Teaching and Assessing Science Process Skills in Physics: THE “BUBBLES” TASK

In the following article, Dr. Seuss's children's books are creatively integrated with science activities through the creation of take-home activity kits. The kits provide families an opportunity to read at home while connecting the enjoyable experience to science content and skill development through associated activities. The kits should be constructed using easy-reading books and aligned to developmentally appropriate academic science standards. Most importantly, they should be designed in a manner so that all family members are participants rather than expecting the adults to teach the expected outcomes. The activity kits can be completed as stand-alone experiences for interested students, used by students who are ready for an additional challenge, or adapted for an entire classroom of students as part of a teacher's normal curriculum.     

Teaching Evolution Concepts to Early Elementary School Students

State and national standards call for teaching evolution concepts as early as kindergarten, which provides motivation to continue developing science instruction and curriculum for young learners. The importance of addressing students’ folk theories regarding science justifies teaching evolution early in K-12 education. In this project, we developed, implemented, and researched standards-based lessons to teach elements of evolution (speciation and adaption) to kindergarteners and second graders. Our lessons attended to the students’ prior knowledge, and utilized inquiry and modeling to teach and assess their ability to recognize patterns of similarity and differences among organisms. Using their products and comments as evidence, it was apparent the students were able to communicate recognition of patterns and effectively apply their knowledge in near transfer activities, indicating they achieved our learning objectives. This provides support for teaching evolution concepts in the early grades and evidence of the ability for young children to effectively engage in supported inquiry and modeling for learning science.     

Improving the public understanding of science: New initiatives

The United States may be on the brink of losing its global edge in science. Many American students are underprepared for and uninterested in the scientific and technical careers they may be asked to take on. Furthermore, these students, their teachers, and the broader public lack basic understandings of what science is and how it works, which may negatively impact their ability to make reasoned and informed decisions about science-related issues. We describe two unique and recently developed projects designed to help tackle these problems by improving public understanding of and interest in science. The Coalition on the Public Understanding of Science is a grassroots effort to lower the barriers between the scientific community and the public. It aims to inspire broad appreciation of science, inform the public about the nature and process of science, and make science accessible to everyone. Understanding Science is a web-based project that aims to improve teacher understanding of the nature of the scientific enterprise, to provide resources that encourage and enable kindergarten through undergraduate (K-16) teachers to reinforce the nature of science throughout their teaching, and to serve as a clear and accessible reference that accurately portrays the scientific endeavor. The botanical and broader scientific communities are invited to participate in these efforts.     

A Missing Link: K-4 Biological Evolution Content Standards

The National Science Education Standards (NSES) is one of the most influential documents in US science education. The NSES has been utilized by local schools and districts, state departments of education, and national curriculum groups to form the backbone for curriculum frameworks, programs, and assessment systems to guide science education. The NSES provides national biological evolution content standards for fifth grade through high school but not for kindergarten through fourth grade. This article presents K-4 biological evolution content standards that can be used in conjunction with the current NSES K-4 life science and earth science content standards, brief examples of integration activities using the K-4 biological evolution content standards, and supplemental teacher information for the K-4 biological evolution content standards. The biological evolution content standards and the additional materials can guide teachers when teaching biological evolution to K-4th grade students.     

Paint and Paper Creations

This article investigates generalist kindergarten teachers’ academic music training based on data collected from students undertaking an undergraduate degree in preschool (kindergarten) education (students aged 4–6 years) in Greece. The study was carried out through a questionnaire survey that addressed students’ aspirations when entering the university and the real learning outcomes by the end of their studies. This article seeks to find relationships between students’ academic experiences and their level of confidence and enthusiasm to teach music in kindergarten. The findings suggest that higher education provides students with most of the learning outcomes that they anticipate. However, students lack adequate practical experiences in terms of observing lessons in real educational settings, which can significantly affect their confidence levels. Finally, the author explores some implications for higher education policy and teaching practice.     

