Key points:
When Senator Bill Cassidy recently questioned whether K–12 systems are adequately preparing students for college-level math, he touched a nerve in the national conversation. We see the symptoms everywhere: rising remediation rates, struggling freshmen, and a growing “readiness gap”–the chasm between student skills and college expectations.
However, if we only look at the gap through the lens of higher education, we are looking at the wrong end of the pipeline. The readiness gap isn’t a failure of student ability; it is a predictable outcome of K–12 systems that aren’t intentionally designed around how students actually learn.
Solving this doesn’t require finger-pointing between colleges and K–12 districts. Instead, it requires us to acknowledge that the readiness gap is a systems design problem. If our foundational instruction is fragmented or misaligned, college readiness will remain elusive.
Much like the science of reading movement required a massive shift in how we prepare educators and invest in professional development, math requires comparable commitment. We must address the reality that many K–6 educators graduate from preparation programs without the deep math content knowledge or pedagogical training needed to foster true mathematicians. To bridge the gap, we must rebuild our systems upon three essential pillars.
Pillar One: Conceptual understanding and procedural fluency–both, not either
In math education, there is often a false dichotomy between conceptual understanding and fluency. This “math war” is counterproductive. To be ready for college, students need both.
Conceptual understanding is knowing why the math works–understanding that addition combines quantities and multiplication represents repeated groups. Fluency, on the other hand, is the ability to accurately and efficiently choose and execute a strategy. While memorization is often treated as a dirty word, it is actually a vital tool for fluency.
Consider a second grader building fluency within 20. Once they understand the concept of base-10, memorizing that 8 + 2 = 10 frees up cognitive space. Without that automaticity, a high school student in Algebra 1 will burn precious mental energy calculating 4 x 3 on their fingers while trying to solve a complex multi-step equation.
When foundational facts are automatic, students can focus on reasoning and modeling. This is the difference between a student who mechanically “borrows” to solve 40-1 and a student who reasons that “one less than 40 is 39.” This flexibility builds a math identity: a sense that they are capable thinkers, not just compliant step-followers.
Pillar Two: Systemic coherence driven by a shared vision
Before we can align a system, we must agree on the goal. Are we trying to produce students who follow instructions, or problem solvers who can reason, model, and critique? Vision must precede design. This need for alignment is a central finding of recent research from Bellwether and K12 Coalition, which emphasizes that schools must agree on a foundational math strategy to boost student performance. Without a shared “North Star,” even the best-intentioned efforts become disjointed and ineffective.
A coherent system aligns three elements: standards, curriculum, and professional learning for teachers and instructional leaders. When these are misaligned, they send an incoherent message to the student. Imagine a student who moves from a second-grade classroom where mistakes are valued and multiple solution paths are welcomed, only to enter a fourth-grade room where instruction is a teacher-directed “I do, we do, you do” procedural model. This fragmentation forces students to reset their understanding of what math is (and whether they themselves understand it or not) every few years.
Coherence also applies to the models we use. If a student uses bar models in K–5, then shifts to entirely different representations in middle school, they lose the logical progression of mathematical language. Schools that move toward a facilitator-led, problem-solving model see more than just improved test scores; they see proficiency rates jump from the mid-70s to near-total mastery. Proficiency and student confidence are not competing goals; they reinforce each other.
Pillar Three: Cumulative learning, not constant resets
Mathematics is inherently cumulative. Decimals build on place value; algebra builds on proportional reasoning. If the foundation is shaky, the later levels will inevitably collapse. Yet many K–12 systems treat each grade level as an island.
When a student struggles, the common reflex is to “reteach the skill” for the current grade. But if a fifth grader doesn’t understand decimals, the root often lies in a misunderstanding of first-grade base-10 concepts. Tools like the Coherence Map from Student Achievement Partners help educators visualize these connections. By identifying prerequisite gaps, teachers can “backfill” strategically rather than just repeating the same grade-level lecture.
To strengthen this pillar, we must prioritize Tier 1 instruction. Many districts over-invest in interventions (Tier 2 and 3) to fix problems that could have been prevented. By strengthening the core classroom experience and honoring the cumulative nature of the subject, we reduce the need for later remediation.
Bridging K–12 and college expectations
Ultimately, colleges must understand that the students they receive are products of a system operating under varied preparation quality and inconsistent curricula. But we cannot wait for the system to fix itself. We must stop treating college readiness as a final checkpoint in the senior year and start treating it as a design principle that begins in kindergarten.
True readiness is not just a standardized test score. It is the ability to reason flexibly, apply efficient strategies, and persist through complex problems. Until our K–12 systems are intentionally structured around conceptual fluency, systemic coherence, and cumulative learning, the pipeline to higher education will continue to leak at the same predictable places.
Beth Zhang, Lavinia Group & Emily Shisler, Bellwether
Beth Zhang is Co-President of Lavinia Group. She partners with school systems to design math instruction that reflects how students learn, fostering deeper understanding and long-term proficiency
Emily Shisler is an Associate Partner with Bellwether on the Academic Program Strategy team. She coaches senior leaders in schools, networks, and districts on strategic planning, instruction, learning acceleration, implementation of high-quality instructional materials, and more
Beth and Emily are both contributing authors of the K12 Coalition and Bellwether report, How We Solve America’s Math Crisis: A Systemwide Approach to Evidence-Based Math Learning.
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