Workers' Organized Leisure Time at the 3. Maj Shipyard within the Framework of the Socialist Self-management Policy in the 1980s (Summary)

U ovome se radu na primjeru riječkoga brodogradilišta “3. maj“ obrađuje tema organiziranoga slobodnog vremena u okviru radničkoga samoupravljanja Socijalističke Federativne Republike Jugoslavije osamdesetih godina prošloga stoljeća. Prvi se dio rada bavi definiranjem organiziranoga slobodnog vremena te njegovim smještanjem u kontekst brodogradilišta “3. maj“, a drugi se dio rada posvećuje njegovu prikazu iz dviju perspektiva – one radnika s jedne strane, te poduzeća s druge. Cilj je rada prikazati načine provođenja organiziranoga slobodnog vremena trećomajskih radnika, a potom, na osnovi toga, pokazati njegovo značenje kako za radnike, tako i za poduzeće, čime se paralelno razotkrivaju i (ne)posredni razlozi za njegovo poticanje.This paper examines the topic of organized leisure time within the framework of workers' self-management in the Socialist Federal Republic of Yugoslavia in the 1980s, using the example of the shipyard 3.MAJ in Rijeka. The first part of the paper defines organized leisure time and places it in the context of the shipyard 3. MAJ, while the second part focuses on its depiction from two perspectives – that of the workers on one side, and the company on the other. The aim of the paper is to present the ways in which the workers of 3.MAJ spend their organized leisure time, and subsequently demonstrate its significance for both the workers and the company, thus also revealing the (in)direct reasons for its encouragement

Stomatal Conductance Modeling to Estimate the Evapotranspiration of Natural and Agricultural Ecosystems

This chapter presents some of the available modelling techniques to predict stomatal conductance at leaf and canopy level, the key driver of the transpiration component in the evapotranspiration process of vegetated surfaces. The process-based models reported, are able to predict fast variations of stomatal conductance and the related transpiration and evapotranspiration rates, e.g. at hourly scale. This high–time resolution is essential for applications which couple the transpiration process with carbon assimilation or air pollutants uptake by plants. In these cases, the big-leaf approach, together with the resistive analogy which simulates the gas-exchange between vegetation and atmosphere, is a simple but valid example of a process-based model which includes the stomatal conductance behaviour, as well as a basic representation of the canopy features