Over the last year we have been able to take a few hours each week to step back from our current work, reflect on our assumptions, learn from others, and explore new ways that our research could both uncover and help dismantle inequities and racism in the STEM education system. This eBook, and the series of blog posts on which it is based, is the result of these conversations and this reflective process. Our goal is to explore the themes and ideas that emerged from the year and how these might fundamentally change the way we think about STEM, work with families and children, and conduct
A practical guide containing descriptions of 11 Tinkering activities for adult learners. It can be used by community development and informal learning practitioners working with adult groups. Some of the activities were newly developed while others were adjusted from already existing and tested activities. Special focus is given to activities suitable for adults from different backgrounds, taking into account different needs, interests and motivations. This publication is a product of Tinkering EU: Addressing the Adults, funded with support from the Erasmus+ Programme of the European Union.
This document is aimed primarily at Informal Learning (IFL) educators working with adult learners from disadvantaged and underserved communities, who wish to:
exploit the inclusive nature of Tinkering to create engaging and relevant STEM learning experiences for adult learners and their families
better understand how and why collaboration and co-design with community organisations can help develop more inclusive programming in STEM learning for adults.
It can also serve as a useful reference for community leaders and adult educators wishing to collaborate with the IFL sector
Tinkering is an approach to learning increasingly adopted within informal learning settings to engage people with STEM learning (science, technology, engineering and mathematics). It builds on ideas in inquiry-based pedagogy and exploits some of the most engaging and motivational elements of learner-centered, immersive and hands-on learning approaches to develop 21st century skills such as critical thinking, creativity, collaboration, problem solving, communication, responsibility, self-confidence, digital literacy and entrepreneurship. In a Tinkering activity, the learner is presented with
Engaging with Tinkering is a highly stimulating and complex experience and invites rich reflections from museum practitioners and teachers. "Tinkering as an inclusive approach for building STEM identity and supporting students facing disadvantage or with low science capital” presents the reflective practice process and tools designed by the "Tinkering EU: Building Science Capital for All" project aiming to understand in more depth the potential impact of using a Tinkering approach with students facing disadvantage. Using tools specifically designed to help teachers observe their students
This report, from the "Tinkering EU: Building Science Capital for All" project, provides a theoretical rationale for understanding the relationship between Tinkering as a pedagogical approach, students’ individual science capital, and inclusive STEM teaching approaches. By exploring the relationship between these three areas, it invites professionals to reflect on the ways in which Tinkering can be used a teaching tool for building science capital.
“Tinkering EU: Building Science Capital for All” aims to develop activities and resources that support a learner-centred culture, improve science education and develop 21st century skills - all of which are fundamental for active citizenship, employability, and social inclusion. To do this, it adopts ‘Tinkering’, an innovative pedagogy developed in the USA, which is used by museums, and has proven able to create a lifelong engagement with science for everyone. Tinkering works particularly well for people who argue that “they are not good at science” or are disaffected from any formal teaching and learning process. It can be a powerful tool to tackle disadvantage. The project integrates Tinkering into the school curriculum to develop the science capital of disadvantaged youth through the use of museums. It addresses students from 8 to 14 years old (primary and junior high schools).
Coordinator: National Museum of Science and Technology Leonardo da Vinci
Partners:
University of Cambridge – UK
NEMO Science Museum – The Netherlands
Science Gallery Dublin – Ireland
CosmoCaixa – Spain
Science Center Network – Austria
NOESIS – Greece
As the maker movement is increasingly adopted into K-12 schools, students are developing new competences in exploration and fabrication technologies. This study assesses learning with these technologies in K-12 makerspaces and FabLabs.
Our study describes the iterative process of developing an assessment instrument for this new technological literacy, the Exploration and Fabrication Technologies Instrument, and presents findings from implementations at five schools in three countries. Our index is generalizable and psychometrically sound, and permits comparison between student confidence
DATE:
TEAM MEMBERS:
Paulo BliksteinZaza KabayadondoAndrew P. MartinDeborah A. Fields
This study explored the effect of depth of learning (as measured in hours) on creativity, curiosity, persistence and self-efficacy. We engaged ~900 parents and 900 students across 21 sites in Washington, Chicago, Los Angeles, New York, Alabama, Virginia and the United Arab Emirates, in 5-week (10-hr) Curiosity Machine programs. Iridescent trained partners to implement the programs. Thus, this analysis was also trying to establish a baseline to measure any loss in impact from scaling our programs and moving to a “train-the-trainer” model. We analyzed 769 surveys out of which 126 were paired. On
The FIRST Longitudinal Study is a multi-year longitudinal study assessing the impacts of FIRST’s afterschool robotics programs on the STEM related interests and educational and career trajectories of program participants. FIRST is one of the nation’s largest after-school robotics programs, serving more than 460,000 youth aged 6-18 annually through the FIRST LEGO League (Ages 7-14), the FIRST Tech Challenge (grades 7-12) and the FIRST Robotics Competition (grades 9-12). The study is tracking over 1200 program participants and comparison students, using a quasi-experimental design, over a
DATE:
TEAM MEMBERS:
Alan MelchiorCathy BurackMatthew HooverJill Marcus