An exciting research project, for example with an unusual
field component, presents a unique opportunity for education and public
engagement (EPE). The adventure aspect of the fieldwork and the drive and
creativity of the researchers can combine to produce effective, novel EPE
approaches. Engagement with schools, in particular, can have a profound
impact, showing the students how science works in practice, encouraging them
to study science, and broadening their career perspectives. The project
SEA-SEIS (Structure, Evolution And Seismicity of the Irish offshore,
STEM subjects are recognized by a large majority of people in Ireland as essential for the country's prosperity (SFI, 2015). Yet, most people are not comfortable with STEM, perceiving the subjects as too specialized. Careers in STEM and, specifically, Earth science do not appear attractive to most school students, in large part due to the lack of information on and exposure to them (Neenan and Roche, 2016). Among specific sections of the public and school students, women's and girls' interest in STEM and careers in STEM is still relatively low, and students in disadvantaged areas have insufficient resources and role models to motivate their interest in STEM (SFI, 2015).
These barriers to STEM engagement are not unique to Ireland (e.g. Tytler et al., 2008), although in Ireland, in particular, the public interest in science and the pride in the national achievements in science have long been well below those for the arts (Ahlstrom, 2019). The world-class research performed in Ireland today in many areas of science is something the country can be proud of and inspired by, adding to the public interest in STEM in the long term. In a more immediate and direct sense, however, research projects themselves and the researchers who work on them represent a rich resource for education and public engagement (EPE).
Getting involved in an ongoing research project offers an appealing gateway to STEM to both school students and adults. Interactions with researchers reveal them to the public as friendly, “normal” people, enthusiastic about their jobs. These interactions are effective in alleviating the common stereotype of scientists as isolated, aloof and focussed on obscure or highly specialized experiments. The exposure to real researchers can thus increase the students' interest in STEM and in careers in STEM.
In this paper, we present, as a case study, an EPE programme developed around a major research project. Started by researchers, the programme grew to include school teachers as co-creators and expanded to the national scale. We describe the best practice developed in the course of the programme, draw lessons from its development, discuss some general inferences, and aim to identify useful templates and recipes for EPE projects that connect researchers to school students and to the general public.
About 90 % of the Irish territory is offshore, most of it to the west of Ireland. Beneath the ocean, spectacular mountains and deep valleys show elevation variations of up to 3–4 km. There are extinct volcanoes, with remarkable biodiversity on their slopes. Ireland's largest sedimentary basins are also here, as are its greatest natural hazards: undersea slope failures have caused tsunamis in the geologically recent past (e.g. Salmanidou et al., 2017; Georgiopoulou et al., 2019).
In the project SEA-SEIS (Structure, Evolution And Seismicity of the Irish
offshore), Earth scientists from the Dublin Institute for Advanced Studies
(DIAS) are investigating the dynamic processes within the Earth that have
shaped the seafloor and caused intraplate volcanic eruptions in the Irish
offshore and the broader Northeast Atlantic (Lebedev et al., 2018, 2019a, b;
Steinberger et al., 2019). In order to
investigate the structure and flow of the rock within the Earth's crust and
mantle, 18 seismic stations have been installed at the bottom of the North
Atlantic Ocean. The ocean-bottom seismometers were deployed from the RV
This major project represents the first successful attempt to instrument a large area of the Atlantic Ocean with ocean-bottom seismometers. It is particularly significant for Ireland, an island with extensive coastlines and a special place for the sea in its culture and history. In addition to its pioneering science, the project also features state-of-the-art technology: the compact, ocean-bottom seismometers can withstand the enormous pressure at the bottom of the ocean while recording its tiniest vibrations, as small as nanometres in amplitude.
The 2018 SEA-SEIS expedition covered over 5000 km in 18 d in the North Atlantic Ocean. Its main purpose was to install the 18 ocean-bottom seismic stations. It also offered spectacular EPE opportunities and provided a focus for the EPE programme that we have developed.
