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1. Investigating and improving student understanding of the basics of quantum computing

   https://doi.org/10.1103/PhysRevPhysEducRes.20.020108  

   Hu, Peter; Li, Yangqiuting; Singh, Chandralekha (August 2024, Physical Review Physics Education Research)

   [This paper is part of the Focused Collection in Investigating and Improving Quantum Education through Research.] Quantum information science and engineering (QISE) is a rapidly developing field that leverages the skills of experts from many disciplines to utilize the potential of quantum systems in a variety of applications. It requires talent from a wide variety of traditional fields, including physics, engineering, chemistry, and computer science, to name a few. To prepare students for such opportunities, it is important to give them a strong foundation in the basics of QISE, in which quantum computing plays a central role. In this study, we discuss the development, validation, and evaluation of a Quantum Interactive Learning Tutorial, on the basics and applications of quantum computing. These include an overview of key quantum mechanical concepts relevant to quantum computation (including ways a quantum computer is different from a classical computer), properties of single- and multiqubit systems, and the basics of single-qubit quantum gates. The tutorial uses guided inquiry-based teaching-learning sequences. Its development and validation involved conducting cognitive task analysis from both expert and student perspectives and using common student difficulties as a guide. For example, before engaging with the tutorial, after traditional lecture-based instruction, one reasoning primitive that was common in student responses is that a major difference between an $N$-bit classical and $N$-qubit quantum computer is that various things associated with a number $N$for a classical computer should be replaced with the number $2^N$for a quantum computer (e.g., $2^N$qubits must be initialized and $2^N$bits of information are obtained as the output of the computation on the quantum computer). This type of reasoning primitive also led many students to incorrectly think that there are only $N$distinctly different states available when computation takes place on a classical computer. Research suggests that this type of reasoning primitive has its origins in students learning that quantum computers can provide exponential advantage for certain problems, e.g., Shor’s algorithm for factoring products of large prime numbers, and that the quantum state during the computation can be in a superposition of $2^N$linearly independent states. The inquiry-based learning sequences in the tutorial provide scaffolding support to help students develop a functional understanding. The final version of the validated tutorial was implemented in two distinct courses offered by the physics department with slightly different student populations and broader course goals. Students’ understanding was evaluated after traditional lecture-based instruction on the requisite concepts and again after engaging with the tutorial. We analyze and discuss their improvement in performance on concepts covered in the tutorial. Published by the American Physical Society2024 

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2. Improving student understanding of quantum mechanics underlying the Stern–Gerlach experiment using a research-validated multiple-choice question sequence

   https://doi.org/10.1088/1361-6404/ab2135  

   Justice, Paul; Marshman, Emily; Singh, Chandralekha (July 2019, European Journal of Physics)

   Abstract Engaging students with well-designed multiple-choice questions during class and asking them to discuss their answers with their peers after each student has contemplated the response individually can be an effective evidence-based active-engagement pedagogy in physics courses. Moreover, validated sequences of multiple-choice questions are more likely to help students build a good knowledge structure of physics than individual multiple-choice questions on various topics. Here we discuss a framework to develop robust sequences of multiple-choice questions and then use the framework for the development, validation and implementation of a sequence of multiple-choice questions focusing on helping students learn quantum mechanics via the Stern–Gerlach experiment (SGE) that takes advantage of the guided inquiry-based learning sequences in an interactive tutorial on the same topic. The extensive research in developing and validating the multiple-choice question sequence (MQS) strives to make it effective for students with diverse prior preparation in upper-level undergraduate quantum physics courses. We discuss student performance on assessment task focusing on the SGE after traditional lecture-based instruction versus after engaging with the research-validated MQS administered as clicker questions in which students had the opportunity to discuss their responses with their peers. 

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3. Development, validation and in-class evaluation of a sequence of clicker questions on Larmor precession of spin in quantum mechanics

   https://doi.org/10.1119/perc.2019.pr.Justice  

   Justice, Paul; Marshman, Emily; Singh, Chandralekha (January 2020, Development, validation and in-class evaluation of a sequence of clicker questions on Larmor precession of spin in quantum mechanics)

   Engaging students with well-designed clicker questions is one of the commonly used research-based instructional strategy in physics courses partly because it has a relatively low barrier to implementation. Moreover, validated robust sequences of clicker questions are likely to provide better scaffolding support and guidance to help students build a good knowledge structure of physics than an individual clicker question on a particular topic. Here we discuss the development, validation and in-class implementation of a clicker question sequence (CQS) for helping advanced undergraduate students learn about Larmor precession of spin, which takes advantage of the learning goals and inquiry-based guided learning sequences in a previously validated Quantum Interactive Learning Tutorial (QuILT). The in-class evaluation of the CQS using peer instruction is discussed by comparing upper-level undergraduate students’ performance after traditional lecture-based instruction and after engaging with the CQS. 

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4. THE QUANTUM FOR ALL PROJECT: STUDENT LEARNING IN THE SUMMER CAMPS

   https://doi.org/10.21125/edulearn.2024.1425  

   Matsler, Karen; Lopez, Ramon (July 2024, IATED)

   Quantum information science (QIS) undergirds a set of critical technologies that will affect information security, smart phones, computers, and other widely used technology. There is a broad need to develop a "quantum smart" workforce in addition to traditional STEM fields, and this development needs to occur in precollege education. The US National Science Foundation has funded the Quantum for All project to provide professional development opportunities for STEM educators to learn about QIS and how to implement it in the classroom. The teacher professional development is tied to summer camp experience for students during which the teachers can test their delivery of the material with students in the summer camp. In this paper we will discuss the outcomes for students in the summer camp for the various content areas presented and relate that back to results of research on teachers and their performance in the professional development experience. 

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5. THE QUANTUM FOR ALL PROJECT: RATIONALE AND OVERVIEW

   https://doi.org/10.21125/edulearn.2023.0913  

   Lopez, Ramon; Matsler, Karen (July 2023, https://library.iated.org)

   The future of economic and national security, commerce, and technology are becoming more dependent on quantum information science (QIS). In addition to traditional STEM fields, there will be a broad need to develop a "quantum smart" workforce, and this development needs to begin before college. Since most students will not major in physics, it is vital to expose precollege students to quantum concepts that are relevant to everyday experiences with information security, smart phones, computers, and other widely used technology. This project, funded by the US National Science Foundation, provides opportunities for students to learn about various aspects of quantum science, regardless of whether they take a physics class. This project provides opportunities for secondary educators to learn and practice QIS. Project partners include universities, businesses, and professional organizations such as Science Teacher Association in Utah and Texas, American Association of Physics Teachers, Institute for Quantum Computing, and Perimeter Institute for Theoretical Physics. In particular, we utilize a trainer of trainer approach, however, the teacher professional development is tied to summer camp experience for students during which the teachers can test their delivery of the material with students in the summer camp. In this paper we will discuss the content areas and provide an outline of the professional development model. 

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