioning

confidence: 99%

“…Recent development of technologies that employ novel detection and identification methods, often in combination with citizen science, has opened up exciting new avenues for tracking insect populations and assemblages [6][7][8]14]. These technologieswhich include automated image and sound recognition, radar, and molecular methodshave the potential to radically…”

Section: Technological Advancement For Insect Monitoringmentioning

confidence: 99%

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Emerging technologies revolutionise insect ecology and monitoring

Klink

August

Bas

et al. 2022

Trends in Ecology & Evolution

144

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Section: Technological Advancement For Insect Monitoringmentioning

confidence: 99%

Section: Technological Advancement For Insect Monitoringmentioning

confidence: 99%

Emerging technologies revolutionise insect ecology and monitoring

Klink

August

Bas

et al. 2022

Trends in Ecology & Evolution

144

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“…Despite gigantic advances in molecular and bioinformatic tools (Tosa et al ., 2021; Anderson et al ., 2021), taxonomy remains a conservative science that still mostly relies on morphological methods and the basic grammar rules of the scientific Latin language used in the 18 th century. At the same time, it’s a domain of science home to vigorous and even heated debates, for example around the role of taxonomy and taxonomists within Academia (Drew, 2011; Zeppelini et al ., 2021) and around emerging new approaches to species descriptions [e.g., photography-based taxonomy (Ceríaco & et al, 2016; Zamani et al ., 2021); sequence-based taxonomy (Sharkey et al ., 2021; Zamani et al ., 2022)].…”

Section: Discussionmentioning

confidence: 99%

Taxonomic practice, creativity, and fashion: What’s in a spider name?

Mammola

Viel

Amiar

et al. 2022

Preprint

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There is a secret pleasure in naming new species. Besides traditional etymologies recalling the sampling locality, habitat, or morphology of the species, etymologies may be tributes to some meaningful person (for example, the species collector, the author husband or wife, or a celebrity), pop culture references, and even exercises of enigmatography. The possibility of choosing witty or even playful names for new species departs from the otherwise impersonal and old-fashioned writing style that is common in taxonomic papers; but, how has the descriptor choice for specific etymologies changed over the 300+ years since the introduction of the Linnaean binomial system of nomenclature? Using an unprecedented dataset of 48,464 etymologies (all valid species and subspecies of spiders described between 1757 and May 2020), we tested the hypothesis that species names given by taxonomists are deeply influenced by their cultural background. In particular, we asked whether naming practices change through space (continent in which the species was found) or have changed through time (year of description). We observed spatial and temporal differences in the way taxonomists name new species. In absolute terms, etymologies referring to morphology were the most frequently used. In relative terms, however, references to morphology peaked in 1850-1900 and then began to decline, with a parallel increase in etymologies dedicated to people and geography. Currently, these are the most widely used, with ca. 38% of all etymologies of spider species described in the last ten years referring to geography, ca. 25% to people, and ca. 25% to morphology. Interestingly, there has been a dramatic increase in etymologies referring to pop culture and other cultural aspects in the last two decades, especially in Europe and the Americas. While such fashionable names often carry little or no biological information regarding the species itself, they help give visibility to the science of taxonomy, a discipline currently facing a profound crisis within academia. Taxonomy is among the most unchanged disciplines across the last centuries in terms of background, tools, rules, and writing style; but our analysis suggests that taxonomists remain deeply influenced by their living time and space.

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“…Natural history is indeed entering its next-generation phase (Anderson et al, 2021;Jarić et al, 2020;Tosa et al, 2021), one characterized by increasingly available data (not only distribution data but also species traits and phylogenies) that can be routinely integrated in our modelling exercises. This is made possible by a parallel development of new methods, ranging from computationally fast multispecies modelling platforms (Pichler & Hartig, 2021) to flexible techniques able to account for traits (phenotypic plasticity) and genetic data in making predictions (Brewer et al, 2016;Bush et al, 2016;Garzón et al, 2019), along with tools to ease model interpretability (Ryo et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

Challenges and opportunities of species distribution modelling of terrestrial arthropod predators

Mammola

Pétillon

Hacala

et al. 2021

Diversity and Distributions

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AimSpecies distribution models (SDMs) have emerged as essential tools in the equipment of many ecologists, useful to explore species distributions in space and time and answering an assortment of questions related to biogeography, climate change biology and conservation biology. Historically, most SDM research concentrated on well‐known organisms, especially vertebrates. In recent years, these tools are becoming increasingly important for predicting the distribution of understudied invertebrate taxa. Here, we reviewed the literature published on main terrestrial arthropod predators (ants, ground beetles and spiders) to explore some of the challenges and opportunities of species distribution modelling in mega‐diverse arthropod groups.LocationGlobal.MethodsSystematic mapping of the literature and bibliometric analysis.ResultsMost SDM studies of animals to date have focused either on broad samples of vertebrates or on arthropod species that are charismatic (e.g. butterflies) or economically important (e.g. vectors of disease, crop pests and pollinators). We show that the use of SDMs to map the geography of terrestrial arthropod predators is a nascent phenomenon, with a near‐exponential growth in the number of studies over the past ten years and still limited collaborative networks among researchers. There is a bias in studies towards charismatic species and geographical areas that hold lower levels of diversity but greater availability of data, such as Europe and North America.ConclusionsArthropods pose particular modelling challenges that add to the ones already present for vertebrates, but they should also offer opportunities for future SDM research as data and new methods are made available. To overcome data limitations, we illustrate the potential of modern data sources and new modelling approaches. We discuss areas of research where SDMs may be combined with dispersal models and increasingly available phylogenetic and functional data to understand evolutionary changes in ranges and range‐limiting traits over past and contemporary time‐scales.

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The Rapid Rise of Next-Generation Natural History

Cited by 44 publications

References 224 publications

Emerging technologies revolutionise insect ecology and monitoring

Emerging technologies revolutionise insect ecology and monitoring

Taxonomic practice, creativity, and fashion: What’s in a spider name?

Challenges and opportunities of species distribution modelling of terrestrial arthropod predators

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