Your search keyword '"Olga Fareeva"' showing total 1 results

1. IoT monitoring of urban tree ecosystem services: Possibilities and challenges

Author

Ivan Seregin, Riccardo Valentini, Giovanna Sala, Victor Matasov, Alexey Yaroslavtsev, Olga Fareeva, Viacheslav Vasenev, Luca Belelli Marchesini, Simona Castaldi, Matasov, V., Marchesini, L. B., Yaroslavtsev, A., Sala, G., Fareeva, O., Seregin, I., Castaldi, S., Vasenev, V., Valentini, R., Matasov V., Marchesini L.B., Yaroslavtsev A., Sala G., Fareeva O., Seregin I., Castaldi S., Vasenev V., and Valentini R.

Subjects

Settore AGR/05 - ASSESTAMENTO FORESTALE E SELVICOLTURA, 010504 meteorology & atmospheric sciences, Atmospheric carbon cycle, 010501 environmental sciences, Real-time monitoring, 01 natural sciences, Ecosystem services, Operational system, Urban planning, Ecosystem services indicator, TreeTalker, Urban heat island, Settore AGR/06 - Tecnologia Del Legno E Utilizzazioni Forestali, 0105 earth and related environmental sciences, business.industry, Environmental resource management, Forestry, lcsh:QK900-989, Ecological engineering, Smart citie, Settore AGR/03 - Arboricoltura Generale E Coltivazioni Arboree, Sustainability, lcsh:Plant ecology, Environmental science, urban forest, Urban forests, Green infrastructure, business, Ecosystem services indicators, Smart cities

Abstract

Urban green infrastructure plays an increasingly significant role in sustainable urban development planning as it provides important regulating and cultural ecosystem services. Monitoring of such dynamic and complex systems requires technological solutions which provide easy data collection, processing, and utilization at affordable costs. To meet these challenges a pilot study was conducted using a network of wireless, low cost, and multiparameter monitoring devices, which operate using Internet of Things (IoT) technology, to provide real-time monitoring of regulatory ecosystem services in the form of meaningful indicators for both human health and environmental policies. The pilot study was set in a green area situated in the center of Moscow, which is exposed to the heat island effect as well as high levels of anthropogenic pressure. Sixteen IoT devices were installed on individual trees to monitor their ecophysiological parameters from 1 July to 31 November 2019 with a time resolution of 1.5 h. These parameters were used as input variables to quantify indicators of ecosystem services related to climate, air quality, and water regulation. Our results showed that the average tree in the study area during the investigated period reduced extreme heat by 2 &deg, C via shading, cooled the surrounding area by transferring 2167 &plusmn, 181 KWh of incoming solar energy into latent heat, transpired 137 &plusmn, 49 mm of water, sequestered 8.61 &plusmn, 1.25 kg of atmospheric carbon, and removed 5.3 &plusmn, 0.8 kg of particulate matter (PM10). The values of the monitored processes varied spatially and temporally when considering different tree species (up to five to ten times), local environmental conditions, and seasonal weather. Thus, it is important to use real-time monitoring data to deepen understandings of the processes of urban forests. There is a new opportunity of applying IoT technology not only to measure trees functionality through fluxes of water and carbon, but also to establish a smart urban green infrastructure operational system for management.

Published

2020