Climate change, young people, and the IPCC: the role of citizen science

This commentary suggests that undertaking citizen science research with young people has the potential to play a significant role in contributing to the IPPC and related UN research and policy processes around climate change. Further, citizen science engagement can educate and empower children and young people in and through research by involving wider communities and groups in data collection, communication, and engagement. A persuasive body of literature suggests that children and youth can be and ought to be included in citizen science projects and that young people ought to and can have a greater say in their environmental and climate lives and futures. There is acknowledgment that certain populations, including young people, have been excluded from participation in citizen science, and strategies need to be developed to be more inclusive. Moreover, through inclusion of youth, there are opportunities for intergeneration collaboration leading to potential solutions. Our commentary is a call for the IPCC to be much more open and creative in its knowledge production work and to engage young people in climate-related citizen science

The Water Footprint of Data Centers

The internet and associated Information and Communications Technologies (ICT) are diffusing at an astounding pace. As data centers (DCs) proliferate to accommodate this rising demand, their environmental impacts grow too. While the energy efficiency of DCs has been researched extensively, their water footprint (WF) has so far received little to no attention. This article conducts a preliminary WF accounting for cooling and energy consumption in DCs. The WF of DCs is estimated to be between 1047 and 151,061 m3/TJ. Outbound DC data traffic generates a WF of 1–205 liters per gigabyte (roughly equal to the WF of 1 kg of tomatos at the higher end). It is found that, typically, energy consumption constitues by far the greatest share of DC WF, but the level of uncertainty associated with the WF of different energy sources used by DCs makes a comprehensive assessment of DCs’ water use efficiency very challenging. Much better understanding of DC WF is urgently needed if a meaningful evaluation of this rapidly spreading service technology is to be gleaned and response measures are to be put into effect

Citizen science for conservation: towards a cleaner, greener China

Citizen science (CS) is the practice where amateurs without formal scientific training collect data to contribute to the scientific observations available to scientists and decision makers (Bonney, et al., 2009). Citizen science is increasingly utilized for environmental protection and conservation as well as related purposes such as education, access to nature, access to justice, inclusion, civics and equality or other ‘social goods’ (Mor Barak, 2020; Makuch & Aczel, 2020). Several eco-citizen science projects are developing in China (Chen, et al., 2020; Hsu, Yeo & Weinfurter, 2020), though little research has evaluated their effectiveness in facilitating environmental protection or advancing social goods. This paper aims to identify the role and potential benefits of environmental citizen science in China to promote environmental and social objectives within the context of what has been called “authoritarian environmentalism” (Beeson, 2018). Through semi-structured interviews and a review of the (limited) available literature, we identify three key areas in which citizen science could potentially benefit environmental protection and promote social good in China: (1) fostering education to inform society and encourage environmental advocacy; (2) facilitating effective environmental governance through monitoring and litigation; and (3) improving data collection for biodiversity and conservation research

Idoneidad del establecimiento del área natural protegida del mar pacífico tropical. suitability of the establishment of the protected natural area of the tropical Pacific sea

In this essay we will analyze the suitability of the establishment of the Marine Protected Area (MPA) of the Tropical Pacific Sea, which would be located off the coast of Piura and Tumbes. Based on an analysis of the literature regarding the design and implementation of MPAs, we will point out some aspects that should be taken into account by administrators and decision makers in all the stages related to the process of assigning the MPA figure to a specific geographical area. Also, we will review the official documentation developed in the proposal process by various state agencies. The objective of this essay is to provide insights into the correct preparation of a proposal that changes the legal system on which the geographical area chosen to be protected rests

Facilitating the transition to sustainable green chemistry

Sustainable green chemistry depends on technically feasible, cost-effective and socially acceptable decisions by regulators, industry and the wider community. The discipline needs to embrace a new suite of tools and train proponents in their use. We propose a set of tools that will bridge the gap between technical feasibility and efficiency on one hand, and social preferences and values on the other. We argue that they are indispensable in the next generation of regulators and chemistry industry proponents