Scientists onboard included the chief scientist (Sergei Lebedev) and seismology (Raffaele Bonadio, Janneke I. de Laat, Clara Gómez-García) and geology (Laura Bérdi) PhD students. The team also included the engineer who had led the development of the ocean-bottom seismometers (Arne Schwenk) and an expert technician from DIAS (Mick Smyth). It also included a journalist and digital media expert (Daniel Farrell) and a sound artist (David Stalling). The diversity of the team was its key strength. All the members joined forces in the technical and EPE work, which came across clearly to school audiences onshore.
The programme was initiated by researchers, motivated by exploratory conversations with school teachers that indicated that it would be useful and in demand. The activities were funded primarily by small amounts from research-project budgets.
Starting with the realization that the North Atlantic expedition was simply
too good an EPE opportunity to be missed, the programme grew and expanded
through contributions from researchers and other members of the team onboard
the RV
We reviewed best practices of previous EPE projects connected to active research and looked for any ideas that could be applicable to ours. Teacher–scientist collaboration aiming to promote hands-on, inquiry-based science teaching is, generally, an established approach. In seismology, specifically, the Princeton Earth Physics Project (PEPP) installed seismometers in schools across the US for use in teaching and in science projects (Nolet, 1993; Steinberg et al., 2000; Phinney, 2002), and a number of seismology-in-schools programmes operate elsewhere around the world (e.g. Bullen, 1998; Virieux, 2000; Blake et al., 2008; Denton, 2008; Courboulex et al., 2012; Balfour et al., 2014; Zollo et al., 2014; Tataru et al., 2016). Collaborative teacher–scientist research projects improve, on the one hand, the scientists' awareness of classroom practices and, on the other hand, the teachers' understanding of scientific research, exposing each group to the other's culture and highlighting the advantages of integrating scientific inquiry into the curriculum (Gosselin et al., 2003). In the joint scientist–teacher–student research projects, the participants particularly enjoy being part of authentic research in which they could take initiative and feel a sense of ownership (Jarrett and Burnley, 2003). Scientist–educator partnerships can produce new teacher resources and lesson plans, incorporating cutting-edge research (Madden et al., 2007).
Recent trends in Earth-science outreach (e.g. Drake et al., 2014; Tong, 2014) include the use of video projects in the science classroom (Dengg et al., 2014; Wade and Courtney, 2014) and storytelling via diverse media (Barrett et al., 2014; Moloney and Unger, 2014). Hut et al. (2016) reviewed the theory of effective geoscience communication through audio-visual media, with a particular focus on television, and identified six major themes and challenges: scientist motivation, target audience, narratives and storytelling, jargon and information transfer, relationship between scientists and journalists, and stereotypes of scientists among the general public. Live video has already been used extensively in the practice of EPE coupled with marine research: ship-to-shore video events have been performed for a number of years by the International Ocean Discovery Program (IODP) (Kulhanek et al., 2014; IODP, 2019). We were able to use the idea successfully in our programme, with a specific focus on ship-to-classroom video link-ups and with our own event templates (Sect. 3.2).
McAuliffe et al. (2018) reported on the creation of a science book for 7–12 year olds. The book showcased the importance of STEM in today's society and aimed to give the children their first conceptions of STEM career pathways. Importantly, children were co-creators in the content development, character design, and “try at home” activities offered in the book. As a result, 93 % of parents of participating children felt that the children became more interested in science than they were before. The Irish research examples used in the book were also found to shift the perception that major scientific discoveries could only take place abroad (McAuliffe et al., 2018).
Further insight into the state of the art in the relevant EPE practice can be gained through direct communication with the practitioners. Contacting and talking to a lot of people – teachers, researchers, EPE and communications experts – was of key importance in the development of the present programme. Best practical ideas and essential partnerships emerged from some of these discussions.
Shortly before the start of the North Atlantic expedition, a press release
on the project was circulated by DIAS through a PR company (Alice PR). This
triggered broad coverage of the project in the national media
(
The seismologists among us have a natural tendency to give their seismic stations names like S01, S02, S03, etc. This is, indeed, how our offshore sites were referred to at the experiment design stage, when we determined the locations for the seismometers.
