香京julia种子在线播放

The Brazilian federal government established standardized social housing projects as a means to provide shelter for low-income families. The existing projects are named popular housing (R1), popular building (PP4), and building of social interest (PIS). Low-interest bank loans to constructors and families are available, as well as tax reduction during and after the construction phase.

Brazil is a large country with different biomes, cultures, climate conditions, and with the different spatial distribution of construction materials availability. Although the standardized social housing projects were derived from an important policy under social perspective, their application across the country raises doubts about the implementation of one type of project over another in the different states toward a better environmental performance. In this sense, Giannetti et al. (2018) studied the Brazilian social housing projects aiming to determine which project is the most adequate to be implemented in each one of the 27 Brazilian states. Using emergy synthesis, the authors accounted for the resource exchanges among the Brazilian states classifying them into renewable, non-renewable, or imported from other states. Focus was also given in the partial renewability of some resources used during housing construction.

The results, analyzed through the emergy ternary diagram, showed that although the R1 project obtained higher performance for the environmental sustainability index (ESI^*) in most states, all three projects are strongly more dependent on non-renewable resources (N, local free resources from nature) than on the imported (Imp) and on renewable (R) ones. Complementarily, results were presented in a graph (Figure 2) relating the ESI^* with the emergy index for construction productivity (EICP, in m²/sej), which supports a holistic (Odum's macroscope) decision on what type of social housing project should be supported in each Brazilian state to achieve higher sustainability. Results indicated that PIS should be implemented in 21 states, while R1 in 6. Popular building (PP4) should not be implemented in any state based on the emergy environmental perspective.

The large Brazilian territory and its regional specificities (cultural, climatic, socio-economical), the individual access of each State to energy and material resources make this kind of evaluation an important example in showing that projects (including social-housing ones) should be carefully chosen by considering environmental variables. Standardizing projects or even choosing projects exclusively based on economic and/or social concerns could be premature, since the opportunity to maximize sustainability could be either forgotten or neglected.

Sevegnani et al. (2018) assessed the internal stocks of an urban system comprising three municipalities in São Paulo, Brazil, called ABC Paulista. The macroscope allowed to visualize the urban stocks that were classified as economic, natural, and social capitals. The economic capital was identified as built structures and vehicle fleet. The natural capital is composed of the water from the reservoirs and the biomass, while the social capital regards the population. The three forms of capital combine themselves promoting development, growth, and complexity. The emergy of natural capital can be understood as a measure of the cities' reliance on natural resources. Less than 1% of the relative participation of ecosystem goods and services was observed, indicating that the ABC Paulista, like other urban centers, sustained its growth based on economic and social capitals, putting aside the preservation of green areas, and local resources. Results also revealed that economic capital is greater than the social one. Due to its high industrial activity, ABC Paulista can be seen as an “urban industry,” when viewed under the macroscope. Raw materials are transformed into final goods using know-how, as well as the infrastructure, justifying such a large economic capital portion. The “urban industry” activities contribute to the development of the larger system (State and Nation), however, as a counterpart, they are highly dependent on external resources and environmental services.

The natural and economic storages of assets were assessed, generating the value of each capital in emergy units (sej) transformed into “Emdollars,” using the eMergy-based currency (Figure 3). The bars show the capital needed to generate one unit of GDP, or the capital available for a GDP unit in each urban system. Estimations can be made in terms of total exploitation of one stock and the effects this would cause, as well as whatever effects the increment of one stock would generate.

The results showed an approximate relation of 12,000:1,100:1 for economic, social, and natural capital respectively. ABC Paulista needs more than 300 dollars of capital (in terms of stock) to make 1 dollar circulate in the economy, confirming that this urban system requires much more feedback from the economy than from local resources, renewable or otherwise, leading to an interpretation of non-sustainable systems. On the other hand, it is possible to identify that part of the emergy of this urban system is used to develop and maintain high-quality assets, giving support to activities that generate higher energy content (transformity) goods and services. The macroscopic view can identify that stored energy is used to increase the size and complexity of the system, and the assessment of storages can help to understand and measure the system complexity.

