Your search keyword '"Nicese, F."' showing total 11 results

1. Estimating CO2 balance through the Life Cycle Assessment prism: A case – Study in an urban park

Author

Nicese, F, Colangelo, G, Comolli, R, Azzini, L, Lucchetti, S, Marziliano, P, Sanesi, G, Nicese F. P., Colangelo G., Comolli R., Azzini L., Lucchetti S., Marziliano P. A., Sanesi G., Nicese, F, Colangelo, G, Comolli, R, Azzini, L, Lucchetti, S, Marziliano, P, Sanesi, G, Nicese F. P., Colangelo G., Comolli R., Azzini L., Lucchetti S., Marziliano P. A., and Sanesi G.

Abstract

In a context of progressive urbanization, urban parks can play a pivotal role in carbon sequestration and stock. The study employs Life Cycle Assessment (LCA) to evaluate CO2e (carbon dioxide equivalent) emissions and removal by plants and soil in different urban green typologies, namely afforested areas, tree rows, social allotments, lawns, hedges, referring to a life span of 50 years. The present study aims to evaluate the carbon balance connected with planning, planting, and maintaining an urban park, the Parco Nord Milano (PNM), a green area located in the metropolitan area of Milan, Italy. The different emission data took into consideration planting and maintenance interventions, including the effects of equipment and vehicle choices, main operational activities, and the fate of vegetal residue from pruning, shrub and tree removal, and lawn mowing. The best performances in terms of CO2e balance per surface unit was obtained with tree rows and afforested area typologies (- 789 and – 527 Mg CO2e ha−1 50yrs-1, respectively), while the hedges showed the worst CO2e balance, (+ 176 Mg CO2e ha−1 50yrs-1). Different planting options, different pruning or thinning intensities or species selection can change this balance. In addition, converting residues from removed trees into wood products can improve the storage of CO2 for long periods. LCA has proved to be an effective tool to support the planning and maintenance of urban parks and the types considered. However, rational planning must also have to take into account user preferences and needs, and which ecosystem services can be maximized to ensure a better quality of life.

Published

2021

2. Molecular characterization and genetic relatedness among walnut (Juglans regia L.) genotypes based on RAPD markers

Author

Nicese, F. P., Hormaza, J. I., and Mcgranahan, G. H.

Published

1998

3. Ricerche sulla micropropagazione della rosa

Author

BINI, G., LEVA, A. R. C., and NICESE, F. P.

Published

1983

4. Effect of Fertilization and Backfill Amendments on Soil Characteristics, Growth, and Leaf Gas Exchange of English Oak (Quercus Robur L.)

Author

Ferrini, F., Giuntoli, A., Nicese, F. P., Pellegrini, S., and nadia vignozzi

Subjects

Ecology, fungi, food and beverages, Forestry, complex mixtures

Abstract

The influence of fertilization and soil amendments on plant growth and leaf gas exchange was monitored on English oak trees (Quercus robur L.) over a 3-year period after planting. The results indicate that shoot growth, leaf area, chlorophyll content, and leaf gas exchange were higher in fertilized plants, especially during the second and third years after planting. However, compost and leonardite were rarely better than the control. Soil physical characteristics were positively influenced by soil amendments, which promoted a better structure and lowered penetration resistance compared to control and fertilization.

Published

2005

5. Reuse of industrial wastewater for the irrigation of ornamental plants

Author

Gori, R., primary, Lubello, C., primary, Ferrini, F., primary, Nicese, F. P., primary, and Coppini, E., primary

Published

2008

6. Reclaimed municipal wastewater as source of water and nutrients for plant nurseries

Author

Gori, R., primary, Lubello, C., primary, Ferrini, F., primary, and Nicese, F., primary

Published

2004

7. Analysis of greenhouse gas emissions from ornamental plant production: A nursery level approach.

Author

Lazzerini, G., Lucchetti, S., and Nicese, F. P.

