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Place-making practices refer to the ways in which people create and define physical spaces as meaningful and significant through their everyday activities and social interactions.[1] In Ethnography, the study of these practices is often referred to as ‘ethnography as place-making,’ which involves the exploration of the cultural meanings and practices that shape the physical and social environments in which people live. This can include examining how people create and maintain social boundaries, how they express their identities and values through the built environment,[2] and how they negotiate power and control over the spaces they inhabit.

This place in Gröpelingen is made a place through the interaction of the people tending to the urban gardening project. 

1. Pink 2008, 178ff. 

2. See: urbanization 

3. Pink 2008, 190. 

The first section of the presentation focuses on the use of artificial intelligence to improve manufacturing and reduce carbon emissions (see 2019 report). Formosa's efforts go back to 2017, when the company was one of five business that each invested NT$30million in the creation of Taiwan’s first AI Academy, initiated by scholars at Academia Sinica (see also Lin 2018). According to the Ministry of Foreign Affairs “[t]he academy has drawn faculty from scholarly institutions ranging from Taiwan’s major universities to foreign research institutes, Academia Sinica and the Industrial Technology Research Institute, as well as from the corporate sphere, with AI managers and entrepreneurs coming in to share their real-world AI experience.” Further, they state that by 2020, FPG had trained over 100 workers through courses offered by the academy.

Slides 37-55 outline FPG's current carbon capture system in Kaoshiung and its future plans for CCS systems in Mailiao, including an experimental system of biodegradable carbon capture. These initiatives, largely through Formosa Smart Energy Corp. also attempt to use AI models to regulate carbon capture for optimal production. 

See slides 40-42 for new initiatives on carbon capture. They list plans to build deep water carbon capture pits, being sited in Yunlin as of 9.2022.

The carbon capture system they have in place at Nanya seems to have reduced the amount of naptha necessary to manufacture butyl ether, a chemical used in solvents and pesticides, through reinjection of that carbon dioxide into source feedstocks (Enhanced Oil Recovery).

“國際碳捕捉技術發展

依據全球碳捕捉與封存研究所(Global CCS Institute, CCSI)最新發布之「2022年全球碳捕捉與

封存發展現況報告(The Global Status Of CCS 2022)」，⾄2022年全球共有30個⼤型CCS綜合

專案已經營運，其中有22個採⾏強制採油技術(Enhanced oil recovery, EOR)，利⽤⼆氧化碳灌

注⾄快枯竭的油氣⽥，獲取更多殘存油氣，以增加效益，其餘8個專案封存於陸地或海洋深層

鹽⽔層，顯示現階段應⽤仍以EOR技術為主，除可減少碳排外，更可增加獲利。

自動翻譯

 Capture Technology Development

According to the "2022 Global Carbon Capture and Storage Storage Development Status Report“ (The Global Status Of CCS 2022), by 2022 there will be 30 large CCS comprehensive

The projects are already in operation, and 22 of them adopt enhanced oil recovery (EOR), using carbon dioxide irrigation. Inject into the depleted oil and gas to obtain more residual oil and gas to increase efficiency, and the remaining 8 projects are sealed in land or deep ocean

The salt water layer shows that the current application is still dominated by EOR technology, which can not only reduce carbon emissions, but also increase profits.” (Slide 38)

Heavy reliance on technosolutions to reach emission reduction and climate goals. Shift from oil as fuel to oil as material. Cooperation between industry, academic, and technical research organizations to research new carbon capture systems. Longevity of the petrochemical industry within climate politics is a high priority for FPG, but also the efficiency of petrochemical inputs. Climate change action is being pursued, but more so in capture of carbon emitted and repurposed within chemical reactions, as opposed to omitted through reductions in production

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.