Your search keyword '"Santiago, Jose-Luis"' showing total 13 results

1. Local Climate Zones (LCZs) and Urban Morphological Parameters Using GIS: An Application to Italian Cities

Author

Buccolieri, Riccardo, primary, Esposito, Antonio, additional, Pappaccogli, Gianluca, additional, Grulois, Myrtille, additional, Donateo, Antonio, additional, Santiago, Jose Luis, additional, Martilli, Alberto, additional, Maffeis, Giuseppe, additional, and Salizzoni, Pietro, additional

Published

2022

2. On the Calculation of Urban Morphological Parameters Using GIS: An Application to Italian Cities.

Author

Esposito, Antonio, Grulois, Myrtille, Pappaccogli, Gianluca, Palusci, Olga, Donateo, Antonio, Salizzoni, Pietro, Santiago, Jose Luis, Martilli, Alberto, Maffeis, Giuseppe, and Buccolieri, Riccardo

Subjects

GEOGRAPHIC information systems, CLIMATE change models, URBAN heat islands, LAND cover, URBAN morphology

Abstract

The identification of parameters that can quantitatively describe the different characteristics of urban morphology is fundamental to studying urban ventilation and microclimate at the local level and developing parameterizations of the dynamic effect of an urban area in mesoscale models. This paper proposes a methodology to calculate four morphological parameters, namely mean height, aspect ratio, sky view factor, and plan area ratio, of five cities located in southern (Bari and Lecce), central (Naples and Rome), and northern (Milan) Italy. The calculation is performed using the Geographical Information System (GIS), starting from morphological and land use data collected and analyzed in shapefiles. The proposed methodology, which can be replicated in other cities, also presents in detail the procedure followed to properly build input data to calculate the sky view factor using the UMEP GIS tool. The results show a gradual increase in the plan area index, λp, and mean building height, H ¯ , moving from the south to the north of Italy. Maximum values of λp and H ¯ are obtained in the regions of Milan, Rome, and Naples, where the highest spatially-averaged values are also found, i.e., λp = 0.22, H ¯ = 10.9 m in Milan; λp = 0.19, H ¯ = 12.7 m in Rome; λp = 0.20, H ¯ = 12 m in Naples. Furthermore, for all the cities investigated, areas characterized by the Corine Land Cover class as "continuous urban fabric" are those with medium sky view factor SVF values (around 0.6–0.7) and λp values (around 0.3) typical of intermediate/compact cities. The methodology employed here for calculating morphological parameters using GIS proves to be replicable in different urban contexts. This opens to a better classification of cities in local climate zones (LCZ), as shown for the Lecce region, useful for urban heat island (UHI) studies and to the development of parameterizations of the urban effects in global and regional climate models. [ABSTRACT FROM AUTHOR]

Published

2023

3. Advances on the Influence of Vegetation and Forest on Urban Air Quality and Thermal Comfort—Series II.

Author

Rivas, Esther, Santiago, Jose-Luis, and Sánchez, Beatriz

Subjects

AIR quality, THERMAL comfort, FOREST plants, URBAN plants, GREEN infrastructure, ATMOSPHERIC deposition

Published

2023

4. Impact of Different Combinations of Green Infrastructure Elements on Traffic-Related Pollutant Concentrations in Urban Areas.

Author

Santiago, Jose-Luis, Rivas, Esther, Sanchez, Beatriz, Buccolieri, Riccardo, Esposito, Antonio, Martilli, Alberto, Vivanco, Marta G., and Martin, Fernando

Subjects

GREEN infrastructure, COMPUTATIONAL fluid dynamics, VERTICAL gardening, GREEN roofs, POLLUTANTS, AIR quality

Abstract

Urban air quality is a major problem for human health and green infrastructure (GI) is one of the potential mitigation measures used. However, the optimum GI design is still unclear. The purpose of this study is to provide some recommendation that could help in the design of the GI (mainly, the selection of locations and characteristics of trees and hedgerows). Aerodynamic and deposition effects of each vegetation element of different GI scenarios are investigated. Computational fluid dynamics (CFD) simulations of a wide set of GI scenarios in an idealized three-dimensional urban environment are performed. In conclusion, it was found that trees in the middle of the avenue (median strip) reduce street ventilation, and traffic-related pollutant concentrations increase, in particular for streets parallel to the wind. Trees in the sidewalks act as a barrier for pollutants emitted outside, specifically for a 45° wind direction. Regarding hedgerows, the most important effect on air quality is deposition and the effects of green walls and green roofs are limited to their proximity to the building surfaces. [ABSTRACT FROM AUTHOR]

Published

2022

5. Urban Obstacles Influence on Street Canyon Ventilation: A Brief Review

Author

Buccolieri, Riccardo, primary, Carlo, Oliver Savio, additional, Rivas, Esther, additional, and Santiago, Jose Luis, additional

Published

2021

6. The Impact of Planting Trees on NOx Concentrations: The Case of the Plaza de la Cruz Neighborhood in Pamplona (Spain).

