Citizen scientist efforts, wherein members of the public who are not professional scientists participate in active research, have been shown to effectively engage the public in STEM fields and result in valuable data, essential to answering pressing research questions. However, most citizen scientist efforts have been centered in colleges of science, and a limited number have crossed into research areas important to chemical engineering fields. In this work we report on the results of a project to recruit high school and middle school students across Utah’s Salt Lake Valley as citizen scientists and potential engineering students who work in partnership with chemical engineering researchers in an effort to create a distributed online network of air quality sensors. Middle and high school students were trained by undergraduate mentors to monitor and maintain their own outdoor air quality sensor with the help of teaching materials that were co-developed with Breathe Utah, a local community group concerned with air quality. With the help of these tailored teaching modules, students learned about the science behind air quality research and the difficulties common to physical measurements to better prepare them to analyze their data. Once trained, students are expected to become semi-independent researchers in charge of monitoring and maintaining their piece of a larger air quality map. We describe in this work the hurdles inherent in citizen science engagement within a chemical engineering research program and the means to address them. We describe successful means of engaging classrooms, training citizen scientists, obtaining faculty buy-in within the confines of state curricular demands, and addressing school administration concerns. With this model, we have directly engaged over 1,000 high school and over 3,000 middle school students. The project has resulted in a growing network of citizen-maintained sensors that contributes to a real-time air quality map. Student scientists may also use the sensors to participate in active research or conduct science fair projects. Student response to this citizen scientist project, where it may be measured, has been enthusiastic and almost wholly positive.
[1]
Randal S. Martin,et al.
Ambient and laboratory evaluation of a low-cost particulate matter sensor.
,
2017,
Environmental pollution.
[2]
A. Parker,et al.
Environmental protection belongs to the public: A vision for citizen science at EPA
,
2017
.
[3]
David De Roure,et al.
Zooniverse: observing the world's largest citizen science platform
,
2014,
WWW.
[4]
N. Oliver,et al.
People power
,
2014,
Nature.
[5]
John Duffy,et al.
Attracting Underrepresented Groups To Engineering With Service Learning
,
2007
.
[6]
Christopher Kullenberg,et al.
What Is Citizen Science? – A Scientometric Meta-Analysis
,
2016,
PloS one.
[7]
Anthony Butterfield,et al.
Effective Engineering Outreach through an Undergraduate Mentoring Team and Module Database
,
2014
.
[8]
Pierre-Emmanuel Gaillardon,et al.
Building Air Quality Sensors & Inspiring Citizen Scientists
,
2018
.
[9]
Assessing The Evolution Of Engineering Saturday Academies For Middle School And High School Women
,
2007
.
[10]
Adrien Treuille,et al.
Predicting protein structures with a multiplayer online game
,
2010,
Nature.
[11]
Sean F. Reardon,et al.
Private School Racial Enrollments and Segregation.
,
2002
.