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Harmful PM2.5 emissions in Dhaka, Bangledesh prompting researchers to study emissions during winter and monsoon season.

helena.dav

Assessing the PM2.5 impact of biomass combustion in megacity Dhaka, Bangladesh - PubMed (nih.gov)

This article is about crop burning in Dhaka, Bangladesh and attempts to figure out if there is more or less harmful PM2.5 particulate air pollution caused by either fossil fuels or biomass, and during which season is one or the other higher in the air pollution it produces. During monsoon season, fossil fuels lead in the most PM2.5 releases at 44.3%. When it is not monsoon season and is the winter season, the percentages are way higher for PM2.5 air particulate releases at 41.4% for the remainder of the year. Across the globe, there are now people stepping up to uncover the true and real environmental and health impacts this harmful particulate byproduct causes in different parts of the world and with differring weather conditions than what we see in North Carolina. 

Emissions from Biomass Burning in South/Southeast Asia; correcting the miscalculation about the PM2.5 emissions from burning.

helena.dav

https://www.researchgate.net/publication/351209404_PM25_Emissions_from_…;

This study is set in South/Southeast Asia and uncovering that, when trying to count the percentages of PM2.5 put off during biomass, the true amount of emissions were being gravely undercalculated. Specifically rice straw burning becuase the amount burned varied so much because of different harvest and burning practices that it just wasn't taken into consideration. What this study does is go bottom up using these strategies: "subnational spatial database of rice-harvested area, region-specific fuel-loading factors, region, and burning-practice-specific emission and combustion factors, including literature-derived estimates of straw and stubble burned"(Lasko et al. 2021, 1). 

The Clean Air Act and the EPA laws and regulations against harmful PM2.5 air pollutant matter

helena.dav

The most common air pollutants are called criteria pollutants and are regulated by the Clean Air Act and the EPA. These pollutants are: particles, ozone, nitrogen oxides, sulfer dioxide, carbon monoxide, and lead. The EPA have sections under the CAA that help regulate factories and air pollution in the environment. For example section 108 requires the EPA to identify the pollutants that are criteria pollutants, listed above, and determine if where they are coming from and if they "endander public health or welfare". Under section 109 the EPA had to set standards across the board for air pulltion in regard to human health and to the environemtn sperately (Christopher D. Ahlers 2016, 51-52).  There are many more sections that go into detail about what the CAA can do and what the EPA members are required to do as well. 

Ahlers, Christopher D. “Wood Burning, Biomass, Air Pollution, and Climate Change.” Environmental Law 46, no. 1 (2016): 49–104. 

Energy Transitions

Briana Leone

As the title of the work hints to, the text builds on discussions surrounding energy policy and energy investments. Throughout the work, Boyer (2019) discusses dimensions of energy transitions that range from job creation, forms of development (industry and otherwise). Most significant to take into consideration is the fact Boyer (2019) acknowledges energy development often occurs without at par social, political, and economic transitions. Boyer (2019) advances discussions of energy politics and transitions by highlighting the inherent problems energy transitions bring into communities where wind farm and green projects are envisioned. Here, we should note the impacts energy transitions may have on the most vulnerable populations, which have been and continue to be documented. In fact, it is documented that LMI communities tend to be least likely to sport energy-efficient, carbon neutral energy systems and appliances (Cluett et al., 2016; Elnakat, 2016; Kaza et al., 2014).

How do we move forward?

Briana Leone

This text is particularly exemplary in documenting local community antagonism to energy transitions as it recognizes small-scale intrusions green energy may introduce. This varies from loss of agricultural planes to loss of fishing potential, as noises created by aeolian energy production can disrupt wildlife and their habitats. It is important to consider details like these in what can be considered microcosms of life. However, the text does not widely address how to move past these intrustions. Questions that still linger are: How can the introduction of green (aeolian and other) energy avoid damaging such microcosms? How can energy prices be made accessible to everyone thanks to the introduction of green energy instead of being used as an excuse to increase energy prices? What understandings are green energy investors missing to carry forward beneficial green energy projects? And, a question that the author asks from the beginning: How can the introduction of green energy benefit those communities in which projects are carried out?