Then, just over 2 weeks before the expedition, we announced a secondary-school competition to name our seismometers. Two weeks is a short time for a teacher who may meet their science or geography class only once a week. Having more time for the competition would have been beneficial as more classes would be likely to participate. However, this was not possible as the expedition started shortly after the beginning of the academic year.
The competition was advertised through the email list of the Irish secondary school principals. To kick it off, we proposed the first name, Brian, ourselves. This was after Brian Jacob (Senior Professor of Geophysics at DIAS, 1989–2001), who led the work on the continental nature of the basins west of Ireland, which resulted in the Irish territory increasing by about a factor of 10.
A total of 20 schools – 19 across Ireland and 1 in Italy – participated in
the competition. Our appeal for help in an important research project has
generated genuine enthusiasm in students and got them engaged with the
project. The teachers used this to have discussions on geoscience and marine
science, as well as Irish and international Earth scientists and explorers.
Among the winning names
(
Some teachers used the competition to talk with their students about the sea in Irish history and culture. Allód was named for the ancient Irish god of the sea, and Gráinne – for Gráinne Ni Mhaille, the “Pirate Queen”, the well-known, 16th-century lord of the Ó Máille dynasty in the west of Ireland. Yet another approach was to let the students' imagination roam free, giving us names like Eve (for “eavesdropping on the Earth”), Gill, and Loch Ness Mometer.
Most schools proposed multiple names, and some names were proposed by more than once school. The SEA-SEIS researchers at DIAS selected and announced the winning names prior to the start of the expedition. Apart from the merit of the names themselves, an additional consideration was to have as many schools as possible among the winners. With some winning names proposed more than once, all the schools that submitted entries by the deadline were among the winners. The students in participating classes – now well engaged with the project – were particularly interested in how their seismometer would do. Most winning classes then participated in the live video links to the ship during the expedition, and the students were keen to see the videos and photos of the deployment of the seismometer that they had named.
Live ship-to-shore video links had been performed in international EPE
programmes before ours, in particular by the International Ocean Discovery
Program (IODP) using RV
Live, ship-to-classroom video link-ups started with a brief introduction of the project and the team and continued with a 20–70 min Q&A session.
Following IODP, we started the video link-ups with an introduction from the
ship that set the stage for a question and answer session with the students
in the classroom. In contrast to the IODP video events, which, with rare
exceptions, are led by educators (Kulhanek et al., 2014), all our video
links were led by PhD students onboard. We also had to develop our own
template for live video events. Because the weather during our expedition
was mostly stormy – which is often the case in the North Atlantic, – the
initially planned live tours of the ship, as performed on RV
With the Marine Institute's assistance, we had secured, in advance and at an
additional cost, a dedicated satellite broadband connection from the ship.
Following RV
After the introduction to the project, the science, and the team, the students were invited to ask questions (Fig. 2). Prior to the video link, they were asked by their teachers to think of some. Most questions that were asked related to the life on the ship, to the project (its goals, hypotheses and methods), to Earth science (earthquakes, volcanoes, tsunamis and other natural hazards; plate tectonics and dynamics of the Earth interior), to the equipment (how it works and how it was developed), to what scientists do in their jobs, and to how one becomes a scientist. The Q&A sessions lasted between 20 and 70 min, depending on how much time the classes had and on our schedule.
Live, ship-to-classroom video link-ups with different schools in Ireland and Italy.
Because of the limited number of video link-ups that could realistically be performed, invitations were sent only to the participants of the seismometer-naming competition (20, over half of them then requesting a slot) and to the members of the Irish Seismology in Schools network (Blake et al., 2008), operated by DIAS (45, a few of them requesting a slot). We were able to schedule and perform a video link with every teacher who asked for one.
In total, 18 video link-ups were carried out. The classes were in schools
all around Ireland, and there was one connection to a school in
Italy – reported on by a regional TV station (
Most presenters on the ship and at DIAS were female. This offered opportunities to all-girl classes and girls in co-educational schools to connect to and identify with their own role models among the scientists.
Both female and male students were clearly excited to chat with scientists and engineers on a ship in the middle of the North Atlantic. According to the teachers, their students would then tell the entire school as well as their parents of this experience, which further broadened the reach of the event. “It was like speaking to Indiana Jones!” was how the students of Lycée Français d'Irlande, Dublin, summarized it.
