Schools are failing to identify high-ability science students, research shows
Their research is laid out in a chapter in the Handbook of Giftedness and Talent Development in the Asia-Pacific.
“We were surprised to find that PAT English and Mathematics tests were one of the key ways high-ability science students were identified,” says Dr Moeed, pointing out not all high-ability science students have skills that transfer to other subjects.
Dr Moeed, from the University’s Wellington Faculty of Education, has been teaching and researching science in New Zealand schools for 40 years, and she and Dr Horsley’s research into the identification of high-academic-ability science students was inspired by Professor Sir Paul Callaghan’s call for innovation many years ago.
The world’s collective response to COVID-19 has relied on top scientists and proves our need to have the best thinkers, says Dr Moeed. “We need those who can think in new ways about the old and new issues we face in our everyday lives, for us to be able to live a satisfying life.”
Other countries have similar issues in identifying high-ability students—some using testing to identify them, others using teacher observations of student’s learning behaviours. And this gap exists in primary school education as well.
“We do not have equitable science teaching and learning in primary schools,” says Dr Moeed, “This is often because the primary teachers are generalists and some don’t feel confident to teach science. An unintended consequence of focus on literacy and numeracy in the early 2000s was less time for teacher education in science.”
The academics have also found research into the experience of high-ability science students in New Zealand’s small towns is scarce. Although those in cities can participate in science fairs, or visit the local university and access lecturers, who can support those who reach out to them, those in small towns aren’t so lucky.
“In my experience in New Zealand, we are very good at coming up with solutions on a local basis. But identification and provision for equitable access of science education to all high-ability students is needed,” says Dr Moeed.
High-academic-ability students involved in the study, run with several top teachers, said they wanted their teachers to engage them in more practical work that challenges them to think, and helps them understand how science is done and scientific knowledge is created and validated.
“Our science curriculum lecturers model how to generate an interest in and enthusiasm for science through engaging in practical work and science investigation—engagement in science needs to be both hands-on and mind-on.”
Primary principals have recently asked the Ministry of Education for more support in providing teachers with better professional development in science and mathematics—including a request to bring back the science advisers that existed to support teachers during the 1990s and 2000s.
New Zealand has produced some great leaders in science, and the opportunity to engage in and learn and excel in science is a reasonable expectation of science education in New Zealand, says Dr Moeed.
“We need scientifically literate citizens, but we also need our future science leaders to be identified, nurtured, and taught so they develop a nuanced understanding of how scientific knowledge is created.”