Faculty members face unique challenges and issues in conducting successful research with undergraduates in STEM fields. How to Get Started in STEM Research with Undergraduates discusses ways to deal with issues such as setting up and managing a research laboratory, designing student research projects, working with administrators, seeking research grants, writing successful grant proposals, integrating research into the classroom, dealing with information management, and making optimal use of the primary literature. Designed for faculty in the early years of teaching, the publication also can assist administrators as they consider elements for research success and institutional expectations for faculty. The appendix lists research agencies that fund undergraduate research.
There are over 20 million young people of color in the United States whose representation in STEM education pathways and in the STEM workforce is still far below their numbers in the general population. Their participation could help re-establish the United States' preeminence in STEM innovation and productivity, while also increasing the number of well-educated STEM workers. There are nearly 700 minority-serving institutions (MSIs) that provide pathways to STEM educational success and workforce readiness for millions of students of colorâ€"and do so in a mission-driven and intentional manner. They vary substantially in their origins, missions, student demographics, and levels of institutional selectivity. But in general, their service to the nation provides a gateway to higher education and the workforce, particularly for underrepresented students of color and those from low-income and first-generation to college backgrounds. The challenge for the nation is how to capitalize on the unique strengths and attributes of these institutions and to equip them with the resources, exceptional faculty talent, and vital infrastructure needed to educate and train an increasingly critical portion of current and future generations of scientists, engineers, and health professionals. Minority Serving Institutions examines the nation's MSIs and identifies promising programs and effective strategies that have the highest potential return on investment for the nation by increasing the quantity and quality MSI STEM graduates. This study also provides critical information and perspective about the importance of MSIs to other stakeholders in the nation's system of higher education and the organizations that support them.
The work of teachers is not just to teach. We are also responsible for the basic needs of students. Helping students eat and live, and also helping them find the tools they need to reflect on the present moment. This is exactly in keeping with Paulo Freire's insistence that critical pedagogy be focused on helping students read their world; but more and more, we must together reckon with that world. Teaching must be an act of imagination, hope, and possibility. Education must be a practice done with hearts as much as heads, with hands as much as books. Care has to be at the center of this work.For the past ten years, Hybrid Pedagogy has worked to help craft a theory of teaching and learning in and around digital spaces, not by imagining what that work might look like, but by doing, asking after, changing, and doing again. Since 2011, Hybrid Pedagogy has published over 400 articles from more than 200 authors focused in and around the emerging field of critical digital pedagogy. A selection of those articles are gathered here. This is the first peer-reviewed publication centered on the theory and practice of critical digital pedagogy. The collection represents a wide cross-section of both academic and non-academic culture and features articles by women, Black people, indigenous people, Chicanx and Latinx writers, disabled people, queer people, and other underrepresented populations. The goal is to provide evidence for the extraordinary work being done by teachers, librarians, instructional designers, graduate students, technologists, and more - work which advances the study and the praxis of critical digital pedagogy.
Nearly 40 percent of the students entering 2- and 4-year postsecondary institutions indicated their intention to major in science, technology, engineering, and mathematics (STEM) in 2012. But the barriers to students realizing their ambitions are reflected in the fact that about half of those with the intention to earn a STEM bachelor's degree and more than two-thirds intending to earn a STEM associate's degree fail to earn these degrees 4 to 6 years after their initial enrollment. Many of those who do obtain a degree take longer than the advertised length of the programs, thus raising the cost of their education. Are the STEM educational pathways any less efficient than for other fields of study? How might the losses be "stemmed" and greater efficiencies realized? These questions and others are at the heart of this study. Barriers and Opportunities for 2-Year and 4-Year STEM Degrees reviews research on the roles that people, processes, and institutions play in 2-and 4-year STEM degree production. This study pays special attention to the factors that influence students' decisions to enter, stay in, or leave STEM majorsâ€"quality of instruction, grading policies, course sequences, undergraduate learning environments, student supports, co-curricular activities, students' general academic preparedness and competence in science, family background, and governmental and institutional policies that affect STEM educational pathways. Because many students do not take the traditional 4-year path to a STEM undergraduate degree, Barriers and Opportunities describes several other common pathways and also reviews what happens to those who do not complete the journey to a degree. This book describes the major changes in student demographics; how students, view, value, and utilize programs of higher education; and how institutions can adapt to support successful student outcomes. In doing so, Barriers and Opportunities questions whether definitions and characteristics of what constitutes success in STEM should change. As this book explores these issues, it identifies where further research is needed to build a system that works for all students who aspire to STEM degrees. The conclusions of this report lay out the steps that faculty, STEM departments, colleges and universities, professional societies, and others can take to improve STEM education for all students interested in a STEM degree.
