Browsing by Subject "climate change"

A systemic change in the current modes of production and consumption, a so-called sustainability transition, is required to overcome large-scale society-transforming phenomena such as the climate change. This in turn demands changes in socio-technical systems, i.e., the networks of actors, institutions, technologies, material artefacts, and knowledge creation. In this thesis, the Finnish construction and housing sector is used as a case study, and an example of one socio-technical system. By focusing on the socio aspect of the socio-technical, I analyse how actors who are involved in the current system may inhibit or enable a sustainability transition. I seek to answer the following questions: what the relevant definitions of and foci for climate-wise action are among stakeholders in the sector in Finland; how actor-related barriers manifest themselves; and which actors could enable or speed up the transition. This thesis builds on sustainability transition theories, especially multi-level perspective and strategic niche management, to better understand actor roles and relationships. Based on a literature review, I define three actor-related barriers to transition (misaligned vision and focus, small network, and pro-regime actor resistance) and one potential enabler (intermediaries). These are then applied to the Finnish context. In this thesis, I employed stakeholder analysis as the methodology, interviewing a pre-defined set of 21 stakeholders. The results were analysed using content and social network analyses. The results suggest that although the understanding of climate-wise construction and housing is gaining a more holistic perspective, the three barriers all still manifest in the sector in Finland: all the stakeholders are engaged in energy-related topics, but hold differing foci on household choices, low-carbon materials and circularity; the network amongst actors seems relatively dense and inclusive, but improvement points emerge with closer examination; although results suggest that development has happened in the recent years, industries and incumbents are still considered too slow-moving. The importance of intermediation is also recognised by many but defining and picking potential intermediaries out of the crowd is a complex task. Overall, the sector may be moving forward in the transition, but the stakeholders create and uphold both barriers and opportunities in the process.

My master’s thesis aims to determine the effect of salinity on phytoplankton traits related to nutrient acquisition, and particularly how this interacts with resource availability. Salinity is an important driver structuring phytoplankton communities in the Baltic Sea. Salinity can also influence nutrient uptake by increasing metabolic rates required for osmotic adjustment. Thus, interaction between salinity and nutrient availability is expected to change community structure by altering phytoplankton traits determining resource competition. This is a particularly relevant area of study for the Baltic Sea due to predicted future freshening of the sea’s upper layer. We performed a microcosm experiment using artificial communities of 10 diverse phytoplankton species grown under different combinations of salinity (0, 5, 12 and 24), Nitrogen to Phosphorus molar ratio (N:P ratio = 2, 10, 16 and 80) and light (10 and 130 µmol photon m-2 s-1) conditions. A three-way interaction among these environmental parameters influenced phytoplankton traits associated with resource competition, as well as the presence and proportions of phytoplankton taxa. Light limitation inhibited community growth under all salinity conditions, but allowed diatom Phaeodactylum tricornutum to dominate. Community growth rate was higher under high light, but also more variable between salinity conditions. The strongest negative effects of nutrient limitation (N, P, and both nutrients together), both on growth rate and taxonomic diversity, were observed in the highest salinity treatment. In the freshwater treatment with the highest proportion of green algae Monoraphidium sp., N-limitation did not inhibit phytoplankton community growth and P-limitation had a more profound negative effect on community performance. Decreasing salinity appeared to decrease community C:N and C:P ratios. This shift is in opposition to the increasing C:N and C:P predicted as a consequence of other climate change-related drivers. Our results emphasise the importance of a trade-off between salinity and resource limitation in functioning of phytoplankton communities and suggest that future freshening of the Baltic Sea is likely to modify phytoplankton community composition and performance.

Concern about global warming can lead to climate change anxiety, a form of anxiety characterized by excessive worry about the climate crisis and associated consequences on the natural world and human society. It has been suggested by previous research that humor can be used to manage feelings of anxiety. This study seeks to determine if this phenomenon can be applied specifically to climate change anxiety. The research combines a comprehensive literature review with an online survey that leveraged climate change themed internet memes as a proxy for humor to gather opinions about the intersections between these two topics. The survey data supplemented claims made by existing literature, indicating that climate change themed internet memes and humor in general can be useful coping mechanisms to mitigate feelings of climate anxiety. The survey was completed by 93 respondents; most of these participants were women, located in the US, and/or between the ages of 20 and 29. Results from the survey showed that people tend to feel best about their environmental anxiety when they are taking active steps to solve the problem. Conscious decisions such as reducing waste or participating in activist movements are easier to recognize and self-report than more passive coping skills. Reliance on humor was reported as a supplementary coping skill, but many respondents indicated that looking at humorous climate change themed memes did influence their feelings about climate change overall. The scope of this study was relatively small in scale, therefore the results presented in this thesis may not be indicative of broader social trends and likely require further research.