The Capture: Kidnapping Students’ Interests Using the Guardians of Ga’Hoole

This project describes a fourth-grade unit that integrated science and language arts using the book The Capture as a focal point. During the unit, students engaged in science activities and language arts lessons that focused on owls. Students conducted investigations that helped them develop a deeper understanding of the adaptations of several owl species. Additionally, the fourth-graders developed their language arts skills for conducting research, using figurative language, and presenting information. Examples of helpful resources and student work are included.     

The Pleasures and the Pitfalls of Plant Science Activities

The topic of wetlands provides a rich context for curriculum integration. This unit contains seven activities that integrate environmental science with math, technology, social studies, language arts, and other disciplines. In this series, students will identify plants and animals found in wetlands, understand the function of wetlands through the use of models, learn some of the effects of human behavior on wetland preservation, and use problem-solving skills to develop solutions to wetland loss.     

Using Amphibians and Reptiles to learn the Process of Science

The National Research Council's document, Inquiry and the National Science Education Standards (2000) describes an elementary science classroom as one that is composed of learners who are engaged in scientific processes. In such a setting, children ask real-world questions and seek real-world solutions. As students pursue their inquiries, they often move away from science textbooks, and they implement mathematical skills, read literature, conduct research in electronic databases, write stories, and so forth in a larger context. What was originally a regular science lesson becomes an opportunity for integration across the curriculum. This article describes an integrated unit on bats and specifically addresses the National Science Education Standards.     

Not Looking a Gift Horse in the Mouth: Exploring the Merits of a Student–Teacher–Scientist Partnership

One major emphasis of reform initiatives in science education is the importance of extended inquiry experiences for students through authentic collaborations with scientists. As such, unique partnerships have started to emerge between science and education in an ongoing effort to capture the interest and imaginations of students as they make sense of the world around them. One such partnership is called the student–teacher–scientist partnership, in which teachers and their students participate in and contribute to the research of scientists. This article explores a partnership between a 10th-grade biology teacher, her students, and practicing scientists who collaborated in the design, implementation and evaluation of a horse evolution unit. The primary goal of the collaborative activity was to involve teachers and students in a process of conceptual change as a means of eliminating common misconceptions implicit in horse evolution displays in museums in various parts of the country. The evidence-based lessons developed enhanced students’ understanding of concepts in macroevolution but also connected the science classroom with a community of scientists whose personalization of the horse evolution unit situated biological concepts and the learning experience within the context of real-world issues.     

Swinging into art with pendulum paintings

Children are captivated with how things work and they like to build things and in many ways, engineering comes naturally for them. Progress does not come from technology alone but from the melding of technology and creative thinking through art and design. There has been a push for STEAM-based curricula to be included in science classrooms and the Next Generation Science Standards (NGSS) provides the framework for integrating engineering design into the structure of science education. The push for the STEAM platform is derived from the lack of creativity and innovation in recent college graduates in the United States. This STEAM-based unit meshes engineering design, representing and interpreting data, visual arts, and motion/stability. As students investigated and analyzed pendulum motion, they also created unique pendulum paintings. Throughout this unit our students applied their content knowledge across several disciplines and in turn allowed them to gain a better understanding and retention of these concepts. Through creating their own pendulum paintings, the students learned about pendulums and how they work, designed and constructed their own pendulums, and applied prior knowledge of forces and motion in a controlled experiment.     

Science Classroom Inquiry (SCI) Simulations: A Novel Method to Scaffold Science Learning

