A New Model of 4-H Volunteer Development in Science, Engineering, and Technology Programs

New initiatives centered on science, engineering, and technology (SET) in 4-H may be moving away from the long-established adult volunteer delivery model. This shift in delivery may be due to a lack of availability of adult volunteers who possess the necessary SET competencies to effectively lead 4-H clubs. One way to offset this trend may be to blend traditional face-to-face training with continuous training efforts that include asynchronous on-line training modules, synchronous Web-based meetings, and self-directed learning. This new 4-H SET Volunteer Competencies Training Model is being tested in the Nebraska 4-H Robotics and GPS/GIS program

A New Model of 4-H Volunteer Development in Science, Engineering, and Technology Programs

New initiatives centered on science, engineering, and technology (SET) in 4-H may be moving away from the long-established adult volunteer delivery model. This shift in delivery may be due to a lack of availability of adult volunteers who possess the necessary SET competencies to effectively lead 4-H clubs. One way to offset this trend may be to blend traditional face-to-face training with continuous training efforts that include asynchronous on-line training modules, synchronous Web-based meetings, and self-directed learning. This new 4-H SET Volunteer Competencies Training Model is being tested in the Nebraska 4-H Robotics and GPS/GIS program

Examining 4-H Robotics and Geospatial Technologies in the Learning of Science, Technology, Engineering, and Mathematics Topics

The study reported here investigated the use of educational robotics, paired with GPS and GIS geospatial technologies, as a context for learning selected concepts in science, technology, engineering, and mathematics within a 4-H camp setting. The study involved 38 students between the ages of 11 to 15. A pretest-posttest quasi-experimental design was used in the study, with a 29-question multiple-choice instrument targeting various academic topics. The results of the study suggest that the 4-H robotics and geospatial summer camp program is a promising approach for supporting STEM-related learning, as represented by a significant increase of means from pretest to posttest

Examining 4-H Robotics in the Learning of Science, Engineering and Technology Topics and the Related Student Attitudes

Youths’ natural fascination and identification with robots make them an ideal teaching and learning platform. Robots would seem to be excellent hands-on tools to teach science, engineering and technology (SET) concepts. However, while research supports their use to increase interest and motivation, the effectiveness of robots to directly teach science, engineering, and technology concepts is less clear. The purpose of this study was to measure the effectiveness of a 4-H robotics program to support the learning of specific SET concepts and to examine related student attitudes towards science. This study compared the pretest and posttest scores on an assessment of basic SET concepts and attitudes of youth who participated in the 4-H robotics intervention with the scores of youth in a control group. Analysis of covariance (ANCOVA) results revealed that youth in the robotics intervention scored better on a SET concepts posttest. Student attitudes toward science were also investigated. The results suggested that educational robotics can engage youth in activities that support their learning of SET topics, but that it may have more limited impact on general student attitudes towards science, as measured by the study\u27s attitudinal instrument

Impact of Robotics and Geospatial Technology Interventions on Youth STEM Learning and Attitudes

This study examined the impact of robotics and geospatial technologies interventions on middle school youth’s learning of and attitudes toward science, technology, engineering, and mathematics (STEM). Two interventions were tested. The first was a 40-hour intensive robotics/GPS/GIS summer camp; the second was a 3-hour event modeled on the camp experiences and intended to provide an introduction to these technologies. Results showed that the longer intervention led to significantly greater learning than a control group not receiving the instruction, whereas the short-term intervention primarily impacted youth attitude and motivation. Although the short-term intervention did not have the learning advantages of a more intensive robotics camp, it can serve a key role in getting youth excited about technology and encouraging them to seek out additional opportunities to explore topics in greater detail, which can result in improved learning

Pairing Educational Robotics with Geospatial Technologies in Informal Learning Environments

Educational robotics, when paired with geospatial technologies and taught in an informal educational environment, can be an innovative strategy to teach youth about science, technology, engineering, and mathematic (STEM) concepts. However, little is known about the true effects on conceptual knowledge and associated attitudes. Therefore, this study was conducted to examine the shortterm effects of a series of five-day summer robotics/geospatial camps held in Nebraska. The study was conducted at six diverse locations and consisted of a five-day 4-H camp experience. The study examined the experiences of 147 youth between the ages of 10 and 15. A pretestposttest quasi-experimental design was used in the study. Instrumentation consisted of a 37-question multiple-choice assessment targeting various STEM topics and a 38-question attitude questionnaire assessing STEM interests and attitudes. Results suggest that the 4-H robotics and geospatial summer camp program is a promising approach for supporting STEM-related learning and enhancing attitudes towards STEM. Introductio