Emergy accounting was also used to study the ABC Paulista under the perspective of prosperity, carrying capacity, and trade (Sevegnani et al., 2017). Accounting for 0.5% of total national emergy, ABC Paulista works as a production center combining the abundance of labor and knowledge with the proximity to large consumer centers.

The emergy indices (Table 1) revealed unsurprising results, enforcing the idea of high dependence of the urban systems on external resources, from both inside and outside Brazil. Approximately 50% of the total emergy of ABC Paulista results from foreign imports and the remaining 50% is from internal (Brazil) imports. The main internal imports are electricity and fuels. The value of Emergy Yield Ratio (EYR), very close to 1 (one), indicates that this urban system is a simple consumer system showing no ability to rely solely on its local resources. On the other hand, the high value of the Environmental Loading Ratio (ELR) shows that the activities occurring in ABC cause high environmental stress. Dividing the EYR by the ELR gives the Environmental Sustainability Index (ESI), which is also low, thus evidencing the environmental pressure resultant from an economy that is highly dependent on imported resources, underlining a low contribution of local resources to the growth of the GDP. Under the light of Emergy Accounting, this urban system can be classified as non-sustainable, since it presents low environmental yield and high environmental loading.

A carrying capacity evaluation was performed and revealed that ABC would support only 4,500 people when considering reliance only on its renewable emergy sources, which corresponds to 2% of the actual population.

The fairness of the trading activities was evaluated by the emergy exchange ratio (EER) indicator. The emergy benefit ratio value for ABC was 2.3, when trading with foreign countries and 1.7 when trading internally with the rest of Brazil. This indicates that when ABC trades with foreign countries, its exports aggregate 2.3 times more emergy in goods and services than ABC receives from the money paid for these exports. Trading internally with Brazilian regions is less disadvantageous (EER = 1.7). So, the trading activities with Brazil and foreign countries are disadvantageous for ABC, and all its municipalities. These results contradict the traditional monetary approach showing that ABC exports, despite promoting economic growth, deliver much more emergy to the buyers than the emergy received back in currency units. The conclusion is that ABC Paulista works primarily as an “industry” and not as a municipality, allowing to suggest that, in the short term, reducing exports to foreign countries and increasing trade with Brazil should attenuate the losses in emergy terms and could stablish a fairer trade activity.

Under the Club of Rome's idea of limits to growth, and recognizing the exponential increase of world population migrating from rural to urban areas, studying the cities limits to growth is of paramount importance to subsidize public policies toward sustainable development. This is especially true, since cities are mostly dependent on fossil energy and other non-renewable materials to support growth. Policymakers must understand the limits of urban growth before proposing the most appropriated policies for sustainable growth. In this context, Agostinho et al. (2018) applied emergy synthesis (Odum's macroscope) in five cities (Araraquara, Bragança Paulista, Campinas, São Paulo, and Taubaté) located in São Paulo State, Brazil, in an attempt to quantify their limits to growth. Emergy was used as a proxy to visualize the limit to growth, specifically calculating the dynamics of empower per capita (in sej/capita/yr) and emergy to money ratio (EMR, in sej/USD) from 1999 to 2011.

The obtained empower and EMR dynamics showed similar growth behavior for all evaluated cities but indicated different development growth stages for each city. Improved efficiency was also observed for all cities, which means that they are able to generate a dollar to GDP by demanding a lower amount of emergy. As represented in Figure 4, stabilization of cities' empower per capita and/or of GDP was not observed, maybe because the limits to growth had not yet been reached within the time period considered. Since the evaluated cities are representative for São Paulo State, the state with the highest social-economic performance among the Brazilian States, it is expected that obtained results can be applied for all other Brazilian cities, each one under its own development stage.