Biochar is a porous, carbon-rich material, made from organic material by pyrolysis in low oxygen conditions, and it can be used to sequester carbon into the soil. This review aspires to give an overview of the economic dimensions of using biochar in Finnish (Boreal and sub-boreal) forests. A literature review was conducted to collect and summarize the information about studies and applications elsewhere, and how we could possibly apply them into Finnish forest ecosystems. This thesis is done as part of Helsus Co-Creation Lab -project, where our group was tasked with looking into how biochar could enhance biodiversity in soil and accelerate transformation to low carbon economy. From this larger topic, this paper is looking into the economic side, and whether it is economically viable to use biochar to enhance and uphold biodiversity. This is evaluated by reviewing and categorizing 164 papers and conducting a literature review. My conclusions are that the current biochar applications show lower economic efficiency than other carbon dioxide abatement technologies. The stability of biochar in soil is a key factor, as the half-lives of biochars may not be as long as commonly suggested. Furthermore, competition for biomass resource use can restrict the availability of feedstock, and make it more expensive. Subsidies for biochar application are required if biochar is to be- come a significant part of the national or global climate mitigation policy. The results in different articles are quite variable and there is currently no standard approach to them. There is a need for specific research on what kind of biochar benefits what soil and vegetation, which is expensive. A primary goal is to incorporate a consistent and standardized testing or analysis method for biochar stability into the certification programs run and administered by the International and the European Biochar Initiatives. In the foreseeable future, biochar by itself is unlikely to play a significant role in climate mitigation strategies. Biochar might be just one of several alternatives in a bundle strategy to re- duce carbon emissions. However, its potential use must still be researched more.

Salt-induced flocculation is a process in which dissolved salts in seawater modify dissolved organic matter (DOM) surface charges and enable its transformation into larger fractions. These larger particles can settle to the benthos removing organic matter from the water column. Flocs formed in the flocculation process are often referred to as suspended particulate material (SPM). SPM is an important part of the biogeochemical cycles. SPM is a vector for pollutants, a food source for organisms and a habitat for microbes. Flocculation is part of the estuarine “coastal filter” -system controlling the material fluxes from land to sea. Climate change is causing water temperatures to increase in both inland and coastal waters affecting the biogeochemistry of aquatic ecosystems. Flocculation is a physicochemical process potentially impacted by temperature but the effects of temperature on flocculation are not well known. In my master’s thesis, I studied the effects of water temperature on the salt-induced flocculation of humic-rich river water. The flocculation experiments were conducted in spring 2023 using humic-rich water sampled from Vantaanjoki, Helsinki, Finland. The effects of temperature were studied in two separate experiments at temperatures ranging from 3 ºC to 20 ºC. The studied variables included quantitative suspended particulate matter as well as the optical properties of DOM including colored DOM and fluorescent DOM. Results of the experiments show that temperature did not have a significant effect on the salt-induced flocculation of DOM in humic-rich river water. However, the optical properties of DOM shifted with increasing temperatures and changing flocculation dynamics. Results show that molecular size increased as temperature increased but also when temperature was lower than 3 ºC. Explanation for the observed trends is discussed but more research is needed for more firm conclusions. DOM concentrations are expected to increase in the Arctic and sub-Arctic rivers transporting more organic matter to estuaries. Results of this thesis suggest that rising temperatures will not increase the amount of particulate matter through salt-induced flocculation meaning that a larger portion of the transported material remains in dissolved fraction. Increases in DOM concentrations may shift marine food webs by changing the food and light availability as well as biogeochemistry in estuaries.