Author

Santiago, Jose-Luis, Rivas, Esther, Sanchez, Beatriz, Buccolieri, Riccardo, and Martin, Fernando

Subjects

*PLANTING, *ATMOSPHERIC nitrogen, *AIR pollutants, *COMPUTATIONAL fluid dynamics

Abstract

In this paper, the role of trees on airborne pollutant dispersion in a real neighborhood in Pamplona (Spain) is discussed. A Computational Fluid Dynamics (CFD) model is employed and evaluated against concentrations measured during the last part of winter season at a monitoring station located in the study area. Aerodynamic and deposition effects of trees are jointly considered, which has only been done in few recent studies. Specifically, the impact on NOx concentration of: (a) tree-foliage; and (b) introducing new vegetation in a tree-free street is analyzed considering several deposition velocities and Leaf Area Densities (LAD) to model deciduous and evergreen vegetation. Results show that the higher the LAD, the higher the deposition (concentration reduction) and the blocking aerodynamic effect (concentration increase). Regardless of foliage or deposition rates, results suggest the predominance of aerodynamic effects which induce concentration increases up to a maximum of 7.2%, while deposition induces concentration decreases up to a maximum of 6.9%. The inclusion of new trees in one street modifies the distribution of pollutant, not only in that street, but also in nearby locations with concentration increase or decrease. This finding suggests that planting trees in street with traffic as an air pollution reduction strategy seems to be not appropriate in general, highlighting the necessity of ad hoc studies for each particular case to select the suitable location of new vegetation. [ABSTRACT FROM AUTHOR]

Published

2017

7. High Spatial Resolution Assessment of the Effect of the Spanish National Air Pollution Control Programme on Street-Level NO 2 Concentrations in Three Neighborhoods of Madrid (Spain) Using Mesoscale and CFD Modelling.

Author

Santiago, Jose-Luis, Sanchez, Beatriz, Rivas, Esther, Vivanco, Marta G., Theobald, Mark Richard, Garrido, Juan Luis, Gil, Victoria, Martilli, Alberto, Rodríguez-Sánchez, Alejandro, Buccolieri, Riccardo, and Martín, Fernando

Subjects

*AIR pollution control, *SPATIAL resolution, *NEIGHBORHOODS, *AIR pollution, *AIR quality, *AIR pollutants, *BUILT environment

Abstract

Current European legislation aims to reduce the air pollutants emitted by European countries in the coming years. In this context, this article studies the effects on air quality of the measures considered for 2030 in the Spanish National Air Pollution Control Programme (NAPCP). Three different emission scenarios are investigated: a scenario with the emissions in 2016 and two other scenarios, one with existing measures in the current legislation (WEM2030) and another one considering the additional measures of NAPCP (WAM2030). Previous studies have addressed this issue at a national level, but this study assesses the impact at the street scale in three neighborhoods in Madrid, Spain. NO2 concentrations are modelled at high spatial resolution by means of a methodology based on computational fluid dynamic (CFD) simulations driven by mesoscale meteorological and air quality modelling. Spatial averages of annual mean NO2 concentrations are only estimated to be below 40 µg/m3 in all three neighborhoods for the WAM2030 emission scenarios. However, for two of the three neighborhoods, there are still zones (4–12% of the study areas) where the annual concentration is higher than 40 µg/m3. This highlights the importance of considering microscale simulations to assess the impacts of emission reduction measures on urban air quality. [ABSTRACT FROM AUTHOR]

Published

2022

8. Advances on the Influence of Vegetation and Forest on Urban Air Quality and Thermal Comfort.

Author

Santiago, Jose-Luis and Rivas, Esther

Subjects

AIR quality, THERMAL comfort, URBAN plants, FOREST plants, GREEN infrastructure, ENVIRONMENTAL quality

Abstract

The interactions between the atmosphere and urban obstacles such as buildings or vegetation induce complex flow patterns because of the heterogeneities of urban morphology. However, street trees can reduce street ventilation and increase pollutant concentration at the pedestrian level [[9], [11]]. Street ventilation is reduced and this fact, linked with the large pollutant emissions from vehicles, gives rise to high pollutant concentrations (NO SB 2 sb , PM SB 10 sb , PM SB 2.5 sb , etc.) and strong gradients of concentration within streets. [Extracted from the article]

Published

2021

9. Analysis of Urban Greening Scenarios for Improving Outdoor Thermal Comfort in Neighbourhoods of Lecce (Southern Italy).