This work also contributed to the advances of emergy synthesis by suggesting the use of thermal transfer in estimating the rainfall transformity (14,150 seJ/J) rather than the traditional approach considering chemical and/or potential rainfall energy, and that index of sustainable economic well-being (ISEW) should be used instead of total GDP to better represent the monetary contribution for societal well-being.

The ecosystem services provided by urban parks were the object of the study by Almeida et al. (2018a). The evaluation was done using the emergy synthesis applied to 73 parks spread throughout the city of São Paulo, Brazil. The parks were divided into small, medium and large and the indicators used for the assessment were the emergy of the NPP, emergy of evapotranspiration, emergy of water retention, as well as the Global Productivity (GP) of CO₂ sequestration, evapotranspiration, and water retention. Figure 5 shows a summarized emergy diagram that can be constructed when using Odum's macroscope. The system receives renewable natural resources (R) and purchased resources (F) from outside its boundaries. These resources, combined with the non-renewable resources (N) inside the system, give support to the NPP stock and help to maintain the facilities inside the parks. The yield of the system presented on the right side of the diagram is the benefits provided to the larger system—the city of São Paulo.

Comparisons of each indicator per area of each park were made, and the results revealed that the most important service provided by the urban parks is the CO₂ sequestration, represented in Figure 5 by the storage of net primary production (NPP). Results revealed that parks with less than 10,000 m² generate ecosystem services less efficiently and the larger ones tend to require less energy. The study estimated the emergy value of the ecosystem services provided by the parks as Em$ 8.5 million and the cost for the municipality as Em$ 6.4 million. Thus, for each Em$ invested in the 73 urban parks of São Paulo, a Em$1.33 return to the municipality is achieved, indicating a positive benefit/cost ratio. It was concluded that decisions on the implementation of new parks or the renovation of the existing ones should consider trade-offs between maintenance costs and the value of the main ecosystem services provided/desired.

In that same year, Almeida et al. (2018b) evaluated how the ecosystem services provided by the urban parks are provided and used, at different spatial scales. The evaluation of environmental costs and the monetary costs determined what type of park is more adequate and meets the environmental needs of a given surrounding neighborhood.

The ratio between natural and economic resources was used as an indicator to manage the urban parks allowing to identify the best configuration for each one, as well as actions for future developments, and the adjustment regarding housekeeping for the existing parks. The results showed that in São Paulo, when considering the total number of small parks, the delivery of ecosystems' services is insufficient, when contrasted with the economic investment made by the municipality. This statement shows a different position when comparing to studies that report higher benefits of implementation of a great quantity of small parks when comparing to fewer ones occupying larger areas. The study calculations show that 82 new small parks would be required in São Paulo city, for the whole set to reach the natural/economic balance. These new parks should consider a tree/grass relationship of 80:20. It was also found that only larger parks (larger than 250,000 m²) are beneficial in terms of climate regulation.

Although allowing for a fast growth on a series of desired socio-economic aspects, urban agglomeration also results in a series of undesired or “catabolic” activities, such as highly concentrated urban solid waste (USW) generation that must be collected, transported and treated appropriately. Urban waste management is of utmost importance due to its direct related social and environmental risks (bad odor, bad landscape appearance, proliferation of disease vectors, toxicological issues on water, and soil, global warming gases emissions, risks on regional fauna, etc.), as well as the indirect associated costs. All this becomes even worse in a city with 12 million inhabitants concentrated in a 1,500 km² area.

Alternatives to manage USW are needed, mainly those most sustainable-oriented. Under this scenario, a sorting and composting waste treatment plant (SCWTP) was proposed and implemented in São Paulo city, and its efficiency was assessed under a macroscale perspective (emergy synthesis) by Agostinho et al. (2013). The obtained results emphasize that, while for some materials (iron & steel, plastic, and compost) the recycling process is advantageous under a net emergy yield perspective, for others (glass and aluminum), the emergy invested is higher than the emergy received back with recycling. Only through a macroscope perspective as represented by Figure 6, one can visualize the energy flows supporting the SCWTP, and understand the reasons why not every recycling processes can be considered as a better alternative for urban waste management. The so-called hidden costs that are not usually perceived under smaller-scale analyses can be identified and accounted for in emergy synthesis. Several external resources are used by internal processes, which results in different performance levels for the recycled products.