Some teachers used the engagement with researchers to accompany special Earth science projects, conducted prior to the video link (Fig. 3). Other teachers spent only one or two periods on the video link and the discussions before and after it. Given the already packed curricula, this flexibility was useful and appreciated by the teachers. The video links provided a “low-cost, high-impact” activity, inspiring the students and encouraging their interest in STEM and STEM careers but not putting excessive strain on the teachers' schedules.
The SEA-SEIS Drawing Competition for Primary Schools ran from October to
December 2018. It was advertised on the SEA-SEIS website and in
We invited the students to draw one of our friendly, adventurous seismometers. Noting the primary school children's concern for the seismometers (Will they be scared at the bottom of the sea, all alone?), we made sure that the competition announcement mentioned that diving deep into the sea was the seismometers' favourite thing to do. The announced evaluation criteria included relevance, artistic merit, and originality.
We received nearly 70 entries in total
(
Because this was a primary-school competition, we awarded a prize to every student who sent us a drawing. The prize was the 2019–2020 SEA-SEIS Calendar, featuring the art by the students (Fig. 4). Every drawing was printed in the calendar, with the ones ranked highest by the SEA-SEIS researcher jury printed on a full page, and the others a few per page.
Participants of the Primary School Drawing Competition
with their prizes, calendars featuring their art.
The feedback from the participating teachers and students indicated that the competition was enjoyable and increased the students' interest in STEM (see Sect. 4). The number of schools who entered, however, was relatively small. This was, in part, because primary schools already have their own art competitions and may feel they are already busy enough with those. In order to increase the participation in the future, it will be useful to communicate to schools more explicitly how the competition can raise the students' interest in STEM and also mention that every valid entry will win a prize, which we had not done in this case.
The SEA-SEIS Song and Rap Competition for Secondary Schools ran from October to December 2018. It was advertised on the SEA-SEIS website and through teacher networks. We invited the students to compose and record a song or a rap on a topic related to seismology, the SEA-SEIS Expedition, Earth science, or exploration of the interior of the Earth. For information, we directed the students to the project website, to video link-ups with the ship if their class participated, and to further reading. Entries from entire classes or smaller groups of students were accepted. The evaluation criteria included relevance, scientific insight and accuracy, artistic merit, and originality.
The competition received excellent entries – creative, imaginative,
artistic, and with a variety of original takes on Earth science and
seismology at sea (
Prizes and some of the winners of the geoscience
song-and-rap competition for secondary schools.
One of the teacher authors of this paper (Céline Tirel) offered the production of a competition entry as a graded Technology project to one of her classes. This was a successful and effective approach, with the production of an entry comprising research on the science, creation of the piece, recording, and preparation of a report.
It was clear from the entries that many students made an effort to research the subject and learn more of the science. Others, however, seemed less interested to learn, and some succeeded in creating impressive entries in spite of that. At one end of the spectrum, one of the winning compositions referred to most SEA-SEIS seismometers by their names, also with a reference to their location and to what they were recording on the seafloor, which showed substantial research on the subject. At the other end, some of the entries showed little understanding and probably no research behind them.
Drawing a line separating “research” from “no research”, however, would be difficult. The competition was developed in order to combine art and science, to get the students to create science-themed art and to get them more interested in science. The pieces the students composed and recorded were free-form, and there were no correct answers they could insert into in their songs. For this reason, it is not possible to gauge precisely the amount of research students put into Earth-science research in the course of this activity.
By the very nature of the art–science approach, it is not always possible to measure everything. We do draw a lesson from the first edition of this competition, however: in its future editions, it will be useful to steer students more firmly towards learning and towards communicating science and technology in their pieces.
The study complied with the
Formal evaluations were conducted after all ship-to-classroom video link-ups, using a SurveyMonkey online survey. The survey was anonymous by default, but the names of the school and the teacher could be given as an option. All teachers that we contacted right after the video link, on the same day, responded and completed the evaluation form. Of those contacted 3 d after the video link (once, the ship lost the internet connection over an entire weekend), half did not respond.
