International Science Council's Statement on Open Science and the UNESCO initiative
In this statement made by the International Science Council (ISC) delegation to the UNESCO Special Committee meeting on Open Science, 6-12 May 2021, the delegation explored how the recommendation and potential cascading interventions by Member States could develop along two divergent pathways.
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Furthering Equitable Evolution of Science and Technology Innovation
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Scientific inquiry has long been a self-organized enterprise. Governments, funders and universities may all, from time to time, have prescribed priorities for scientific inquiry, but scientists themselves have largely determined how inquiries should be conducted. In the process they have created and stewarded their own organizations: learned societies, academies, and centres within the generally flexible framework of their universities. Principles of self-organization have been sustained even as governments have increasingly recognized the value of science in promoting national agendas. Common implicit, and sometimes explicit, premises have been that whilst governments may articulate their priorities and set research budgets, decisions on how resources are expended, and how research is organized are best left to researchers, and that giving scientists the freedom to follow their inspiration is the best way to maximize the return on society’s investment in research. Thus, the social organization of the scientific effort in addressing increasingly complex, interdisciplinary problems or strategic research priorities has been largely left to researchers.
Ensuring Self-Organization of Knowledge and its Applications
This self-organization has developed in a way that maintains a creative tension between, on the one hand, competition for esteem and funding, and on the other hand, cooperation to achieve deeper more widely applicable understanding. It is a balance of drivers that has served the enterprise well, whether at the level of individuals, national science systems or international science collaborations, whilst also serving the interests of multiple stakeholders.
The ongoing digital revolution of recent decades has created a new basis for scientists to access, manipulate and communicate data, metadata, information, and preliminary knowledge, and to hypothesize, debate, reproduce, replicate, validate and refute. It has greatly facilitated globally networked research, efficient data-sharing, and immediate access to the record of science, including by automatic techniques of knowledge discovery, in principle by all, thereby enhancing the rate and dimensions of knowledge creation. Although Open Science is not new, it stems from the publication of the first scientific journals in the late seventeenth century, profound new digital opportunities have inspired scientific communities to progressively mature and crystallize the essentials of a new Open Science movement.
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Open Science as an Intrinsic Value for Civil Society
Open Science enlarges scientific and social horizons in the pursuit of knowledge, its dissemination and use. Intrinsic to this new paradigm are historic values of scientific self-organization, principles of freedom and responsibility, universal accessibility and sharing, inclusivity and equitability, together with responsibilities for education and capacity development, as reflected in the statutes of the ISC and in its vision of “science as a global public good” [1]. The expanded social networks of this new openness are exemplified in trends of increased multi-nationally authored scientific papers, the growth of transdisciplinary collaboration and of citizen science. The shaping of this new paradigm has largely been achieved through the work of the national academies, international scientific unions and associations, and related bodies that are represented in the membership of the ISC, and reflected in its statement on Open Science [2]. National and regional funders of science have increasingly supported the Open Science imperative by investments in supportive infrastructures and promotion of open access publishing as a condition of funding.
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Now UNESCO has taken a stance. UNESCO seeks to formalize these trends at an international level by placing a recommendation on Open Science before its 193 Member States for their endorsement [3]. UNESCO has engaged with the scientific community over the last year to generate a long list of draft recommendations for open access to the published record of science, open data, open educational resources, open-source software and code, open hardware and infrastructures, and open engagement with society.
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Ensuring Scientific Knowledge is Openly Accessible to the General Public
The draft’s first contact with political reality, in the form of national representatives, took place in early May 2021. Representatives were almost universally supportive, and even added “bite” on some crucial issues. For example, there is an increasing awareness of the moves of some major commercial publishers to evolve into broadly based “science/knowledge platforms”, able increasingly to monopolize not only access to scientific knowledge but also to data about science and scientists, their evaluation, scientometrics, management, networking, priorities and funding, with little accountability to the scientific community or its organizations [4a, 4b]. Indeed, the commercial public sector has been more than effective in monetizing scholarly output, creating an oligopoly of control, and is learning how to take control over additional aspects of the research life cycle, now especially focused on the interaction between publishing, data repositories, and access to data. Awareness of these trends was reflected in a critical insertion in the text by UNESCO Member States that: “The monitoring of Open Science should be explicitly kept under public oversight, including the scientific community, and whenever possible supported by open non-proprietary and transparent infrastructures. This monitoring aspect could include but should not be delegated to the private sector.”
