Spatial and temporal variation in settlement, growth and condition of the rockfish species Sebastes caurinus and Sebastes carnatus in the Channel Islands region, Santa Barbara, CA

Survival during the early life stages of marine species, including nearshore temperate reef fishes, is typically very low, and small changes in mortality rates, due to physiological and environmental conditions, can have marked effects on survival of a cohort and, on a larger scale, on the success of a recruitment season. Moreover, trade offs between larval growth and accumulation of energetic resources prior to settlement are likely to influence growth and survival until this critical period and afterwards. Rockfish recruitment rates are notoriously variable between years and across geographic locations. Monitoring of rates of onshore delivery of pelagic juveniles (defined here as settlement) of two species of nearshore rockfishes, Sebastes caurinus and Sebastes carnatus, was done between 2003-2009 years using artificial collectors placed at San Miguel and Santa Cruz Island, off Southern California coast. I investigated spatiotemporal variation in settlement rate, lipid content, pelagic larval duration and larval growth of the newly settled fishes; I assessed relationships between birth date, larval growth, early life-history characteristics and lipid content at settlement, considering also interspecific differences; finally, I attempt to relate interannual patterns of settlement and of early life history traits to easily accessible, local and regional indices of ocean conditions including in situ ocean temperature and regional upwelling, sea surface temperature (SST) and Chlorophyll-a (Chl-a) concentration. Spatial variations appeared to be of low relevance, while significant interannual differences were detected in settlement rate, pelagic larval duration and larval growth. The amount of lipid content of the newly settled fishes was highly variable in space and time, but did not differ between the two species and did not show any relationships with early life history traits, indicating that no trade off involved these physiological processes or they were masked by high individual variability in different periods of larval life. Significant interspecific differences were found in the timing of parturition and settlement and in larval growth rates, with S. carnatus growing faster and breeding and settling later than S. caurinus. The two species exhibited also different patterns of correlations between larval growth rates and larval duration. S. carnatus larval duration was longer when the growth in the first two weeks post-hatch was faster, while S. caurinus had a shorter larval duration when grew fast in the middle and in the end of larval life, suggesting different larval strategies. Fishes with longer larval durations were longer in size at settlement and exhibited longer planktonic phase in periods of favourable environmental conditions. Ocean conditions had a low explanatory power for interannual variation in early life history traits, but a very high explanatory power for settlement fluctuations, with regional upwelling strength being the principal indicator. Nonetheless, interannual variability in larval duration and growth were related to great phenological changes in upwelling happened during the period of this study and that caused negative consequences at all trophic levels along the California coast. Despite the low explanatory power of the environmental variables used in this study on the variation of larval biological traits, environmental processes were differently related with early life history characteristics analyzed to species, indicating possible species-specific susceptibility to ocean conditions and local environmental adaptation, which should be further investigated. These results have implications for understanding the processes influencing larval and juvenile survival, and consequently recruitment variability, which may be dependent on biological characteristics and environmental conditions.

Monitoraggio di rilasci accidentali di sostanze pericolose in un impianto chimico

Il monitoraggio dei rilasci può essere indoor o outdoor; l’attenzione del presente lavoro è rivolta a sistemi di monitoraggio di gas infiammabili e/o tossici in ambienti esterni di stabilimenti onshore. L’efficacia dei sistemi di Gas Detection è profondamente influenzata dalla disposizione dei sensori nelle aree di rischio. Esistono codici e standard che forniscono informazioni molto dettagliate per la progettazione dei sistemi di Fire Detection e linee guida per la scelta, l’installazione ed il posizionamento ottimale dei sensori di incendio. La stessa affermazione non si può fare per i sistemi di Gas Detection, nonostante dall’individuazione tempestiva di un rilascio dipendano anche le successive azioni antincendio. I primi tentativi di sviluppare linee guida per il posizionamento dei sensori di gas sono stati effettuati per le applicazioni off-shore, dove l’elevato livello di congestione e il valore delle apparecchiature utilizzate richiedono un efficiente sistema di monitoraggio dei rilasci. Per quanto riguarda gli impianti on-shore, i criteri di posizionamento dei rilevatori di gas non sono ufficialmente ed univocamente definiti: il layout dei gas detectors viene in genere stabilito seguendo criteri di sicurezza interni alle compagnie affiancati da norme di “buona tecnica” e regole empiriche. Infatti, nonostante sia impossibile garantire l’individuazione di ogni rilascio, vi sono linee guida che propongono strategie di posizionamento dei gas detectors in grado di massimizzare la probabilità di successo del sistema di monitoraggio. Il presente lavoro è finalizzato alla verifica del corretto posizionamento dei gas detectors installati presso l’impianto pilota SF2 dello stabilimento Basell Poliolefine Italia di Ferrara.

Influenza dei parametri idrogeologici nei processi di contaminazione del sottosuolo imputabili a rilasci accidentali di idrocarburi

Il presente lavoro di tesi si propone di esaminare i processi di contaminazione del suolo e delle acque sotterranee conseguenti ad un fenomeno di “oil spill”: con tale termine si vuole intendere un fenomeno di rilascio accidentale di sostanze chimiche, come il benzene, dovuto al danneggiamento di lunghe condotte onshore realizzate per trasferire, tali sostanze, anche per distanze di centinaia di chilometri. Sebbene le basse frequenze incidentali confermino che il trasporto in condotta rappresenta la modalità di movimentazione via terra più sicura per fluidi chimici, bisogna tuttavia tener presente che i quantitativi di sostanze che possono essere rilasciate da questi impianti sono molto elevati.In questo lavoro, si è partiti con l’esaminare un caso studio riportato in letteratura, relativo alla valutazione quantitativa del rischio ambientale legato a fenomeni di oil spill da condotte onshore [Bonvicini et al., 2014]. Si è considerato, in particolare, un singolo tratto di una lunga condotta industriale, in corrispondenza del quale si è ipotizzato il verificarsi di una rottura, con conseguente rilascio di contaminante nel sottosuolo. L’impianto in questione è finalizzato al trasporto di benzene (LNAPL), idrocarburo aromatico cancerogeno, fortemente pericoloso per l’ambiente e per l’uomo.

Feasibility study and flow scheduling optimization of a multi-product pipeline system

The first goal of this study is to analyse a real-world multiproduct onshore pipeline system in order to verify its hydraulic configuration and operational feasibility by constructing a simulation model step by step from its elementary building blocks that permits to copy the operation of the real system as precisely as possible. The second goal is to develop this simulation model into a user-friendly tool that one could use to find an “optimal” or “best” product batch schedule for a one year time period. Such a batch schedule could change dynamically as perturbations occur during operation that influence the behaviour of the entire system. The result of the simulation, the ‘best’ batch schedule is the one that minimizes the operational costs in the system. The costs involved in the simulation are inventory costs, interface costs, pumping costs, and penalty costs assigned to any unforeseen situations. The key factor to determine the performance of the simulation model is the way time is represented. In our model an event based discrete time representation is selected as most appropriate for our purposes. This means that the time horizon is divided into intervals of unequal lengths based on events that change the state of the system. These events are the arrival/departure of the tanker ships, the openings and closures of loading/unloading valves of storage tanks at both terminals, and the arrivals/departures of trains/trucks at the Delivery Terminal. In the feasibility study we analyse the system’s operational performance with different Head Terminal storage capacity configurations. For these alternative configurations we evaluated the effect of different tanker ship delay magnitudes on the number of critical events and product interfaces generated, on the duration of pipeline stoppages, the satisfaction of the product demand and on the operative costs. Based on the results and the bottlenecks identified, we propose modifications in the original setup.