Overall, the teachers rated the educational activity at 4.7 out of 5, on average. Eighty-six percent reported that the video link encouraged the students' interest in science, with 14 % reporting “somewhat encouraged” and none reporting “did not encourage”. The respondents also reported that the video links triggered the students' curiosity, showed them that science is part of real life, highlighted the importance of collaborating and broadened their career ideas. Getting to know scientists as “open, friendly people” impressed the students. For the classes who had participated in the seismometer-naming competition, the main highlight was, invariably, seeing the deployment of the seismometer they had named.
The evaluation relating to the drawing competition was informal, based on the feedback from the primary school teachers and students themselves. The bulk of the feedback came in the form of 24 thank-you cards from 7–8-year-old students from Abbeyleix South National School, County Laois, Ireland. It was clear that the children were encouraged to write the cards by their teacher and that the teacher must have mentioned a number of things that could be included in the cards. However, different children opted to include different things in their text, and the phrasing was their own, different in different cards. Nearly all the students wrote that they enjoyed learning about the seismometers and the project, with some mentioning explicitly that they explained what they had learned to their parents. All were pleased with their prizes and happy that everybody got a prize. Some wrote that they would like to work with the SEA-SEIS researchers in the future.
This evidence would not yield robust statistical inferences (only one class, influenced by their teacher) but, even though the evidence may be regarded as anecdotal, we consider it encouraging and useful. It confirms that young primary school students are curious about and receptive to the general ideas of Earth science research and that rewarding every participant with a prize is an effective approach in primary-school competitions. It also highlights the key role of an actively participating teacher and the importance of a teacher network in order for such a competition to reach a broad, national scale.
In this section, we focus on the lessons and recipes provided by our EPE programme. We discuss the approaches shown to be particularly important and useful. We also point out what did not work as expected and why. In addition, we consider potential next steps towards an expanded, sustainable EPE programme coupled with Earth-science research projects.
Academic researchers are a source of essential STEM expertise. They also possess genuine enthusiasm for science. Their potential capacity for EPE resource development and EPE activities is remarkable: scientists are creative and resourceful, and they have excellent technical and computer skills. The researchers' motivation to participate in STEM activities, however, is not universally high, for a number of reasons. The incentive structures (assessment criteria) at academic institutions prioritize research, published in top journals of the field, as well as service to the institutions, including administration and teaching (Lam, 2011; Hillier et al., 2019). In informal networks of international researchers, achievements in research are also prioritized. Outreach work can be dismissed by a colleague with a quick “Ah, it's not science”. Misguided as this may be, most researchers have heard this, and the opinion of the community of peers affects not only their self-esteem but also their employment and funding opportunities.
For the academics still keen to develop EPE activities, allocating time for this can be difficult, especially if this is unrelated to any of their current research projects. Also, even though most funding agencies encourage EPE, they often do not provide any funds for it in regular research grants.
Researchers thus tend to leave EPE development to outreach specialists and participate in the activities occasionally. They are often used as presenters in pre-designed EPE activities, which gives them opportunities for improving their communication skills (e.g. Illingworth et al., 2018) – often not their greatest strength to begin with. However, consistently using researchers for what many of them do not particularly enjoy or excel at does not, obviously, get the best out of them, pushing some away altogether.
EPE coupled with active research projects can channel the academic researchers' drive and creativity into the development of spectacular, novel EPE programmes. Not all research projects are equally suitable for this, and smaller projects may lack the scale and personnel. A certain proportion of research projects, however, will always present excellent opportunities for the development of effective EPE programmes, led by scientists or by scientists and educators together. Projects with an exciting field component, in particular, easily capture the imagination of school students and engage them, as illustrated by the SEA-SEIS and a number of other EPE programmes (e.g. Kulhanek et al., 2014; IODP, 2019).
