Your search keyword '"Haibin Hang"' showing total 2 results

1. Geometric and topological approaches to shape variation in Ginkgo leaves

Author

Haibin Hang, Martin Bauer, Washington Mio, and Luke Mander

Subjects

biological shape, plant traits, morphometric methods, elastic curves, persistent homology, Science

Abstract

Leaf shape is a key plant trait that varies enormously. The range of applications for data on this trait requires frequent methodological development so that researchers have an up-to-date toolkit with which to quantify leaf shape. We generated a dataset of 468 leaves produced by Ginkgo biloba, and 24 fossil leaves produced by evolutionary relatives of extant Ginkgo. We quantified the shape of each leaf by developing a geometric method based on elastic curves and a topological method based on persistent homology. Our geometric method indicates that shape variation in modern leaves is dominated by leaf size, furrow depth and the angle of the two lobes at the leaf base that is also related to leaf width. Our topological method indicates that shape variation in modern leaves is dominated by leaf size and furrow depth. We have applied both methods to modern and fossil material: the methods are complementary, identifying similar primary patterns of variation, but also revealing different aspects of morphological variation. Our topological approach distinguishes long-shoot leaves from short-shoot leaves, both methods indicate that leaf shape influences or is at least related to leaf area, and both could be applied in palaeoclimatic and evolutionary studies of leaf shape.

Published

2021

2. Geometric and topological approaches to shape variation in Ginkgo leaves

Author

Martin Bauer, Washington Mio, Haibin Hang, and Luke Mander

Subjects

Leaf base, Multidisciplinary, Persistent homology, biology, Range (biology), Science, Ginkgo, morphometric methods, Topology, biology.organism_classification, Geometric method, persistent homology, Variation (linguistics), Leaf width, Extant taxon, plant traits, Organismal and Evolutionary Biology, elastic curves, Leaf size, biological shape, Plant traits, Research Articles, Mathematics

Abstract

Leaf shape is a key plant trait that varies enormously. The range of applications for data on this trait requires frequent methodological development so that researchers have an up-to-date toolkit with which to quantify leaf shape. We generated a dataset of 468 leaves produced by Ginkgo biloba , and 24 fossil leaves produced by evolutionary relatives of extant Ginkgo . We quantified the shape of each leaf by developing a geometric method based on elastic curves and a topological method based on persistent homology. Our geometric method indicates that shape variation in modern leaves is dominated by leaf size, furrow depth and the angle of the two lobes at the leaf base that is also related to leaf width. Our topological method indicates that shape variation in modern leaves is dominated by leaf size and furrow depth. We have applied both methods to modern and fossil material: the methods are complementary, identifying similar primary patterns of variation, but also revealing different aspects of morphological variation. Our topological approach distinguishes long-shoot leaves from short-shoot leaves, both methods indicate that leaf shape influences or is at least related to leaf area, and both could be applied in palaeoclimatic and evolutionary studies of leaf shape.

Published

2021