The Guide on the Side: Coaching STEM Students in Problem-Solving

From Manager to Mentor: A Practical Strategy for AI Development

As faculty, we know that working effectively with our Assistant Instructors (AIs) is key to a successful course. In last week’s post on Best Practices for Working with Assistant Instructors,” I highlight the importance of mentorship and creating professional development opportunities. But what does that mentorship look like in practice?

One of the most impactful ways to mentor our AIs is to equip them with high-leverage teaching strategies. Instead of just managing their grading, we can teach them how to teach. A powerful approach for this is the Guide on the Side philosophy, which shifts the AI’s role from a simple answer-key to a learning coach.

The Guide on the Side: Coaching STEM Students in Problem-Solving

It’s a familiar scene in any STEM lab or office hour: a student, staring at a screen, is utterly stuck. For new teaching assistants (Associate Instructors, or AIs), the temptation is strong to take the shortcut; to grab the keyboard, write the line of code, or simply provide the answer. But while this solves the immediate problem, it bypasses a crucial learning opportunity.

This is where the Guide on the Side approach comes in. It’s a teaching philosophy that equips new AIs with practical strategies to coach students through the problem-solving process rather than solving problems for them. For faculty in STEM, empowering your AIs with these skills can transform your students’ learning experience. 

Why This Shift in Pedagogy Matters

Across STEM disciplines, students frequently encounter “sticking points” moments of cognitive friction where the path forward isn’t obvious. If an instructor or AI simply hands over the solution, the student leaves with a single answer but no transferable skill. They learn to be dependent on an external expert.

By contrast, an instructor who guides the process models resilience, inquiry, and expert reasoning. The student leaves not only with a solution but with strategies they can apply to the next problem, and the one after that. They learn how to think.

Putting Theory into Practice: Activities for Your AIs

Faculty can use these activities in their own training sessions to help AIs develop a coaching mindset:

  • “Sticking Point” Brainstorm: In a think-pair-share format, AIs identify the most common places their students struggle. This builds a shared awareness of teaching challenges and normalizes the experience.

  • Scenario Analysis: AIs compare two contrasting dialogues: one where the AI gives the answer directly, and another where the AI uses Socratic questioning to lead the student to their own solution.

  • Questioning Roleplay: In pairs, AIs practice how to respond with guiding questions when students make common statements like, “I’m totally lost,” or “Can you just tell me if this is right?”

A Simple Framework for Modeling Expertise

A core strategy of this approach is teaching AIs to make their thinking visible. Experienced problem-solvers naturally follow steps that are often invisible to novices. Encourage your AIs to narrate their own problem-solving process explicitly using a simple four-step framework:

  1. Understand: Restate the problem in your own words. What are the inputs, the desired outputs, and the constraints?

  2. Plan: Outline possible approaches. What tools, algorithms, or libraries might be useful? What are the potential pitfalls of each approach?

  3. Do: Execute the plan step by step, narrating the reasoning behind each action. (“First, I’m going to create a variable to hold the total because I know I’ll need to update it in a loop.”)

  4. Reflect: Test the solution. Does it work for edge cases? Could it be more efficient? Are there alternative ways to solve it? 

This explicit modeling teaches students how to think, not just what to do.

The Power of a Good Question: Building a Question Bank

Guiding questions are the primary tool of a “Guide on the Side.” They skillfully shift the cognitive work back to the student. Encourage your AIs to build a bank of go-to questions, such as:

  • To start a conversation: “What have you tried so far?” or “Can you walk me through your current approach?”

  • To prompt a next step: “What does that error message suggest?” or “What’s the very next small step you could take?”

  • To encourage deeper thinking: “Why did you choose that particular method?” or “What are the trade-offs of doing it that way?”

  • To promote reflection and independence: “How could you check your answer?” or “What would you do if you encountered a similar problem next week?” 

Navigating Common Classroom Challenges

This approach provides concrete strategies for these common moments:

  • When a student is silent: Allow for sufficient wait time. If the silence persists, break the problem down and ask a simpler, first-step question.

  • When a student is frustrated: Acknowledge their feelings (“I can see this is frustrating; these problems are tough.”) and normalize the struggle before gently re-engaging with the task.

  • When a student just wants confirmation: Instead of giving a simple “yes” or “no,” redirect with a metacognitive prompt like, “What makes you confident in that answer?” or “How could you design a test to verify that?”