Our programme benefited greatly from its integration of practitioners from
different disciplines. The team that developed ideas, produced digital
content, and conducted the EPE activities included Earth scientists,
engineers and technicians, secondary school teachers, a journalist, and a
sound artist. Our teachers (Céline Tirel and Brendan O'Donoghue) made key contributions to the
development of classroom-activity ideas, from the early stages of the
programme planning. Our journalist and media expert (Daniel Farrell) had participated in the
programme development since before the expedition and produced a popular
blog that covered the expedition, also professionally maintaining the
project's digital media presence, increasingly recognized as essential in
science communication (Drake et al., 2014). Together with our sound artist
(David Stalling), they shot and edited onboard the project-introduction and
tour-of-the-ship videos. The sound artist, whose primary work using the
sounds recorded on the ship will be presented in a month-long show as part
of a major international festival, made sure we were all heard during the
video links, even outside in strong winds. The engineers and technicians
(Arne Schwenk, Mick Smyth, Louise Collins) presented and explained with authority the technology aspect of
the project. All the team members onboard the RV
School students were invited to help scientists and made a real contribution to the project. Their names for the ocean-bottom stations (Fig. 1) have permanently replaced the tentative S01, S02, etc. After the data are collected, these names (abbreviated when required) will remain attached indefinitely to seismograms in international data repositories. In our two art competitions, the participants produced pieces that are now themselves effective tools for education and public engagement.
We found that inviting students to become co-creators gets them engaged with enthusiasm. They are, then, motivated to learn more on the project, the scientific hypotheses behind it, and what the scientists do in the course of the project. Even though the students do not perform any of the project's key technical tasks, co-creation does help to get across the excitement and creative nature of scientific research more effectively than a pure exchange of information would. This, in turn, is likely to contribute to increasing the students' interest in STEM and STEM careers.
We offered the teachers the flexibility of activities that could be fit into just one or two periods, used in science and technology lessons and projects, or integrated into the Earth science part of the curriculum, according to their needs at the time. The different activities were inter-related but independent (the naming competition prior to the expedition, live video link-ups during the expedition, and the song and drawing competitions after the expedition). Some classes participated in only one of the activities, others – in two or three, with the teachers choosing what was the most suitable for them. The activities were “low-cost” in the sense of the minimum required classroom time commitment. Their impact was “high gain” when compared to the modest amount of the class-time investment required. The gain is in terms of encouraging the students' interest in STEM and STEM careers, which was achieved thanks to the captivating adventure aspect of the project's fieldwork, engagement of students through co-creation with scientists, and direct, live-video communications between students and scientists.
Our competitions were, in a sense, experiments. When announcing them, we could not predict the level of participation in either of them or their effectiveness in promoting STEM. The seismometer-naming competition was successful and got the students who participated in it engaged in the project. The follow-up drawing and song-and-rap competitions produced some excellent entries, but the number of participating schools was lower than expected. A proportion of entries to the song-and-rap competition showed little evidence of the students researching either Earth science or the SEA-SEIS project's scientific goals.
While successful as a proof of concept, the competitions also highlighted what was missing: an effective network of teachers. We worked closely with a few teachers and attracted around 30 more from different schools through project announcements. But many other teachers did not respond to invitations to join our EPE activities, possibly not finding them sufficiently compelling or sufficiently informative. Our aim is to help the teachers to get their students more interested in STEM. In order to do this more effectively and develop our EPE programme further, we would need to grow an extensive, national-scale teacher network, offering the teachers continuing professional development, workshops, and resources.
An expanded, sustainable EPE programme should also offer more activities. Video links can be performed not only from the ship but from the lab and from other fieldwork locations. The expanded programme could have joint activities with multiple research projects and a wider group of researchers associated with them. The programme could also broaden so as to target adult audiences as well as school students. Generally, more engagement, co-creation, discussion, and debate are needed in order to get people of all ages more interested, involved, and comfortable with STEM subjects (SFI, 2015). Using the approaches, lessons, and recipes from the present programme, this can be addressed through the work with schools supported by the development of an effective teacher network, through presenting science through arts, and through the use of a sophisticated digital platform. Such expansion of the programme would, however, require dedicated funding – being sought at the moment.
A research project with an exciting field component presents a unique opportunity for broad public engagement. Educational activities with schools, in particular, can have a profound, lasting impact, showing the students how science works, encouraging them to study science, and broadening their career perspectives. Participation in a real research project and co-creation with scientists gets the students enthusiastically engaged.