Permafrost peatlands have the capacity to store significant amounts of carbon, and thus they act as important controllers of the climate. Approximately 14% of the world’s soil organic carbon pool is stored in permafrost peatlands, which are sensitive to climatic fluctuations due to their location in the high latitudes of the subarctic zone. Permafrost peatlands also act as a habitat for a large number of moisture-sensitive organisms, such as bryophytes and testate amoebae, which can be used to study how the hydrology of peatlands has changed and will continue to change throughout time, giving us an opportunity to predict the future of peatlands under a changing climate. In this Master’s Thesis I examined the testate amoebae composition and used these species as indicators to study hydrological fluctuations from three subarctic permafrost peatland cores extracted from Taavavuoma and Abisko in northern Sweden. The species compositions were combined with radiocarbon (14C) and lead (210Pb) dates to reconstruct the past water table levels for the late Holocene, spanning four climatic periods. The reconstructions were then compared to past studies on testate amoebae to understand how permafrost peatlands and their species assemblages respond to changes in the hydrology of the active layer of the peat. Out of the study sites only the Taavavuoma cores spanned the Dark Age Cold Period (DACP) and Medieval Climate Anomaly (MCA). Species compositions in both cores indicated fluctuating water tables during the DACP, but during the MCA the results began to contradict with one site showing a wetter, and the other a drier MCA. Two out of three study sites indicated a wetter Little Ice Age and a drier Post-Industrial Warming, supporting past studies indicating similar results, whereas one study site gave opposite results. The results indicated large variability in testate amoebae assemblages throughout time, indicating that the hydrology of peatlands can change very abruptly and vary considerably even on a local scale. Modelling is however complicated by the poorly known ecology of testate amoebae, which is why a multi-proxy approach is essential to reliably predict the future fate of permafrost peatlands.

Urban densification is resulting in the rapid loss of urban green spaces and their associated values. Moreover, the remaining urban green spaces are under increasing pressure to meet diverse resident needs and preferences. While past studies have investigated the intrinsic, instrumental, and relational values associated with such spaces, little attention has been paid to the sub-sets of relational values referred to a fundamental-relational (i.e., contributions toward enhanced social resilience) and eudemonic-relational values (i.e., actions, experiences, and habits linked to a “good life”). This study used public participation geographic information systems (PPGIS) surveys in a residential neighborhood of Helsinki, Finland to spatially explore and examine the differences between intrinsic, instrumental, fundamental-relational, and eudemonic-relational values in urban green spaces. I analyzed responses from residents and stakeholders (n = 1089) using Chi-square tests for significant associations and density-based clustering. Mapped values indicated that green spaces were primarily valued for their relational value, with an emphasis on eudemonic-relational values. Moreover, there were differences in the spatial distribution of instrumental, intrinsic, and relational values between green space types and values were spatially clustered by land use. Notably, there were few differences in how these values were assigned by different sociodemographic groups. I discuss the implications of these findings for local- and city-scale planning and the use of value typologies in PPGIS surveys. Further research in this field will benefit from the use of further value subcategories, increased geographic scale, and additional study of the influence of sociodemographic factors.

Climate change is expected to cause salinity change in the Baltic Sea and therefore may affect organisms living in the Baltic such as plankton. The microbial loop is an important part of the plankton food web. It consists of heterotrophic bacteria, nanoflagellates and ciliates and is connected with the classic plankton food chain through interactions with primary producers and mesozooplankton. Therefore, salinity affects the functioning of the microbial food web not only directly, but also through salinity induced changes on primary producers and mesozooplankton. In this master’s thesis I studied the effects of salinity change on microbial loop components bacteria, nanoflagellates and ciliates in an outdoor mesocosm experiment containing four salinity treatments with salinities of 3.5, 5.5, 7.5 and 9.5, three replicas each. The experiment took place offshore at the Tvärminne Zoological Station. Bacteria were sampled from the mesocosms every other day and nanoflagellates and ciliates every 6th day. Bacteria were analysed with the flow cytometer, nanoflagellates with epifluorescent microscopy and ciliates using an inverted microscope. The effects of salinity on microbial loop components were statistically tested using linear mixed effects models. Results of the experiment show that salinity had an indirect effect on microbial loop components through changes in mesozooplankton composition. There were significant differences between high and low salinity treatments in bacteria abundance and composition, the interaction strength between HNFs and bacteria and in the mean cell size of ciliate communities. These were mainly caused by differences in mesozooplankton community structure between salinity treatments, which had cascading effects on the strength of top-down and bottom-up control on the trophic levels of the microbial loop, leading to changes in bacteria abundances and composition. Based on the results of this thesis, more studies are needed to detect the effects that changes in the composition and functioning of the microbial loop might have on the ecosystem. Further research should also focus on the significance of the structure and diversity of the communities within the microbial loop as well as the functional roles of different species in the microbial food web.

