Biography:Nanako Shigesada

From HandWiki

Nanako Shigesada (重定南奈子, Shigesada Nanako) is a Professor Emeritus at Nara Women's University in Japan , most notable for her work in the fields of mathematical biology and theoretical ecology.[1] Her established career in academia has seen many of her journals published to acclaim, as well as contributing to the education of researchers at Kyoto University and Doshisha University. Shigesasda has served as the Research Supervisor for the Basic Research Program PRESTO in the research area "Innovative Models of Biological Processes and its Development", supported by the Japan Science and Technology Agency from 2007-2013.[2] She has also served as Secretary General and President for The Japanese Society for Mathematical Biology.[3] In 2013, she was awarded the Akira Okubo Prize.[4]

Career

In the 1970s Shigesasda was an active member of Mumay Tansky, a group composed of Shigesasda and colleagues Ei Teramoto, Hiroshi Ashida, Hisao Nakajima, Kohkichi Kawasaki, and Norio Yamamura.[5] The group, organised by Teramoto, published papers on structure, stability and efficiency of ecosystems.[6]

In 1979, Shigesada focused on the observational study of the spatial distribution of ant lions by ecologist Masaaki Morisita. She studied the concept of the structures of experience and consciousness (phenomenology) with regards to environmental density and the degree to which a habitat might be unfavourable. She introduced a model that combined population pressure, due to mutual interference between individuals, with environmental potential. Shigesasda extended Morisita's work, explaining how coexistence of competing species can arise through spatial segregation.[7]

In the last twenty years, Shigesada studied pine wilt disease which is caused by the pinewood roundworm with a pine sawyer beetle as vector. Through the study of population dynamics, she estimated beetle densities and parameter values, finding that there is a threshold host density above which the disease can spread, and that the minimum density critically depends on the eradication rate.[8]

Notable works

Title[9] Year
Biological invasions: theory and practice 1997
Spatial segregation of interacting species 1979
Modeling stratified diffusion in biological invasions 1995
Traveling Periodic Waves in Heterogeneous Environments 1986
Modeling the expansion of an introduced tree disease 2000
Invasion and the range expansion of species: effects of long-distance dispersal 2002
Modeling the spread of pine wilt disease caused by nematodes with pine sawyers as vector 1999

References