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Promoting the Open Source Pathway Over the Restricted Access Pathway
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The UNESCO recommendation and potential cascading interventions by Member States could develop along two divergent pathways. They could enhance governmental support for the scientific community, and the stakeholder ecosystem of which it is part, as they develop new policies, infrastructures and collaboration strategies that serve the Open Science paradigm as it has progressively evolved over the last two decades. Alternatively, Member States could disregard the tradition whereby the scientific community self-organizes to achieve its purposes, and come to specify, or even regulate, how it should be organized. We are strongly in favour of the former, and concerned about the potential of the latter, which could create a mode of Open Science that opens the door: “to capture of publicly funded research value by commercial platforms, yet more ‘metrics’ of productivity to ‘incentivize’ scholars to work harder and a focus on the system-wide progress of science, ignoring costs and benefits to individuals, whether scientists or non-scientists” [5]. Nonetheless, we welcome the draft UNESCO recommendation most strongly, with the comment that awareness of danger is the first step in averting it.
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ISC Delegation to the UNESCO Special Committee meeting on Open Science, 6-12 May 2021:
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Geoffrey Boulton, Governing Board member, International Science Council (ISC)
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Christophe Cudennec, International Union of Geodesy and Geophysics (IUGG)
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David Castle, World Data System (WDS)
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Nada Chaya, Arab Council for the Social Sciences (ACSS)
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Nilay Dogulu, International Union of Geodesy and Geophysics (IUGG)
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Janet Halliwell, on behalf of Canada’s adhering members, National Research Council of Canada (NRC) and Social Sciences and Humanities Research Council (SSHRC)
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Frédéric Hélein, International Council for Industrial and Applied Mathematics (ICIAM)
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Pam Maras, International Union of Psychological Sciences (IUPsyS)
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Michaela Rossini, International Institute for Applied Systems Analysis (IIASA)
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Juan Armando Sanchez, Colombian Academy of Exact Physical and Natural Sciences
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Megha Sud, Science Officer, International Science Council (ISC)
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Jens Vigen, International Union of Pure and Applied Physics (IUPAP)
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CSTI Commitment to Promoting the Benefits of Open Science
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UNESCO delineated the ecosystem components that enable Open Science collaborations to deliver synergistic benefits for all involved in the discovery of scientific knowledge and technological Innovation [6]. Open Source tools such as social media platforms and search engines have dramatically improved access to news and data. Today, information on Google can be accessed in raw form by researchers and the general public or curated by librarians and business service providers. A researcher might want access to all information on green building techniques and their ecological impact while an EDGE certified construction manager might pay for curated news on low-toxic materials that improve building energy efficiency [7]. Open Universities are proliferating online and cater to a student population (customer base) that has never been able to access public or private universities, even when courses are online. The COVID-19 pandemic and resulting shift towards online conferencing has vastly increased the ability of many to attend multiple global scientific conferences in the same month.
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Although open source software was once thought of as a sure failure for a business model, several companies have achieved billion dollar revenue status by leveraging big data that becomes available when millions of users can access a free platform [8]. Assuming the capture and use of data is transparent and consensual, Facebook and Twitter users can find like minded turtle stitching practitioners, Hashicorp users can develop a custom cloud service app for a company of 10 people, DataBricks developers can support community groups with custom analytics for the 100 daily water quality data points that add up to millions of data points over 365 days. In short, we are entering an era where hyper local customization of technology, business and scientific services is affordable to a mass market.
The same trends are emerging in hardware. Virtual reality laboratories provide the same physical experience as a traditional laboratory without the smells or risk of chemical burns [9]. There is no doubt that understanding the difference between the smell of sulfur versus formaldehyde is an important skill along with the physical understanding that a base can burn worse than an acid. Notwithstanding, the ability to conduct a nitroglycerin molar mass experiment without the risk of an explosion is quite reassuring. Once only used for desktop prototyping, 3D printers are now used for remote collaboration in construction design and the actual construction of affordable buildings with software that makes the permit approval process easier [10]. As with any scientific discovery process, the only thing that is very clear at this stage is that we don't even know what we don't know.
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The determination of what is beneficial versus harmful will require constant use of the precautionary principle to anticipate risks and harm before attempting large scale deployments [11]. Simultaneously, by committing to respectful collaboration, even when perspectives are diametrically opposed to each other, the final result is a more robust outcome. To this end, we engage and invite others to engage in the exciting yet daunting journey towards increasing Open Science and increasing the number of diverse Open Science beneficiaries.
Footnotes:
1 https://council.science/actionplan/isc-vision-and-mission/
2 https://council.science/actionplan/open-science/
3 https://en.unesco.org/science-sustainable-future/open-science/recommendation
4 https://infrastructure.sparcopen.org/landscape-analysis and https://council.science/wp-content/uploads/2020/06/2020-02-19-Opening-the-record-of-science.pdf
6 https://en.unesco.org/sites/default/files/open_science_brochure_en.pdf​
9 https://eonreality.com/a-virtual-lab-for-chemistry-students/
11 https://www.europarl.europa.eu/thinktank/en/document.html?reference=EPRS_IDA(2015)573876
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