Author

Gatto, Elisa, Ippolito, Fabio, Rispoli, Gennaro, Carlo, Oliver Savio, Santiago, Jose Luis, Aarrevaara, Eeva, Emmanuel, Rohinton, and Buccolieri, Riccardo

Subjects

THERMAL comfort, NEIGHBORHOODS, ATMOSPHERIC temperature, BUILDING layout, URBAN planning, URBAN ecology (Sociology), GEOTHERMAL ecology, BUILT environment

Abstract

This study analyses the interactions and impacts between multiple factors i.e., urban greening, building layout, and meteorological conditions that characterise the urban microclimate and thermal comfort in the urban environment. The focus was on two neighbourhoods of Lecce city (southern Italy) characterised through field campaigns and modelling simulations on a typical hot summer day. Field campaigns were performed to collect greening, building geometry, and microclimate data, which were employed in numerical simulations of several greening scenarios using the Computational Fluid Dynamics-based and microclimate model ENVI-met. Results show that, on a typical summer day, trees may lead to an average daily decrease of air temperature by up to 1.00 °C and an improvement of thermal comfort in terms of Mean Radiant Temperature (MRT) by up to 5.53 °C and Predicted Mean Vote (PMV) by up to 0.53. This decrease is more evident when the urban greening (in terms of green surfaces and trees) is increased by 1266 m2 in the first neighbourhood and 1988 m2 in the second one, with respect to the current scenario, proving that shading effect mainly contributes to improving the urban microclimate during daytime. On the contrary, the trapping effect of heat, stored by the surfaces during the day and released during the evening, induces an increase of the spatially averaged MRT by up to 2 °C during the evenings and a slight deterioration of thermal comfort, but only locally where the concentration of high LAD trees is higher. This study contributes to a better understanding of the ecosystem services provided by greening with regard to microclimate and thermal comfort within an urban environment for several hours of the day. It adds knowledge about the role of green areas in a Mediterranean city, an important hot spot of climate change, and thus it can be a guide for important urban regeneration plans. [ABSTRACT FROM AUTHOR]

Published

2021

10. The Challenge in the Management of Historic Trees in Urban Environments during Climate Change: The Case of Corso Trieste (Rome, Italy).

Author

Gatto, Elisa, Buccolieri, Riccardo, Perronace, Leonardo, and Santiago, Jose Luis

Subjects

URBAN trees, CLIMATE change, URBAN ecology (Sociology), SCIENTIFIC literature, THERMAL comfort, TREE planting

Abstract

This study carries out a quantitative analysis of the impact on microclimate (air temperature and thermal comfort) of a row of 165 historical Pinus pinea L. located in a central neighbourhood of Rome (Italy). The analysis starts from a qualitative general analysis on the stressful conditions leading to tree decline in the urban environment especially during extreme climate change phenomena. Subsequently, the effects of planting new types of trees are assessed using ENVI-met, a 3D prognostic non-hydrostatic model for the simulation of surface-plant-air interactions. Results, obtained by simulating three different scenarios in which the trees are first removed and then modified, show that a gradual renewal of the existing trees, based on priority criteria of maturity or senescence, vegetative and phytosanitary conditions, efficiency of ecosystem services and safety for citizens, has positive effects on thermal comfort. By integrating current results and scientific literature, the final aim of this work is to provide stakeholders with a strategic and systemic planning methodology, which, based on the innovative integrated use of tree management and modelling tools, may (i) enhance the benefits of greening in a scenario of climate change and (ii) lead to intervention strategies based on complementarity between conservation of existing trees and tree renewal. [ABSTRACT FROM AUTHOR]

Published

2021

11. Characterization of Urban Greening in a District of Lecce (Southern Italy) for the Analysis of CO2 Storage and Air Pollutant Dispersion.

Author

Buccolieri, Riccardo, Gatto, Elisa, Manisco, Michela, Ippolito, Fabio, Santiago, Jose Luis, and Gao, Zhi

Subjects

ATMOSPHERIC carbon dioxide, AIR pollutants, COMPUTATIONAL fluid dynamics, AIR quality, GROUND cover plants, DISPERSION (Chemistry), GROUND vegetation cover

