Punks, Goths, and Other Eye‐Catching Peer Crowds: Do They Fulfill a Function for Shy Youths?

Abstract. Over history, humankind has tended to settle near streams because of the role of rivers as transportation corridors and the fertility of riparian areas. However, human settlements in floodplains have been threatened by the risk of flooding. Possible responses have been to resettle away and/or modify the river system by building flood control structures. This has led to a complex web of interactions and feedback mechanisms between hydrological and social processes in settled floodplains. This paper is an attempt to conceptualise these interplays for hypothetical human-flood systems. We develop a simple, dynamic model to represent the interactions and feedback loops between hydrological and social processes. The model is then used to explore the dynamics of the human-flood system and the effect of changing individual characteristics, including external forcing such as technological development. The results show that the conceptual model is able to reproduce reciprocal effects between floods and people as well as the emergence of typical patterns. For instance, when levees are built or raised to protect floodplain areas, their presence not only reduces the frequency of flooding, but also exacerbates high water levels. Then, because of this exacerbation, higher flood protection levels are required by society. As a result, more and more flooding events are avoided, but rare and catastrophic events take place.

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Debates—Perspectives on socio‐hydrology: Capturing feedbacks between physical and social processes

Baldassarre

Viglione²,

Carr

et al. 2015

Water Resources Research

392

369

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In flood risk assessment, there remains a lack of analytical frameworks capturing the dynamics emerging from two-way feedbacks between physical and social processes, such as adaptation and levee effect. The former, ''adaptation effect'', relates to the observation that the occurrence of more frequent flooding is often associated with decreasing vulnerability. The latter, ''levee effect'', relates to the observation that the non-occurrence of frequent flooding (possibly caused by flood protection structures, e.g. levees) is often associated to increasing vulnerability. As current analytical frameworks do not capture these dynamics, projections of future flood risk are not realistic. In this paper, we develop a new approach whereby the mutual interactions and continuous feedbacks between floods and societies are explicitly accounted for. Moreover, we show an application of this approach by using a socio-hydrological model to simulate the behavior of two main prototypes of societies: green societies, which cope with flooding by resettling out of flood-prone areas; and technological societies, which deal with flooding also by building levees or dikes. This application shows that the proposed approach is able to capture and explain the aforementioned dynamics (i.e. adaptation and levee effect) and therefore contribute to a better understanding of changes in flood risk, within an iterative process of theory development and empirical research.

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Insights from socio-hydrology modelling on dealing with flood risk – Roles of collective memory, risk-taking attitude and trust

Viglione

Baldassarre

Brandimarte

et al. 2014

Journal of Hydrology

259

237

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Water shortages worsened by reservoir effects

et al. 2018

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Conceptualizing socio‐hydrological drought processes: The case of the Maya collapse

Kuil

Carr

Viglione

et al. 2016

Water Resources Research

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With population growth, increasing water demands and climate change the need to understand the current and future pathways to water security is becoming more pressing. To contribute to addressing this challenge, we examine the link between water stress and society through socio‐hydrological modeling. We conceptualize the interactions between an agricultural society with its environment in a stylized way. We apply the model to the case of the ancient Maya, a population that experienced a peak during the Classic Period (AD 600–830) and then declined during the ninth century. The hypothesis that modest drought periods played a major role in the society's collapse is explored. Simulating plausible feedbacks between water and society we show that a modest reduction in rainfall may lead to an 80% population collapse. Population density and crop sensitivity to droughts, however, may play an equally important role. The simulations indicate that construction of reservoirs results in less frequent drought impacts, but if the reservoirs run dry, drought impact may be more severe and the population drop may be larger.

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Linda Kuil

Socio-hydrology: conceptualising human-flood interactions

Debates—Perspectives on socio‐hydrology: Capturing feedbacks between physical and social processes

Insights from socio-hydrology modelling on dealing with flood risk – Roles of collective memory, risk-taking attitude and trust

Water shortages worsened by reservoir effects

Conceptualizing socio‐hydrological drought processes: The case of the Maya collapse

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