Subjects

GREENHOUSE gases, ORNAMENTAL plants, PLANT productivity, PLANT nurseries, ARABLE land, GLOBAL warming

Abstract

The focus of the work is to define a methodology to evaluate greenhouse gas (GHG) emissions for the nursery industry, comparing two different plant production systems (field- and container-grown plants) and assessing different scenarios for the reduction of the emissions. The Life Cycle Assessment (LCA) methodology, with the "from cradle to gate" approach, was used. The analysis revealed that the total emission of CO2eq is higher in container cultivations than in field cultivations, with emissions ranging between 26.1 and 34.7 Mg ha-1 year-1 for the former, and between 2.3 and 6.6 Mg ha-1 year-1 for the latter; greenhouse horticultural crops emit 2.2-10.3 Mg ha-1 year-1 of CO2eq and arable crop emissions were measured as 6.2 Mg ha-1 year-1 of CO2eq. Different scenarios for the reduction of GHG emission were tested and a 15.5% reduction of GHG emission was achieved. Two of the scenarios applied - 50% recycled water usage (scenario 1) and 10% of green waste recovery for substrates (scenario 3) - are already in use in nursery farms. [ABSTRACT FROM AUTHOR]

Published

2014

8. Chestnut (Castanea sativaMill.) genotype identification: An artificial neural network approach

Author

Mancuso, S., primary, Ferrini, F., additional, and Nicese, F. P., additional

Published

1999

9. Effect of Temperature on Key Physiological Responses of Grapevine Leaf

Author

Ferrini, F., primary, Mattii, G. B., additional, and Nicese, F. P., additional

Published

1995

10. Reclaimed municipal wastewater as source of water and nutrients for plant nurseries

Author

Riccardo Gori, Lubello, C., Ferrini, F., and Nicese, F.

11. Estimating CO2 balance through the Life Cycle Assessment prism: A case – Study in an urban park

Author

L. Azzini, Roberto Comolli, F.P. Nicese, Stefano Lucchetti, Giuseppe Colangelo, Pasquale A. Marziliano, Giovanni Sanesi, Nicese, F, Colangelo, G, Comolli, R, Azzini, L, Lucchetti, S, Marziliano, P, and Sanesi, G

Subjects

0106 biological sciences, Ecology, ved/biology, Ecosystem service, LCA, Sink, ved/biology.organism_classification_rank.species, Soil Science, Carbon dioxide equivalent, Lawn, Forestry, 010501 environmental sciences, Carbon sequestration, 010603 evolutionary biology, 01 natural sciences, Shrub, Metropolitan area, Carbon, Ecosystem services, Soil, Environmental protection, Urbanization, Environmental science, Life-cycle assessment, 0105 earth and related environmental sciences

Abstract

In a context of progressive urbanization, urban parks can play a pivotal role in carbon sequestration and stock. The study employs Life Cycle Assessment (LCA) to evaluate CO2e (carbon dioxide equivalent) emissions and removal by plants and soil in different urban green typologies, namely afforested areas, tree rows, social allotments, lawns, hedges, referring to a life span of 50 years. The present study aims to evaluate the carbon balance connected with planning, planting, and maintaining an urban park, the Parco Nord Milano (PNM), a green area located in the metropolitan area of Milan, Italy. The different emission data took into consideration planting and maintenance interventions, including the effects of equipment and vehicle choices, main operational activities, and the fate of vegetal residue from pruning, shrub and tree removal, and lawn mowing. The best performances in terms of CO2e balance per surface unit was obtained with tree rows and afforested area typologies (- 789 and – 527 Mg CO2e ha−1 50yrs-1, respectively), while the hedges showed the worst CO2e balance, (+ 176 Mg CO2e ha−1 50yrs-1). Different planting options, different pruning or thinning intensities or species selection can change this balance. In addition, converting residues from removed trees into wood products can improve the storage of CO2 for long periods. LCA has proved to be an effective tool to support the planning and maintenance of urban parks and the types considered. However, rational planning must also have to take into account user preferences and needs, and which ecosystem services can be maximized to ensure a better quality of life.

Published

2021