Resources for a Deeper Dive 

For faculty and AIs who want to explore this pedagogical approach further, these resources are short, impactful, and highly relevant:

  • Book: Small Teaching: Everyday Lessons from the Science of Learning by James M. Lang

  • Article: Asking Questions to Improve Learning – Washington University in St. Louis Center for Teaching and Learning

  • Video: Eric Mazur’s video on Peer Instruction is a great resource for understanding how to shift from traditional lecturing to more active, student-centered learning. He effectively demonstrates the curse of knowledge and how students learning from each other can be more effective than an expert trying to explain something they’ve long ago mastered.
    His approach, where students first think individually, then discuss with peers, and finally re-evaluate their understanding, directly aligns with the principles of guiding students through problem-solving rather than just showing them the answer. It emphasizes active processing and peer teaching, which are crucial for deeper learning and developing independent problem-solvers.

The Takeaway for Faculty

The “Guide on the Side” approach aligns perfectly with evidence-based teaching practices. By encouraging your AIs to slow down, model your thinking, and use questions effectively, you help them grow from being answer keys into becoming true teaching coaches. The result is a more engaged and resilient cohort of students who leave your courses not only with solutions, but with the confidence and strategies to tackle the next challenge independently.

Quick Tip: Name the Thinking (Cognitive Skill), Not Just the Task

Name the Thinking (Cognitive Skill), Not Just the Task

When introducing a problem set, coding lab, or design activity, take 1–2 minutes to make the thinking process explicit. For example:

  • Instead of just saying: “Debug this code”
    Add: “This task is about identifying assumptions in how the code should work versus how it runs. Pay attention to the strategies you use: reading error messages, testing small chunks, or tracing variables.”

  • Instead of just saying: “Sketch a wireframe”
    Add: “This is about perspective-taking; imagining the interface from a novice user’s point of view.”

By naming the cognitive skill (debugging, pattern recognition, abstraction, empathy, systems thinking), students begin to see how their work maps onto the broader competencies of your field.

Why it matters:

  • Supports metacognition (students reflect on how they learn, not just what they learn).

  • Helps novice learners connect class tasks to professional practices.

  • Reinforces disciplinary literacies and makes hidden expectations visi

Integrating metacognitive and student engagement strategies into your practice

The article, How Changes in K-12 Schooling Hampered the Preparation of College Students” Published last month in the Chronicle of Higher Education,  explores how reforms in K-12 education, combined with broader societal changes and disruptions from the COVID-19 pandemic, and teacher shortages have affected the academic habits and preparedness of today’s college students, particularly Generation Z. When examining how test-based accountability has impacted curriculum design, policies such as “No Child Left Behind” have prioritized short-term performance over long-term learning.

Teaching became narrowly focused on test-taking skills, such as answering multiple-choice questions and writing formulaic essays, leaving students unprepared for broader academic tasks. “The [K-12] curriculum has been narrowed to mirror standardized tests. Students work on short passages to develop specific skills. Every class has a lesson, and every lesson has an assessment plan and an outcome. So when students arrive at college, they are conditioned to expect that same level of guidance. Ethan Hutt [an associate professor of education at the University of North Carolina at Chapel Hill], would like to give an assignment that goes like this: Pick a topic, write an essay, and say something interesting. But he finds he can’t — not even with his doctoral students”.

The article argues that, as a result, Students struggle with tasks like reading long texts and writing analytical essays because of a curriculum that favored short passages and responses. The shift away from holistic learning resulted in “atomized” education, where students are conditioned to expect detailed rubrics and granular guidance for assignments. Professors find that students enter college unprepared for the skills that are expected of them. Students often struggle with open-ended assignments, critical thinking, and engaging deeply with academic material. The article concludes that while K-12 reforms and the pandemic have played significant roles in shaping current students’ academic habits, broader systemic and cultural factors must also be addressed. Higher education inherits these challenges and must adapt to better support students’ academic and social transitions.

Based on the content of this article it may be helpful to integrate student engagement and metacognitive practices into first and second year classes such as integrating the Student Engagement Roster into your classroom practice:

SER Roster: The early feedback tool that allows faculty members to communicate with students about how they are doing in a class and make recommendations to improve or deepen their learning. SER also allows instructors to meet two faculty reporting obligations at IUB: Attendance verification and early evaluation grades. More information on those topics is available in the Help and Resources section.

Next week (1/20/2025) Submit SER with Attendance/Participation Feedback for:

  • Anyone not attending

  • Anyone already struggling to turn in work

  • Anyone doing a great job participating

Metacognitive Strategies

 

Think Aloud Exercises:

Anytime you can talk out loud (‘think aloud’) about how you view a document or a picture or programming an assignment, or share your thinking processes with students you are helping them become more metacognitive in their own approaches to the subject.  Once you have modeled for them how you would solve a problem or interpret a piece of writing, have students work in pairs to talk out loud as to how they are thinking about an assignment piece of homework or an assignment.