Science education is progressively more focused on employing inquiry-based learning methods in the classroom and increasing scientific literacy among students. However, due to time and resource constraints, many classroom science activities and laboratory experiments focus on simple inquiry, with a step-by-step approach to reach predetermined outcomes. The science classroom inquiry (SCI) simulations were designed to give students real life, authentic science experiences within the confines of a typical classroom. The SCI simulations allow students to engage with a science problem in a meaningful, inquiry-based manner. Three discrete SCI simulations were created as website applications for use with middle school and high school students. For each simulation, students were tasked with solving a scientific problem through investigation and hypothesis testing. After completion of the simulation, 67% of students reported a change in how they perceived authentic science practices, specifically related to the complex and dynamic nature of scientific research and how scientists approach problems. Moreover, 80% of the students who did not report a change in how they viewed the practice of science indicated that the simulation confirmed or strengthened their prior understanding. Additionally, we found a statistically significant positive correlation between students’ self-reported changes in understanding of authentic science practices and the degree to which each simulation benefitted learning. Since SCI simulations were effective in promoting both student learning and student understanding of authentic science practices with both middle and high school students, we propose that SCI simulations are a valuable and versatile technology that can be used to educate and inspire a wide range of science students on the real-world complexities inherent in scientific study.     

Incorporating Argumentation through Forensic Science

This article outlines how to incorporate argumentation into a forensic science unit using a mock trial. Practical details of the mock trial include: (1) a method of scaffolding students’ development of their argument for the trial, (2) a clearly outlined set of expectations for students during the planning and implementation of the mock trial, and (3) an example of how to use questioning to guide students through the planning of the mock trial. While a general forensic science unit is provided in the article, a teacher can use the details of the mock trial with any forensic science unit for either middle school or secondary science students.     

Connecting ecology to daily life: how students and teachers relate food webs to the food they eat

This study used sociocultural learning theory to better understand how middle and high school environmental science and biology students and pre- and in-service science teachers connect the daily life activity of eating to the food web model learned in school. We sought to understand how student and teacher perceptions of the environment and their experiences influenced their responses to interview questions regarding this topic. Findings, based on transcribed interviews with 54 study participants, indicate that three quarters of teachers and students were unable to connect the food they eat with ecosystem food webs. Even so, many respondents particularly those from elite public schools, did not demonstrate common food web misconceptions identified by other researchers, instead showing a sophisticated understanding of food web interactions. These findings indicate that even though participants were proficient in their school science understanding of food web interactions, they did not readily think about how their everyday out of school activities, like eating, relate to those interactions. This may be representative of a more general disconnect between formal ecology instruction and daily life activities. We provide several recommendations for how this disconnect can be remedied in our classrooms.     

Undergraduate student attitudes and perceptions toward low- and high-level inquiry exercise physiology teaching laboratory experiences

The purpose of this investigation was to compare student attitudes toward two different science laboratory learning experiences, specifically, traditional, cookbook-style, low-inquiry level (LL) activities and a high-inquiry level (HL) investigative project. In addition, we sought to measure and compare students' science-related attitudes and attitudes toward science. Students participated in 5 wk of LL activities followed by a 5-wk HL project. An open-ended survey administered at the end of the semester and analyzed by a χ(2)-test revealed that 1) students enjoyed the HL project more than the LL activities, 2) high-level inquiry did not have a negative effect on student motivation in the laboratory, and 3) students perceived that they learned more about physiology principles with the LL activities. Most students liked the HL project, particularly the independence, responsibility, freedom, and personal relevance. Of the students who did not like the HL project, many reported being uncomfortable with the lack of structure and guidance. Many students gained a more positive and realistic view about scientific research, often reporting an increased respect for science. Likert scale surveys administered before and after each 5-wk period showed no significant changes in student attitudes to scientific inquiry, adoption of scientific attitudes, enjoyment of science lessons, or motivation toward science when the three time points were compared. The findings in this study have helped to provide suggestions for better implementation of HL projects in the future.     

All Aboard! The Polar Express Is Traveling to Science—Understanding the States of Matter while Differentiating Instruction for Young Learners

This standards-based science lesson introduces young learners to scientific inquiry and critical thinking by using activities to demonstrate three phases of matter (solid, liquid, and gas). By learning about the states of matter through a 5E instructional approach, students are encouraged to observe changes in the states of matter and to discuss their understanding in both small and large group forums. Student participants will be involved in hands-on activities along with small and large group discourse while actively learning about the states of matter and enjoying a hot chocolate demonstration with sampling. Developmentally appropriate instructional approaches are emphasized throughout this lesson.     