Overcharged Energy Supplies

Briana Leone

This text historically traces the exploitative nature of energy supplies and charges (costs). Impactful statistics to consider in Oaxaca are that energy users pay for usage of one-hundred water plants when only twenty are operational but even more drastic is the fact energy companies overcharge residential customers to undercharge commercial customers (Boyer, 2019:100, 133). Here, we can think of COVID-19 parallels where nationwide job loss has burdened families' abilities to cope with utility bill payments. Companies have been pushing for cost/usage increases in residential sectors due to burdens experienced whilst contemporarily reducing cost/usage in commercial sectors. However, if burden experienced by residential customers is ignored, many will likely ask for subsidy payments, as CFE's customer base (98% of customers receive 70% off on their energy costs) (Boyer, 2019:152). The pre-COVID-19 burdens in Oaxaca have likely worsened since the advent of the COVID-19 pandemic, which should inform or at least direct wider discussions of energy rights as situated both within and outside a pandemic. More than informing understandings of COVID-19-situated conditions, this text provides us with the grounds to investigate pre-pandemic burdens and to discuss vulnerabilities to energy losses or scarcity, but also of the needs and willngness to promote efficiency, net-zero emissions, or even carbon neutral energy.

Racist energy systems

Briana Leone

Like many other systems, energy systems are grounded in gender, race, and social hierarchies. Similarly, we can think of energy infrastructures today as continuing racist, gendered, and classist systems, particularly when we think of the energy vulnerbale populations that are particularly affected by the pandemic. Just as Dr. Daggett suggests, we need new energy systems to move away from energy wastes, energy inequality but also energy systems to account for compouded vulnerabilities as faced by the most at risk populations.

COVID-19 and Energy expenditures

Briana Leone

As we think of the COVID-19 and energy shifts due to closure for social distancing aims, we can think of Dr. Daggett's argument of energy systems modeled for energy intensive and productive labor. In a sense, despite COVID-19 shifting energy consumption to the residential area, we can argue COVID-19 has also led to an overall reduction in energy use for industrial sectors. However, these reduced expenditures are not as significant as energy analysts had anticipated and, instead, call to Dr. Daggett's discussions of energy governing labor and hierarchies, as developed in a 19th century world. We can think of ways in which our systems (socioeconomic and political) have become wholly dependent on energy production and, thus, even our leisure activities will inevitably lead to the consumption of energy. Our COVID-19 energy paradigms demonstrate energy is so engrained into our regimes, even social distancing measures cannot wholly reduce overall energy expendatures, despite best efforts. In a way, we should try to understand energy paradigms in Dr. Daggett's eyes as specifically situated in the COVID-19 pandemic.

Solutions to work-based energy

Briana Leone

While the text discusses the birth and transitions of energy paradigms, providing timelines of how we have understood energy throughout the centuries, we are left with little in the way of how to move away from existing energy regimes (Daggett, 2019). That said, the text discusses work as a social convention rooted in energy definitions (Daggett, 2019:197). In other words, Dr. Daggett conceptualizes work relations in terms of energy, with productivity and efficiency concepts emerging from energy definitions, providing examples of how we, as a society, have moved from labor intensive work to abstract (still intensive) work to maximize capital. All of the foregoing discussions rely on concepts of energy, drawing connections between the nature of work and the expenditure of energy to discuss how energy-intensive economies have been created. However, while Dr. Daggett brings to light issues with the current energy networks we are frustatingly left with little ideas on how to tackle energy intensive environments. Frustatingly, with little suggestions on how to address energy-intensive labor markets the book simply provides us with a historical and more analytical discussion of how our labor systems have come to be.

New York City's electricity patterns during COVID-19

Briana Leone

As outlined in this brief article by the U.S. Energy Information Administration, energy consumption by New York City alone has dropped significantly more than the surrounding areas. On a prima-facie observation, one could say the foregoing alleviates stress on the existing energy infrastructures. However, deeper analyses should consider the repercussions that demanding less energy may have on production, supply, and distribution, as well as transitions between larger and smaller electric microgrids. Given energy infrastructures in the United States are already vulnerable, can it be really said the pandemic alleviates stress on the existing energy infrastructures when everybody is connected to the internet and is generally using more technology at home?