Concept Mapping: 

Learning benefits can be derived from instructor-led or student-constructed concept maps of the connections and key ideas from a course or class. It is best that the instructor demonstrate how to design a concept map of a class or course before students are asked to do the same. Show students how the readings, videos, assignments and activities are connected to the course learning outcomes and other courses.

Design a brief or detailed concept map of the course or sub-components of the course and share with students. Then later on in course students can form small groups and build a concept map as a review activity before a mid-term or as a review of a portion of the course. Students can do for homework or they can do in class and share with each other explaining the interrelationships between each component. Ask the students to draw all the ‘cross-links’ and label them as they see the components connecting fully or partially.

Guided Notes

Guided notes are structured outlines provided by an instructor that include key concepts, ideas, or topics, with spaces for students to fill in additional information during the lecture or while engaging with course content.

  • Lecture Notes: An instructor provides an outline of the lecture with prompts for students to add definitions, examples, or connections.

  • Reading Notes: A guided framework for analyzing a reading or resource, directing students’ attention to specific questions or themes.

  • Problem-Solving Frameworks: In mathematics or sciences, guided notes might include partial steps of a problem-solving process, leaving students to complete the solution.

This technique aligns with various teaching strategies, including scaffolding and universal design for learning (UDL), as it helps to bridge the gap between independent learning and instructor support.

More strategies and resources available here.

Strategies to Help Struggling Students Turn It Around

The following tips were adapted from materials developed by Doug Holton, PhD. They are intended to help faculty support students at the midpoint of the semester who are struggling in class:

Integrating Retrieval Practice into classroom instruction

Retrieval practice is one of the most effective methods of learning and remembering information for long-term use. During retrieval practice, students “retrieve” what they know about a topic or lesson out of their memory. Retrieval practice requires effort on the part of the student to recall specific information, which is beneficial to improving learning and strengthening students’ memory. Retrieval practice can be “…a no-stakes learning opportunity that increases student performance, beyond formative and summative assessments” (Agarwal & Bain, 2019, p.4).

In general, giving students multiple opportunities for practice and retrieval will break up a lecture with short brain breaks and prove valuable in the effective learning process. If we can work these methods into our instruction and teach students how to use them on their own, our students stand a much better chance of actually remembering our material (Gonzalez).

Effective Learning and Studying Strategies Examples adapted from ASEE:

Spaced practice and interleaving

  • Spaced practice: Study material over longer, spaced intervals instead of cramming. For example, review material a day after class and then again a few days later, and so on.

  • Interleaving: Mix your practice of different subjects or skills together. For instance, instead of doing all your math problems in one go, mix problems from different chapters to improve your ability to switch between concepts. 

Jot Recall (Oakley, et al., 2021, p. 12-13)

  • Students check understanding of concept by recalling information without aids.

  • Promotes retrieval and spaced repetition to reinforce long-term memory.

  • Can be used in class or out of class as a study technique.

  • Pause and have students use a blank piece of paper to recall concepts by writing notes or making a drawing

  • Have students compare and discuss within a small group

Retrieval practice and elaboration

  • Retrieval practice: Actively recall information from memory rather than just rereading notes. This can be done by testing yourself with practice questions or by explaining concepts aloud in your own words.

  • Elaboration: Expand on new information by asking questions and connecting it to what you already know. For example, relate new theories to real-life situations or stories. 

Notetaking (Oakley, et al., 2021, pp. 25, 30-31)

  • Students are offered handouts or outlines of lecture materials to assist with notetaking.

  • Helps students actively engage with class material, instead of struggling to make sense of content and take notes at the same time.

  • Provides better studying references.

Scaffolding (Alber, 2011 and “Scaffolding,” n.d.)

  • Students move incrementally (via ‘scaffolds’) towards a deeper understanding of material.

  • Allows students to gradually build understanding.

  • Consider that students come to your classroom with varying backgrounds, experiences, and abilities.

Varied Practice (Oakley,, et al., 2021, p. 7)

  • Incorporating opportunities for students to practice what they’re learning in different ways and contexts.

  • Helps students consolidate material.

  • Aids long-term memory.

Other effective strategies

  • Dual coding: Combine words with visuals. Create concept maps, diagrams, or sketches to represent information, which can lead to a deeper understanding.

  • Concrete examples: Think of specific examples and non-examples to clarify the meaning of a concept.

  • Teach others: Explaining a concept to someone else is a powerful way to solidify your own understanding.

  • Elaboration: Students take the time to ask themselves complex and open-ended questions about the content they are learning or studying. This improves learning and goes beyond simple recall of information.