The Use of Robotics, GPS and GIS Technologies to Encourage STEM-Oriented Learning in Youth

In our technology rich world, the educational areas of science, technology, engineering, and mathematics (STEM) play an increasingly essential role in developing well-prepared specialists for the 21st century workplace. Unfortunately, interest in theses areas has been declining for a few decades. Various innovative educational initiatives in formal and informal learning environments have been undertaken nationally to attempt to encourage STEM-oriented learning. Funded by the National Science Foundation, the particular program described in this paper focuses on middle school youth in non-formal learning environments. The program integrates educational robotics, Global Positioning System (GPS) and geographic information system (GIS) technologies to provide educational experiences through summer camps, 4-H clubs and afterschool programs. The project’s impact was assessed in terms of: a) youth learning of computer programming, mathematics, geospatial concepts, and engineering/robotics concepts and b) youth attitudes and motivation towards STEM-related disciplines. An increase in robotics/GPS/GIS learning questionnaire scores and a stronger self-efficacy in relevant STEM areas have been found through a set of project-related assessment instruments

Robots, GPS/GIS, and Programming Technologies: The Power of Digital Manipulatives in Youth Extension Experiences

The study reported here examined the effectiveness of educational robotics combined with GPS/GIS technologies used as digital manipulatives in the teaching of concepts in science, engineering, and technology. Based on the success of previous summer camps, the study also examined a scaling-up of the intervention from 38 participants to 147. The 147 youth (ages 10-15) participated in one of six summer camps held in Nebraska during 2008. Results indicate that participants scored higher on the content posttest than the pretest. The study further examined the differential results. The article makes recommendations for further studies, while acknowledging the potential power of digital manipulatives

Concern, Conflict, and Chaos: Nebraska Educator Experiences during the Pandemic

During the spring of 2020, Nebraska’s 983 public schools sat vacant, and Nebraska’s 329,290 Pre-Kindergarten to Grade 12 students were learning in environments other than school. Educators were expected to pivot quickly from traditional classroom instruction to remote experiences. Understanding the effects of the pandemic on educators is necessary to effectively meet their needs and the needs of students. The purpose of this study was to identify and describe the experiences of Nebraska’s urban and rural PreK–Grade 12 educators during the early stages of the COVID-19 pandemic. In surveys collected in July 2020, participants (i.e., superintendents, principals, and teachers) completed both fixed-response items and one open-ended question that assessed experiences during the initial pandemic-related school closings. The results indicate educators identified lack of family help and inability to engage students as a top concern about student academic progress. Educators reported dramatic increases in stress during school closures. Many reported coping only somewhat well or worse. Educators also reported personal challenges with remote instruction, including mental health issues and blurred work-and home-life boundaries. Significant differences were found between rural and urban educators, as well as between elementary and secondary educators. Direct quotes from participants vividly describe their lived experiences

Examining 4-H Robotics in the Learning of Science, Engineering and Technology Topics and the Related Student Attitudes

Youths’ natural fascination and identification with robots make them an ideal teaching and learning platform. Robots would seem to be excellent hands-on tools to teach science, engineering and technology (SET) concepts. However, while research supports their use to increase interest and motivation, the effectiveness of robots to directly teach science, engineering, and technology concepts is less clear. The purpose of this study was to measure the effectiveness of a 4-H robotics program to support the learning of specific SET concepts and to examine related student attitudes towards science. This study compared the pretest and posttest scores on an assessment of basic SET concepts and attitudes of youth who participated in the 4-H robotics intervention with the scores of youth in a control group. Analysis of covariance (ANCOVA) results revealed that youth in the robotics intervention scored better on a SET concepts posttest. Student attitudes toward science were also investigated. The results suggested that educational robotics can engage youth in activities that support their learning of SET topics, but that it may have more limited impact on general student attitudes towards science, as measured by the study's attitudinal instrument