When asked to name scientists, students mention the likes of Charles Darwin, Albert Einstein, and Isaac Newton. And when asked to draw a scientist, students almost always draw a white man holding a test tube and wearing a lab coat. Professor Robin Costello from the University at Buffalo tells us more about a new study that parsed the effects of including visual depictions and humanizing information about scientists featured in undergraduate biology course materials.

This post was originally released by The Royal Society, here.

How students think of scientists reflects the false narrative that only certain types of people can be scientists – specifically white men with brilliant minds.

One powerful tool to combat this false narrative is to feature relatable, contemporary scientists whose identities do not match the dominant stereotype of a scientist featured in course materials. To highlight counter-stereotypical scientists, instructors can implement course materials that include photographs of scientists in their lecture slide decks. Or instructors can highlight humanizing information about scientists in their course materials. Sharing information such as the barriers scientists have faced or how they overcame obstacles in STEM may help students relate to scientists and envision their own STEM careers.

In our latest study, we parsed the effects of including visual depictions and humanizing information about scientists featured in undergraduate biology course materials with a large-scale research study. Over several academic terms and 36 undergraduate institutions in the United States, we distributed three versions of short quantitative activities (Data Nuggets) that varied in their level of information about the featured scientists (from including only their names and pronouns to full Project Biodiversify scientist profiles).

Data from over 3,700 students revealed that including humanizing information about scientists improves student engagement with quantitative biology activities. Photos of the scientists alone were not enough to improve student engagement. Instead, when provided information about the scientists’ life experiences, students found the activities more interesting, more relevant to their future careers, and put more effort into the activities. Our data suggests this pattern was driven by increased relatability of the featured scientists. 

While these results applied to all students, the strongest impacts were evident among students who shared excluded identities with the featured scientists.Our findings underscore the importance of providing students with examples of relatable scientists in STEM courses, rather than simply adding photos to increase representation. By highlighting humanizing information about scientists, instructors can both increase student engagement in their courses and improve equity in STEM.

We recommend several evidence-based resources to use in biology courses, including the Data Nuggets and Project Biodiversify materials studied here (together, DataVersify), as well as Scientist Spotlights, BioGrapI, and the Story Collider Podcast.

When the days grow shorter and the landscape is blanketed in snow, it might seem like nature has gone dormant. Trees stand bare, ponds freeze over, and many animals disappear from sight. But winter is a critical time for many species. Researchers brave the cold to study how organisms survive and even thrive in winter’s harsh conditions.

For many species, winter isn’t an obstacle—it’s a necessity. Some organisms have evolved incredible adaptations to endure the cold. Insects use snow as an insulating blanket and even plants rely on winter conditions, with some seeds requiring a cold period before they can sprout.

But winter isn’t what it used to be; Climate change is altering seasonal patterns, leading to shorter, warmer winters. These changes disrupt the delicate balance that many species depend on. Snow cover is disappearing earlier, and fluctuating temperatures cause unpredictable freeze-thaw cycles, which can be harmful to plants and animals alike.

Postdoctoral researcher associate Rosemary Martin (Rosie) studies how cold temperatures affect the development of organisms, particularly dragonfly larvae. These larvae spend their early lives underwater before emerging as winged adults, and rather than hibernating in winter, they remain active. Understanding how temperatures shape their development is crucial, especially as climate change alters seasonal temperature patterns.

To investigate this, Rosie and her colleagues conduct lab experiments with six species of dragonflies. They expose them to different pre-winter temperatures before placing them in bio chambers at 4°C—mimicking the temperature of water beneath the ice. By measuring metabolic rates and analyzing fat and protein levels, they aim to uncover how different pre-winter conditions influence their health and survival. If larvae grow faster or slower due to higher pre-winter temperatures, it could impact the entire food web, from the predators that rely on dragonflies to the insects they eat.

“They actually stay active through the winter,” Rosie explains. “You can imagine how having built up resources—and still burning through them during the winter—affects their body condition in the spring. That’s what we’re trying to understand.”

Despite the cold temperatures, Rosie notes that “this is the part that I enjoy the most. […] Part of the reason I got into winter ecology is because I wanted an excuse to get outside into the field all year round.” Winter ecology does come with its unique challenges though. It is often understudied as it doesn’t line up with the usual academic schedule. “There’s also the danger of working on ice,” Rosie mentioned, “especially during the shoulder seasons when it’s less stable. And, of course, a lot of people just don’t think about winter as a biologically active season. […] But in these mid-latitude to high-latitude environments it is obviously a really impactful environmental filter.”

One surprising fact Rosie often shares is that many people don’t realize dragonflies have an aquatic stage at all. “First, I have to explain that, and then I get to the fact that they’re active through the winter—which surprises not just the general public but even some ecologists.”

A Data Nugget on Rosie’s research will be published shortly! 

Getting Students Involved in Winter Science

For educators or students interested in exploring winter science, Rosie offers creative ideas. “If you have access to a refrigerator—and don’t mind keeping live insects in there—it can serve as a great proxy for an aquatic winter environment at 4°C,” she suggests. A mini bio chamber with LED lights and a timer can simulate winter conditions.

For those exploring the outdoors, Rosie recommends digging under the snow to examine leaf litter insects. “Try warming them up and see how long it takes for them to resume activity—that can give you insights into their overwintering strategies!” Other ideas include observing animal tracks, studying winter-active birds, and comparing how different types of trees handle the cold.

Bringing Winter Science to Your Classroom With Data Nuggets

Winter offers countless opportunities to engage students in real-world science. Data Nuggets provides resources to explore seasonal changes, including lessons on:

• How road salt affects freshwater ecosystems
• The importance of snow cover for insect survival 
• How climate change is shifting winter conditions
• How animals adapt to survive freezing temperatures

These lessons use real data collected by scientists, allowing students to analyze patterns and draw their own conclusions. By bringing winter science into the classroom, you can help students see that research doesn’t stop when the temperature drops—it simply takes on a new form.

So, this winter, bundle up and explore the science happening all around you! Whether it’s tracking animal footprints in the snow, investigating how ice forms, or analyzing real-world data, there’s no shortage of discoveries waiting to be made.

External Links: 

Life under the Ice

Dragonfly larvae