Signal transduction in the carnivorous plant Sarracenia purpurea. Regulation of secretory hydrolase expression during development and in response to resources.

Carnivory in plants has developed as an evolutionary adaptation to nutrient-poor environments. A significant investment of the resources of a carnivorous plant is committed to producing the traps, attractants, and digestive enzymes needed for the carnivory. The cost:benefit ratio of carnivory can be improved by either maximizing the prey capture rate or by reducing the metabolic commitment toward carnivory. Using the pitcher plant Sarracenia purpurea, we have investigated whether the expression of the hydrolytic enzymes needed for digestion is regulated in response to the presence of prey. Expression of protease, RNase, nuclease, and phosphatase activities could be induced in the fluid of nonactive traps by the addition of nucleic acids, protein, or reduced nitrogen, suggesting that hydrolase expression is induced upon perception of the appropriate chemical signal. Hydrolase expression was also developmentally controlled since expression commenced upon opening of a trap, increased for several days, and in the absence of prey largely ceased within 2 weeks. Nevertheless, the traps remained competent to induce expression in response to the appropriate signals. These data suggest that in young traps hydrolase expression is developmentally regulated, which is later replaced by a signal transduction mechanism, and they demonstrate the ability of a carnivorous species to respond to the availability of resources.     

Setting the stage: developmental biology in pre-college classrooms

Exercises that employ dynamic living material have proved highly successful at generating interest in science among young students. Developing embryos and larvae are especially well suited for such endeavors, for they can be handled without expensive or elaborate equipment, and their changing nature engages students. Using amphibian embryos, which are relatively large and exhibit profound, easily observed morphological changes, and amphibian larvae, which are easily kept and observed, captures the attention of children. By designing inquiry-based exercises and focused discussion sessions, a high intellectual content can be integrated into these endeavors. The long-term implications for generating an informed citizenry, improving the participation of women in science, and empowering elementary school teachers are profound. Professional developmental biology researchers should feel encouraged to participate in these types of activities.     

Muggles,Wizards, and Witches Using Harry Potter Characters to Teach Human Pedigrees

These activities allow students to investigate behavioral responses of the large Milkweed bug, Oncopeltus fasciatus, and the mealworm, Tenebrio molitor or Tenebrio obscurus, to external stimuli of light, color, and temperature. During the activities, students formulate hypotheses to research questions presented. They also observe insects for a period of time, record observations, analyze the data, and draw conclusions. Important outcomes include experience with critical and analytical thinking and appreciation for the process of science as well as the biology of living things. The activities described herein are appropriate for upper elementary grades, middle school, and high school biology classes.     

Infrared Photography

Although literacy plays a large role in elementary science classrooms, one thing that offers a challenge for educators is meeting the linguistic needs of English language learners (ELLs) while also meeting their content needs. An additional challenge is ensuring that academic literacy extends beyond the classroom. This article presents ways of extending classroom literacy into the home. The suggestions and activities emphasize literacy strategies appropriate for ELLs as well as English-speaking students.     

Hypothesis testing as a laboratory exercise: a simple analysis of human walking,with a physiological surprise

This paper describes a laboratory exercise designed to provide students with experience testing a hypothesis by systematically isolating and controlling determinant variables. The study involves an analysis of walking and is performed by the students on a subject from within their lab group. The study requires use of a motorized treadmill, tape measure, stop watch, metronome, personal cassette player, and calculator. The exercise is designed to include factors that the students are familiar with, so they can focus on the isolation of variables without being confused about the process they are investigating. However, the exercise will not turn out as the students anticipate, meaning they will be forced to reevaluate the assumptions that formed the basis of their original hypothesis. This exercise is designed for a college-level course in exercise science, physiology, or biology but could easily be managed by a high school honors class with appropriate guidance.