This is a modification of an original TIEE Module, investigating these questions: How does nutrient pollution impact stream ecosystems locally and nationally? How does land cover change impact nutrient pollution?

Students use data on nitrogen and phosphorus levels in streams and macrobenthic insect biodiversity to consider issues of nutrient pollution and stream health while learning to filter, summarize, and plot data.

Important learning outcomes for biology students include the ability to develop experiments as well as pull together concepts across their coursework. The field of developmental biology, especially environmental influences on development (eco-devo), provides a framework for connecting concepts including tissue dynamics, cell signaling, and physiology. An eco-devo framework also provides opportunities for experiments that are relevant to student interests and/or experiences by encompassing topics such as the impact of environmental contamination or maternal health on development. Here we present a guided course-based undergraduate research experience (CURE) for students to work with zebrafish embryos as a foundation for the design and execution of their own novel research project. The guided experiment that is performed first in this lesson explores how the weed killer atrazine might affect development of zebrafish, even though atrazine would not be expected to impact animals. The student-developed independent experiment is planned during the guided experiment and then performed in subsequent weeks by students in the second part of this lesson. The independent experiment allows students to investigate a research question related to their own interests. These experiments can be modified for a variety of courses depending on the instructor's curriculum, time constraints, and goals for the experiment. Students are particularly engaged in the lesson because it enables them to investigate their ideas and interests.

Due to the COVID-19 pandemic and increasing need to teach students online, aquatic scientists are looking for ways to give students field experiences virtually. Asynchronous, self-led field trips are emerging as a solution. However, due to the varying circumstances surrounding students and the dangers of exploring near water alone, asynchronous field trips need to be designed with equity, inclusivity, and safety in mind. Here, I provide a guide to creating inclusive field trips meant to introduce students to making qualitative scientific observations about aquatic ecosystems. This guide for designing an asynchronous, self-led aquatic ecology field trip explains how to: i) gauge whether this type of activity is suitable for your students, ii) promote safety and equity in choosing field trip sites, iii) build a community of learners while in a virtual setting, iv) prepare students for their individual trips, v) create a step-by-step worksheet to lead students through the activity, and vi) improve the experience for future classes.

Primary image: Backyard River: Standing on a bridge looking over the Rillito River flowing through urban Tucson (photo taken by the author).

Undergraduate education and long-term science literacy are enhanced by integrating data projects with public datasets and creating analysis summaries. Underutilized public datasets are often generated by community-based or citizen science projects to address conservation issues supported by local residents. The objectives of this course activity are for students to contribute to a community science project, observe local species diversity, develop biodiversity questions, and apply data science techniques. Engaging students in these local projects enhances their understanding of the scientific process and its broader impacts on their community. The City Nature Challenge (CNC) is an annual global community science event where students participate by documenting species observations with the iNaturalist application, similar to localized BioBlitz events. Students are guided through using the iNaturalist database to practice biodiversity calculations then data is collected through participation in CNC (or a BioBlitz event an instructor arranges for their class). Spreadsheet software is used by students to organize, analyze, and summarize their relevant data to their peers. Students join the iNaturalist community of observers, which includes professional and non-professional naturalists. Therefore, students can see the themselves as scientists by contributing locally relevant data to a global and digital community of scientists. Experience working with large datasets such as the CNC iNaturalist dataset is essential for STEM careers and building data literacy. Implementing these experiences in classrooms will provide students unique opportunities to learn more about local biodiversity, develop interdisciplinary skills and positively influence a global network of scientists.

Primary image: Students recording biodiversity observations in an open field. At the annual Macaulay Honors College BioBlitz, students are divided into teams to explore a specific NYC park and record the animal and plant life they observed, which they later used to generate biodiversity reports including the species richness and abundances for the park.

Scientists have discovered that microplastic pollution is ubiquitous in the environment, but the small size of these microscopic pollutants prohibits most people from recognizing their prevalence. This river-based field lesson will introduce environmental science students to this emerging environmental concern, and encourages them to explore microplastics in their local waterways with sample collection, density separation and field-based microscopy. Students will appreciate the opportunity to connect to this topic from anywhere in the world, allowing them to see microplastics with their own eyes and without the use of sophisticated equipment. In addition, this lesson helps students recognize their own personal impact on microplastic pollution and identify ways to reduce their creation of microplastics.