Environmental Engineering as Care for Human Welfare and Planetary Health

Among the subdisciplines of engineering, environmental engineering is distinctive in three aspects. First, descriptions of the profession of environmental engineering emphasize that environmental engineers solve problems to prevent harm, which typically is an important motivation for taking a job in care work. Second, the percentage of degrees awarded to women is highest for environmental among all subdisciplines of engineering (i.e., 53.3% of bachelor’s degrees, 46.3% of master’s degrees, and 43.6% of doctoral degrees in environmental engineering conferred in 2020 were awarded to women). Third, median salaries for environmental engineers–controlling for other variables–are lowest among engineering subdisciplines (i.e., $82,036 per year in 2019), despite high levels of educational attainment and training. Our analysis of environmental engineers working in the United States strongly suggests that the profession of environmental engineering is highly susceptible to what is known as the care penalty. The care penalty is a function of market dynamics, which tend to undervalue work that generates substantial unpriced benefits for others. The care penalty often is observed in jobs characterized by high levels of intrinsic motivation, such as concern for human welfare. Additional data would be useful to further evaluate the care penalty in environmental engineering in other countries. To address the care penalty, we do not suggest that environmental engineers should become less caring. Rather environmental engineers should be aware of this potential economic risk and seek to mitigate the care penalty in two specific ways. First environmental engineers should encourage life-cycle principles and environmental full-cost accounting in order to increase fungibility among different measures of the components of the triple bottom line of people (i.e., human welfare), planet (i.e., planetary health), and prosperity (i.e., financial gain). Second, environmental engineers should clearly demonstrate the unique contributions that technically skilled commitments to human welfare can generate. We suggest that a greater awareness of these issues could build on and strengthen growing public concerns regarding environmental sustainability. Finally, we suggest that distinctive attributes of environmental engineering may prove critical to unlocking growth in the engineering workforce as care for human welfare and planetary health

Quantification of an Eikelboom type 021N bulking event with fluorescence in situ hybridization and real-time PCR

Primers targeting 16S rRNA genes were designed to detect and quantify Eikelboom type 021N organisms by real-time PCR. Eikelboom type 021N filamentous bulking was induced in a laboratory-scale sequencing batch reactor and the evolution of Eikelboom type 021N 16S rRNA and 16S rRNA genes was monitored. A significant correlation was found between the sludge volume index and the amount of these filamentous organisms present in the sludge (r 2=94.6%, n=10,