A view of the night sky from Egypt’s Katameya Observatory, the largest telescope in the Arab world.
A view of the night sky from Egypt’s Katameya Observatory, the largest telescope in the Arab world. Credit: Islam Hassan, CC BY-SA 2.0

The scientific and societal value of exploring our solar system and studying the meteorites that fall to Earth is widely accepted in today’s scientific community. However, not all regions of the world have been able to assert themselves in this endeavor. Africa in particular is underrepresented in planetary and space sciences.

Planetary and space science (PSS) research groups are now emerging in Africa, but they remain scattered and underfunded. Here we review PSS programs in Africa and pinpoint ways to further elevate PSS.

An Opportunity on Many Fronts

A dagger, recovered from King Tutankhamun’s mummy, sports a blade hammered from meteoritic iron. Credit: Egyptian Museum of Cairo

Exploration beyond Earth—and the technologies involved—has, in part, been responsible for jump-starting innovation and economic growth in many countries [International Space Exploration Coordination Group, 2013]. For example, PSS has led to technical breakthroughs in the study of rocks and minerals, including the portable handheld hyperspectral and geophysical sensors useful in mineral exploration. The technology developed for hyperspectral and geophysical imaging of Earth and other planets is now being used for farming, including for precision agriculture of high-value wine grapes [Mustard, 2017]. Much large-scale farming, such as corn in the U.S. Midwest, is mechanized with remote-controlled harvesters and other instruments that use GPS to navigate.

Public attention to PSS discoveries in North America, Europe, or Asia also serves as a major driver in inspiring interest in scientific and engineering careers. Thus, PSS is a key factor in promoting and retaining a country’s intellectual and economic prowess.

PSS can also help us understand our past. Recent archeological findings reveal that our ancestors, including the ancient Egyptians, learned how to process metal from meteoritic iron before metallurgic techniques to extract iron from crustal rocks became available [Rehren et al., 2013; Comelli et al., 2016]. Thus, PSS contributed to the discovery that meteorites may have played a role in transitioning humanity into the Iron Age.

What is more, PSS teams often involve physicists, chemists, geologists, biologists, and engineers working on a common problem. This multidisciplinary aspect serves as a template for tackling pressing issues in our modern world. In particular, because climate change and food are of critical relevance in Africa [Ngcofe and Gottschalk, 2013], government agencies’ development of high-level skills in fields such as PSS can empower communities to better and directly address their specific problems.

Planetary and Space Sciences in Africa Today

PSS is a vast domain of research. Here we focus on the exploration of the solar system, the study of planetary material (meteorites), and geological processes affecting planets (e.g., impact cratering).

A preliminary scan of articles published between 2000 and 2015 in four representative PSS journals—Icarus, Journal of Geophysical Research: Planets, Journal of Geophysical Research: Space Physics, and Meteoritics and Planetary Science—reveals that Africa produces less than 1% of the world output of scientific publications in PSS, despite having more than 15% of the world’s population (Figure 1). What factors cause this low rate, and how can production be increased?

Map illustrating the emerging activities in planetary and space sciences in Africa.
Fig. 1. Map illustrating the emerging activities in planetary and space sciences in Africa. Color codes represent results from a preliminary scan of published journals. The use of “project” here means that plans are in place to build facilities. Click here for a list of recent international conferences and workshops related to planetary and space sciences in Africa. Credit: David Baratoux

Discussions at the 35th International Geological Congress (IGC) last year in Cape Town, South Africa, revealed a widespread misperception in modest- and low-income African countries that funding fundamental science costs society a lot but has little or only long-term societal impact. This misperception remains an obstacle for developing PSS, representatives at IGC discussed.

However, solutions exist. For example, the recent emergence of PSS in North Africa illustrates the key role played by a few dedicated individuals, particularly when they are supported by political will favoring the training and academic recruitment of a knowledgeable young generation. For an overview of emerging PSS activities across Africa, see Figure 1.

PSS in Southern Africa

Southern Africa has a strong PSS presence and the most advanced facilities on the continent, including the South African National Space Agency and the South African Astronomical Observatory (founded in 1820). The world’s largest radio telescope project, the iconic Square Kilometre Array (SKA), is currently being built in the deserts of Australia and South Africa.

The SKA has strong government support, and degree programs in astronomy are growing to meet the demand for scientists, but the planetary sciences have no dedicated academic or research programs in southern Africa. Isolated groups work on specific projects, such as meteorite and impact cratering studies, stellar occultations, asteroid detection and characterization, and lunar laser ranging.

Efforts in North Africa

In North Africa, Morocco has gained visibility in meteoritics and impact studies [e.g., Chennaoui Aoudjehane et al., 2016] with the organization of international conferences, outreach (Space Bus Morocco), and frequent radio and TV appearances. The Ibn Battuta Center in Marrakesh is testing instruments and subsystems related to Martian exploration. In parallel, a group of astronomers at Cadi Ayyad University (Marrakesh) has established the first astronomical observatory in the Atlas Mountains of Morocco [Benkhaldoun et al., 2005].