Boreal mires are natural sources of methane and contribute considerably to the global methane budget. Therefore, in order to comprehend the overall impact that these ecosystems have on climate change, it is essential to understand the factors that influence processes involved in methane production and consumption. Factors affecting methane flux vary between different mires, but there is also great spatial and temporal variation in flux within mires. In previous studies, temperature and water table position have been shown to influence methane flux, but vegetation could aid in explaining the small-scale variation. Vegetation can indicate spatial variation in water table position, but also affect methane flux directly by the transportation of methane through plant tissues, and by providing substrate for microorganisms through primary production. Furthermore, redox potential is a poorly studied factor that can reflect if chemical conditions in peat are suitable for methane production or consumption, making it a useful tool in predicting methane flux. In this thesis, I seek to identify if small-scale spatial variation in the methane flux occurs within the studied mire area. In addition, I strive to identify important controllers of the observed spatiotemporal variation in methane flux, with a specific focus on the effect of vegetation properties and redox potential. Methane and carbon dioxide fluxes were measured with the closed chamber technique at a boreal fen in Sodankylä (67°22'06.6"N 26°39'16.0"E) during the growing season in 2019. Flux measurements were carried out at nine measurement plots belonging to three different vegetation types: flark, lawn and string. Coverage and height of plant functional groups were followed during the summer and continuous redox potential was measured for each plot. CH4 fluxes of different plots and vegetation types were compared to study the spatial variation in methane flux. Generalized additive models (GAM) were used to determine which variables are best to explain spatiotemporal variation in methane flux over the growing season. Mean methane flux during the summer was 0.94 ug CH4 m-2 s-1 which is in the same magnitude as observed in a previous study at the fen. Some small-scale spatial variation in the methane fluxes was observed at the study site, with strings having lower flux than flaks and lawns. However, overall the spatial variation was small, while temporal variation in methane flux over the growing season was considerable. The best model, that was a combination of vegetation, redox potential and environmental variables, and it explained 72 % of the observed variation in methane flux. Vascular plant variables were the most important variables in the model, whereas moss functional groups were of lesser importance. Redox potential in deeper peat layers was also important in the model, but redox potential closer to the surface was not found to be significant. Vegetation is an important controller of methane flux, and this information could potentially be used when predicting methane flux over larger areas by using remote sensing to map vegetation characteristics. Redox potential, on the other hand, is relatively easy to measure, and the result suggests that it could provide a useful tool for improving the predictions of methane flux.

Climate change is applying pressures to plant populations, which must adapt or move to retain fitness. A changing climate highlights the need for us to understand the potential that species possess to evolve in addition to any plastic responses. Approaches that allow the study of contemporary evolution, such as resurrection studies, have the capacity to provide insights into the responses of populations to these changes. In this resurrection experiment, seeds from seven populations of Hypericum perforatum collected from the UK and France, and their historic counterparts, were grown and subjected to four temperature treatments. Three traits were measured and compared between historic and contemporary populations: date of flowering, average seed weight and flower abundance. I found that temperature influenced date of flowering and flower abundance, leading to an overall earlier flowering time and an overall decrease in flower abundance with increase in temperature. The only significant difference between historic and contemporary populations was found in flower abundance - where, whilst flower abundance declined with increasing temperature, contemporary populations produced proportionally more flowers than historic populations per degree of temperature increase. These results suggest that plasticity allows this species to adjust its flowering phenology to retain fitness in warmer conditions but that evolution during the past decades may have selected for a decreased flower abundance at higher temperatures. These findings contribute to our overall understanding of how species have and will react under climate change, as we try to disentangle the roles that plasticity and evolution play in enabling populations to retain fitness under changing conditions.