Science, technology, engineering, and mathematics (STEM) are cultural achievements that reflect our humanity, power our economy, and constitute fundamental aspects of our lives as citizens, consumers, parents, and members of the workforce. Providing all students with access to quality education in the STEM disciplines is important to our nation's competitiveness. However, it is challenging to identify the most successful schools and approaches in the STEM disciplines because success is defined in many ways and can occur in many different types of schools and settings. In addition, it is difficult to determine whether the success of a school's students is caused by actions the school takes or simply related to the population of students in the school. Successful K-12 STEM Education defines a framework for understanding "success" in K-12 STEM education. The book focuses its analysis on the science and mathematics parts of STEM and outlines criteria for identifying effective STEM schools and programs. Because a school's success should be defined by and measured relative to its goals, the book identifies three important goals that share certain elements, including learning STEM content and practices, developing positive dispositions toward STEM, and preparing students to be lifelong learners. A successful STEM program would increase the number of students who ultimately pursue advanced degrees and careers in STEM fields, enhance the STEM-capable workforce, and boost STEM literacy for all students. It is also critical to broaden the participation of women and minorities in STEM fields. Successful K-12 STEM Education examines the vast landscape of K-12 STEM education by considering different school models, highlighting research on effective STEM education practices, and identifying some conditions that promote and limit school- and student-level success in STEM. The book also looks at where further work is needed to develop appropriate data sources. The book will serve as a guide to policy makers; decision makers at the school and district levels; local, state, and federal government agencies; curriculum developers; educators; and parent and education advocacy groups.
How do you create effective STEM classrooms that energize students, help them grow into creative thinkers and collaborators, and prepare them for their futures? This practical book from expert Anne Jolly has all the answers and tools you need to get started or enhance your current program. Based on the author’s popular MiddleWeb blog of the same name, STEM by Design reveals the secrets to successful lessons in which students use science, math, and technology to solve real-world engineering design problems. You’ll learn how to: Select and adapt quality existing STEM lessons that present authentic problems, allow for creative approaches, and engage students in meaningful teamwork; Create your own student-centered STEM lessons based on the Engineering Design Process; Assess students’ understanding of basic STEM concepts, their problem-solving abilities, and their level of engagement with the material; Teach STEM in after-school programs to further build on concepts covered in class; Empower girls to aspire to careers in STEM and break down the barriers of gender bias; Tap into STEM's project-based learning style to attract and engage all students. Throughout this user-friendly book, you’ll find design tools such as checklists, activities, and assessments to aid you in developing or adapting STEM lessons. These tools, as well as additional teacher resources, are also available as free downloads from the book’s website, http://www.stem-by-design.com.
In order for the United States to maintain the global leadership and competitiveness in science and technology that are critical to achieving national goals, we must invest in research, encourage innovation, and grow a strong and talented science and technology workforce. Expanding Underrepresented Minority Participation explores the role of diversity in the science, technology, engineering and mathematics (STEM) workforce and its value in keeping America innovative and competitive. According to the book, the U.S. labor market is projected to grow faster in science and engineering than in any other sector in the coming years, making minority participation in STEM education at all levels a national priority. Expanding Underrepresented Minority Participation analyzes the rate of change and the challenges the nation currently faces in developing a strong and diverse workforce. Although minorities are the fastest growing segment of the population, they are underrepresented in the fields of science and engineering. Historically, there has been a strong connection between increasing educational attainment in the United States and the growth in and global leadership of the economy. Expanding Underrepresented Minority Participation suggests that the federal government, industry, and post-secondary institutions work collaboratively with K-12 schools and school systems to increase minority access to and demand for post-secondary STEM education and technical training. The book also identifies best practices and offers a comprehensive road map for increasing involvement of underrepresented minorities and improving the quality of their education. It offers recommendations that focus on academic and social support, institutional roles, teacher preparation, affordability and program development.
For students whose experience with science has been primarily in the classroom, it can be difficult to identify and contact potential mentors, and to navigate the transition to a one-on-one, mentor-student relationship. This is especially true for those who are new to research, or who belong to groups that are underrepresented in research. The Entering Research curriculum offers a mechanism to structure the independent research experience, and help students overcome these challenges.
"For undergraduates in STEMM fields, the experience of working in a lab or other research position has become an increasingly important credential for many career paths. Landing such a position can be difficult, with hundreds of applicants for perhaps a dozen openings in the most competitive cases. But finding a meaningful research experience also involves knowing what to look for and how to present yourself effectively, skills that represent a hidden curriculum for many students. In this book, an expert lab manager and a longtime principal investigator share their secrets for securing these positions, both in summer undergraduate research programs and in labs operating during the academic year. They offer advice on the application and interview processes for undergraduates who often do not know how to prepare appropriately professional emails, cover letters, CVs, and interview responses. They address students in a wide variety of STEMM fields at both research-intensive universities and primarily undergraduate institutions. And they focus on how first-generation college students and those from low-income backgrounds and communities historically underrepresented in science can learn to negotiate the hidden curriculum and claim their place in research settings. This new edition also serves as a companion to the authors' social accounts, including @YouInTheLab and @TheLabMentor, where they offer advice on lab life at many levels"--
A comprehensive resource for high school teachers and students, STEM Student Research Handbook outlines the various stages of large- scale research projects, enabling teachers to coach their students through the research process.