Abstract

This paper is devoted to the assessment of urban greening effects on two important ecosystem services, i.e., air quality and CO2 storage, including the corresponding economic impacts in a real urban area, i.e., a district located in the Mediterranean city of Lecce (southern Italy). Two tools were employed, i-Tree Canopy and the computational fluid dynamics (CFD) microclimate model ENVI-met. i-Tree Canopy allowed fully determining the land-cover percentage on the basis of different ground cover classes and obtaining an estimate of annual values of CO2 storage, air pollutant removal, and economic benefits in the presence of urban greening. The estimate in i-Tree Canopy considered only the amount of greening; therefore, air pollutant removal estimates were only potential. As the vegetation was located in street canyons, its interaction with local meteorology and urban geometry strictly affected the dispersion of nitrogen oxides (NOx) (taken here as an example) as obtained from ENVI-met simulations. In ENVI-met, both deposition/absorption and aerodynamic effects were considered, and local increases in concentration were found in the district. The analysis of results obtained from different tools (one complex (CFD model) and the other simple (i-Tree model)) showed the error associated with the simple model in the computation of impacts if the interaction among the vegetation characteristics, the meteorological conditions, and the urban geometry was neglected; however, it also uncovers a novel approach for comprehensively characterizing a given area in terms of its vegetation cover, CO2 storage, and economic benefits, as well as local effects on air quality. This study is set in a broader context aimed at assessing the air quality in urban canopies of Mediterranean areas characterized by the presence of narrow street canyons where pollutants can accumulate due to ineffective air exchange with the above atmosphere. [ABSTRACT FROM AUTHOR]

Published

2020

12. Impact of Urban Vegetation on Outdoor Thermal Comfort: Comparison between a Mediterranean City (Lecce, Italy) and a Northern European City (Lahti, Finland).

Author

Gatto, Elisa, Buccolieri, Riccardo, Aarrevaara, Eeva, Ippolito, Fabio, Emmanuel, Rohinton, Perronace, Leonardo, and Santiago, Jose Luis

Subjects

URBAN plants, THERMAL comfort, GREEN infrastructure, URBAN planners, CLIMATE change, URBAN ecology (Sociology)

Abstract

This paper is devoted to the application of the modelling approach, as one of the methods for the evaluation of thermal comfort, to neighborhoods located in two cities characterized by a different climate, i.e., a Mediterranean city in southern Italy (Lecce) and a northern European city in southern Finland (Lahti). The impact of the presence of vegetation in both places is evaluated and compared, further considering alternative scenarios for thermal comfort improvement. The thermal comfort condition is expressed in terms of indices (mean radiant temperature (MRT) and predicted mean vote (PMV)). Results show that at pedestrian level the presence of vegetation lead to an improvement of thermal comfort in summer of about 2 points in both neighborhoods. This improvement is also evident observing the spatial distribution of MRT with a difference of 7 °C in the Lecce neighborhood and 3 °C in Lahti. In winter, thermal discomfort is observed in the presence of vegetation with a difference of 1.3 °C in the Lecce neighborhood and 1.5 °C in Lahti in terms of MRT. However, trees and green cover have the important potential to offset climate change impact and to make urban environments less thermally stressful. This study aims to guide urban planners towards a motivated and necessary transaction towards new green infrastructure whose effect should, however, be analyzed and investigated case by case. [ABSTRACT FROM AUTHOR]

Published

2020

13. On the Impact of Trees on Ventilation in a Real Street in Pamplona, Spain.

Author

Santiago, Jose-Luis, Buccolieri, Riccardo, Rivas, Esther, Sanchez, Beatriz, Martilli, Alberto, Gatto, Elisa, and Martín, Fernando

Subjects

*URBAN trees, *WIND speed, *KINETIC energy, *URBAN plants, *LEAF area, *MINE ventilation, *STREETS, *FOREST declines

Abstract

This paper is devoted to the quantification of changes in ventilation of a real neighborhood located in Pamplona, Spain, due to the presence of street trees Pollutant dispersion in this urban zone was previously studied by means of computational fluid dynamic (CFD) simulations. In the present work, that research is extended to analyze the ventilation in the whole neighborhood and in a tree-free street. Several scenarios are investigated including new trees in the tree-free street, and different leaf area density (LAD) in the whole neighborhood. Changes between the scenarios are evaluated through changes in average concentration, wind speed, flow rates and total pollutant fluxes. Additionally, wind flow patterns and the vertical profiles of flow properties (e.g., wind velocity, turbulent kinetic energy) and concentration, horizontally-averaged over one particular street, are analyzed. The approach-flow direction is almost perpendicular to the street under study (prevailing wind direction is only deviated 4º from the perpendicular direction). For these conditions, as LAD increases, average concentration in the whole neighborhood increases due to the decrease of wind speed. On the other hand, the inclusion of trees in the street produces an increase of averaged pollutant concentration only within this street, in particular for the scenario with the highest LAD value. In fact, the new trees in the street analyzed with the highest LAD value notably change the ventilation producing an increase of total pollutant fluxes inward the street. Additionally, pollutant dispersion within the street is also influenced by the reduction of the wind velocity along the street axis and the decrease of turbulent kinetic energy within the vegetation canopy caused by the new trees. Therefore, the inclusion of new trees in a tree-free street should be done by considering ventilation changes and traffic emissions should be consequently controlled in order to keep pollutant concentration within healthy levels. [ABSTRACT FROM AUTHOR]

Published

2019