The EPE programme presented here as a case study comprised of live video link-ups between scientists on a ship in the North Atlantic and students in classrooms and three school competitions, before and after the expedition. Survey responses from the teachers confirmed that the video links encouraged the students' interest in STEM. Researchers – both experienced and early-career – could see the real impact of the outreach and got involved with enthusiasm and commitment. The outcomes of an educational programme coupled with a research project can thus include both the school students getting more interested in STEM and STEM careers and researchers getting more experienced and proficient in the education and public engagement work.
This case study offers useful lessons and recipes for EPE programmes coupled with active research projects. First of all, it highlights how the research projects and the researchers working on them are a rich resource for EPE. Researchers can be effective EPE leaders, with the EPE programmes channelling their drive and creativity into the development of effective, novel EPE activities.
Secondly, it illustrates the importance of an EPE team with diverse backgrounds and complementary expertise and skill sets. In EPE with primary and secondary schools, the most essential partners are the school teachers and principals. The development of a network of actively engaged teachers is a prerequisite of successful EPE with schools and should, if possible, be initiated at the earliest stages of the programme. Beyond that, our programme capitalized on contributions of not only scientists and teachers, but also engineers and technicians and a sound artist. An effective national media campaign around the start of the SEA-SEIS Expedition and EPE programme was orchestrated by our communication manager, working with a partner PR firm. Our digital media presence was maintained primarily by the team's digital journalist, his expertise increasing its effectiveness greatly.
Thirdly, the programme demonstrates the value of co-creation by the EPE team, teachers, and school students. Close collaboration with the teachers was essential in planning and developing the programme activities. Getting the school students to co-create with scientists in the course of the school competitions got them engaged and genuinely interested.
Finally, our project can be seen as a template for a multifaceted, “low-cost, high-gain” EPE programme. Recognizing that the school curricula are already packed, making it difficult for teachers to allocate a lot of time to extra material, we offered them the flexibility of activities that could be fit into just one or two periods or integrated into the Earth science part of the curriculum, according to their needs at the time. We offered a series of different, inter-related but independent activities (the naming competition prior to the expedition, live video events during the expedition, and the song and drawing competitions after the expedition). Some classes participated in only one of the activities, others in two or three, with the teachers choosing which was the most suitable for them. In the sense of the minimum required classroom time commitment, the activities were low-cost. The high gain, relative to the amount of class-time investment and in terms of increasing the students' interest in STEM and STEM careers, is achieved thanks to the captivating adventure aspect of the project's fieldwork, engagement of students through co-creation with scientists, and direct, live-video communications between students and scientists.
The evaluation survey data are provided in the Supplement.
In our three video supplements, we present
an 8 min introductory video created for our ship-to-classroom video
link-ups ( a light-hearted but informative account of instrument deployments in rough weather – an example of the presentation of an aspect of the project to a broad audience ( an entertaining compilation of selected images and sounds from our
competitions for the primary and secondary schools
(
The supplement related to this article is available online at:
The complete member list of the SEA-SEIS Team can
be found at
SL prepared the manuscript with contributions from all co-authors. RB, DF, and DS produced the project EPE videos. SL, BO'D, CT, DF, SM, RB, CGG, JIdL, LB, and BCdM developed and ran school competitions. SL and DF performed programme-evaluation surveying. SL, LB, RB, JIdL, CGG, AS, DF, DS, LC, and BCdM developed, managed, and performed live video link-ups between the ship, classrooms, and DIAS. CT and BO'D contributed key ideas and co-created the competition and video-link activities.
The authors declare that they have no conflict of interest.
We thank the secondary and primary school teachers and principals in Ireland
and Italy who participated in the SEA-SEIS competitions and video link-ups
(
This research has been supported by the Science Foundation Ireland, Geological Survey of Ireland, Marine Institute, European Regional Development Fund (grant nos. 16/IA/4598, 13/CDA/2192, and 13/RC/2092).
This paper was edited by Marina Joubert and reviewed by Anthony Lelliott and Penny Haworth.