Anticipatory regulation: lessons from fracking and insights for Greenhouse Gas Removal innovation and governance

The UK has incorporated a net-zero emissions target into national legislation. A range of Greenhouse Gas Removal (GGR) options will likely play a key role in the government's strategy toward meeting this goal. Governance frameworks will need to be developed to support GGR development and manage the potential impacts, particularly those on the diverse local communities where the various options will be deployed. This research examines the UK's experience with development and regulation of shale gas - using the technologies of hydraulic fracturing combined with horizontal drilling - with a focus on governance and the implications for the development and widespread deployment of GGR. We evaluate the approach used against the principles of good governance, which emphasizes the critical role that local communities and publics play in deployment. The UK's top-down governance of shale gas highlights the risk of regulation driven by assumptions about national and local need, value and a lack of transparency or meaningful stakeholder participation in decision-making. The use of existing legislative frameworks for conventional fossil fuel extraction proved inadequate to address unanticipated consequences such as induced seismicity. Moreover, the support for unconventional hydrocarbons in UK energy policy appeared inconsistent with the goal of meeting greenhouse gas targets and passing significant legislation in 2019 to bring carbon emissions to net-zero. To gain social acceptance at the local level, deployment of new technologies needs to be evaluated from a variety of framings and viewpoints. Where new technologies or practices are deployed, such as fracking and GGR, the knowledge and understanding of the impacts - a fundamental principle of good governance - may be less certain or more contested. Early inclusion and participation of local communities would allow issues of concern to inform how trials are undertaken and regulation designed. This anticipatory and participatory approach fits with the principles of good governance and procedural justice, which can help build the trust needed to ensure social legitimacy leading to development and implementation of technological innovations

Fjords as Aquatic Critical Zones (ACZs)

In recent decades, the land-ocean aquatic continuum, commonly defined as the interface, or transition zone, between terrestrial ecosystems and the open ocean, has undergone dramatic changes. On-going work has stressed the importance of treating Aquatic Critical Zones (ACZs) as a sensitive system needing intensive investigation. Here, we discuss fjords as an ACZ in the context of sedimentological, geochemical, and climatic impacts. These diverse physical features of fjords are key in controlling the sources, transport, and burial of organic matter in the modern era and over the Holocene. High sediment accumulation rates in fjord sediments allow for high-resolution records of past climate and environmental change where multiple proxies can be applied to fjord sediments that focus on either marine or terrestrial-derived components. Humans through land-use change and climatic stressors are having an impact on the larger carbon stores in fjords. Sediment delivery whether from accelerating erosion (e.g. mining, deforestation, road building, agriculture) or from sequestration of fluvial sediment behind dams has been seriously altered in the Anthropocene. Climate change affecting rainfall and river discharge into fjords will impact the thickness and extent of the low-salinity layer in the upper reaches of the fjord, slowing the rate of the overturning circulation and deep-water renewal – thereby impacting bottom water oxygen concentrations

Citizen science and the role of natural history museums

Citizen science, the active participation of the public in scientific research projects, is a rapidly expanding field in open science and open innovation. It provides an integrated model of public knowledge production and engagement with science. As a growing worldwide phenomenon, it is invigorated by evolving new technologies that connect people easily and effectively with the scientific community. Catalysed by citizens’ wishes to be actively involved in scientific processes, as a result of recent societal trends, it also offers contributions to the rise in tertiary education. In addition, citizen science provides a valuable tool for citizens to play a more active role in sustainable development. This book identifies and explains the role of citizen science within innovation in science and society, and as a vibrant and productive science-policy interface. The scope of this volume is global, geared towards identifying solutions and lessons to be applied across science, practice and policy. The chapters consider the role of citizen science in the context of the wider agenda of open science and open innovation, and discuss progress towards responsible research and innovation, two of the most critical aspects of science today