Although not showing a positive emergy yield for some recycled materials, the evaluated SCWTP is still a better alternative than sanitary landfill (with and without electricity generation by burning methane) when compared with data from the scientific literature. The importance of the macroscope in the work of Agostinho et al. (2013) sustains that such conclusions can be only achieved when this larger-scale perspective is applied, avoiding decisions based exclusively on economic aspects.

Frimaio (2017) assessed technological options for more sustainable treatment of urban solid waste including landfill, incineration, plasma arc, composting, and pyrolysis. Plant scenarios were proposed to indicate the best option for megacities, medium, and big-sized cities, spatially distributed in each region in Brazil. Odum's macroscope (emergy synthesis) and goal programming were used as scientific methods. The proposed scenarios considered the efficiency of waste treatment options as well as the resulting benefits that each technology could provide, such as electric power and/or organic compost.

Results show the treatment option that integrates incineration and composting with a 50% share for the organic fraction of urban solid waste, demands the lowest amount of resources (emergy) for every city-size within the Brazilian regions. It was realized that it is more advantageous (i.e., lowest demand for non-renewable emergy) to increase the percentage of organic matter to 100% in the incineration-composting technology than using any other treatment option, since emergy per mass of treated waste will be still lower.

Although Odum's macroscope provides an important perspective for a decision, sometimes the cultural, economic, and geographical aspects do not allow for a decision based exclusively on emergy, which claims for a methodological approach that is able to find the best single technological waste treatment option when more drivers are taken into account. This is primarily important for decision-makers, who demand this kind of information from the scientific arena. In so doing, establishing and using a goal-programming model including the variables costs, emissions, emergy, treatment time, and area, the optimized result indicates the following order of preference for waste treatment option: composting, incineration, landfill, plasma arc. This is valid for all municipality sizes and their location, as well as for all different organic fractions in the waste.

Giannetti et al. (2016) assessed domestic wastewater treatment processes, in order to identify priority actions toward an improvement on sustainability performance. Odum's macroscope (emergy synthesis) was used as a method in quantifying the sustainability for two domestic wastewater treatment processes: activated sludge and biodigester. The costs supported by the surrounding environment to dilute the concentrated wastewater was the focus, as well as the demand for resources to implement and operate each treatment process. Emergy synthesis numbers were converted into land-area in an attempt to represent the support area for each treatment process that could be useful when deciding upon the location to install wastewater treatment plants.

Results show that the main resource inputs, in terms of emergy, for the activated sludge are electricity (28%) and labor (17%). For the biodigester, 44% of its emergy is related to labor. An important finding is that, during the operation phase, the biodigester requires only 20% of the emergy required by the activated sludge plant; the biodigester is the lesser resource-demanding option. When it comes to pollutant dilution, the environmental services of dilution required by the active sludge system correspond to 27% of its total emergy budget, which is high when compared to the 1% required by the biodigester. Another result that can show the high impact of the activated sludge system is that the emergy investment to dilute the emissions would be 60,000 times higher than that of the biodigester when comparing equal volumes of treated wastewater.

Although aiming at the same ultimate goal (i.e., to treat domestic wastewater) of helping the natural environment deal with the waste of human activities, both evaluated technological options impose a degree of additional load on the environment, by demanding resources for their implementation and operation phases. Usually, this can be observed and understood only by considering a macroscope perspective. Thus, the choice between one of these two treatments should consider the extent of the imposed extra environmental load due to the use of the ecosystem services required to dilute their emissions and the availability of an environmental support area to supply the resources required to their operation. Results showed that the biodigester option has better performance for all aerial-based indicators (Table 2) than the activated sludge option to treat the same volume of wastewater.