Morocco’s Astronomical Observatory of Cadi Ayyad University, nestled in the Atlas Mountains.
Morocco’s Astronomical Observatory of Cadi Ayyad University, nestled in the Atlas Mountains. Successful planetary research programs conducted at the Astronomical Observatory of Cadi Ayyad University (Morocco) include observation of meteorite impacts on the moon [Ait Moulay Larbi et al., 2015] and the search for exoplanets [Gillon et al., 2017]. Credit: Zouhair Benkhaldoun

The Algerian state has also endeavored to promote PSS through higher education reforms and development of its research infrastructure. Ongoing research is focused mainly on meteorites and impact craters and involves international collaboration [e.g., Lamali et al., 2016; Sahouiet al., 2016]. Professional-amateur collaborations are common in Algeria [Mimouni, 2011]: Events to foster such collaborations include, among other things, preparatory training courses and astronomical observations of recent asteroid occultations.

In addition, the Arabian Geosciences Union launched a section on planetary science and astrobiology in 2015 for PSS scientists across northern Africa and the Middle East.

East Africa PSS Programs

In East Africa, Egypt, Kenya, and, more recently, Ethiopia have launched national space programs.

Remote sensing techniques are the cornerstone of planetary and space sciences; knowledge of these techniques allows researchers to develop skills that are widely applicable.

Remote sensing techniques are the cornerstone of PSS; knowledge of these techniques allows researchers to develop skills that are widely applicable in Earth, environmental, and atmospheric sciences. Recognizing this, Egypt has established a National Authority for Remote Sensing and Space Sciences (NARSS), which focuses on acquiring technical knowledge and capabilities to build small research and remote sensing satellites. NARSS also addresses environmental management and resource exploration, and it has recently launched a geoportal to facilitate access to Earth remote sensing data for research and education purposes.

Currently, the Egyptian government is establishing the Egyptian Space Agency in collaboration with China. Leading astronomical research centers in eastern Africa include the National Research Institute of Astronomy and Geophysics in Egypt, which operates the Katameya Observatory, the largest telescope in the Arab world. The institute also is planning to build an observatory on top of Mount Sinai.

The Egyptian Geological Museum in Cairo houses a small meteorite collection, including a specimen of the Nakhla Martian meteorite, which fell to Egypt in 1911. The exhibition is open to the public. In addition, Egypt has started a program for promoting science, technology, engineering, and mathematics (STEM) by establishing 11 STEM schools distributed across the country.

Ethiopia’s vision is to focus its priorities toward serving local needs such as communication and agriculture. Ethiopia is home to the privately funded Entoto Observatory and Research Center, which is located on top of 3200-meter-high Mount Entoto, near Addis Ababa.

Kenya is taking advantage of its equatorial position to efficiently launch satellites. Its capital also hosts a regional SERVIR facility for eastern and southern Africa; SERVIR is a joint venture by NASA and the U.S. Agency for International Development that supports satellite-based Earth monitoring and modeling in developing nations around the world.

PSS in West Africa

In West Africa, Nigeria has a space program that focuses on environmental management, resource exploration, communication, and defense projects.

Space Bus programs, such as this one in Senegal, promote planetary and space sciences to the general public.
Space Bus programs, such as this one in Senegal, promote planetary and space sciences to the general public. The bus follows an itinerary across the country and stops in several cities. At stops, interested people can gather to hear interactive talks and engage in hands-on activities about about telescopes, planets, and space exploration. Credit: Maram Kaire

The Ghana Space Science and Technology Centre, with current projects in radio astronomy, was established in 2012. The University of Ghana in Accra offers courses in geochemistry, including one that focuses on cosmochemistry. A network of international collaborations among Ghana, Europe, and North America was established around the time of the International Continental Scientific Drilling Program project at the Bosumtwi impact crater in Ghana in 2004. This collaboration resulted in several local scientists receiving advanced degrees overseas before returning to Ghana, and the program stimulated Ghanaian ecotourism [e.g., Boamah and Koeberl, 2007].

The Senegalese Association for the Promotion of Astronomy is very active in public outreach and has its own Space Bus program. PSS is virtually nonexistent in central Africa, but basic planetary sciences may be taught locally at the undergraduate level.

The Future of PSS in Africa on a Continental Scale

On a fundamental level, Africa needs more experts in STEM subjects, including PSS. This need is well documented in the declaration and action plan created by participants at the 2015 African Higher Education Summit.

To foster PSS in Africa, a group of researchers is proposing a 20-year continent-wide push to strengthen academics, research, and innovation surrounding PSS. This push would build on and enhance local efforts.

False color aerial view of Ghana’s Bosumtwi impact structure, the site of recent drilling research
False-color aerial view of Ghana’s Bosumtwi impact structure showing surface enrichments of potassium (red), thorium (green), and uranium (blue) superimposed on a shaded relief image. The crater is about 10.5 kilometers in diameter and formed when a meteorite struck about 1 million years ago. Through the Africa Initiative for Planetary and Space Sciences, researchers hope to use geologic features like Bosumtwi to inspire the public and industries to become invested in planetary and space sciences. Credit: David Baratoux and Geological Survey of Ghana

Key aspects of this program, dubbed the Africa Initiative for Planetary and Space Sciences, involve prioritizing M.Sc. and Ph.D. scholarships, temporary study-abroad fellowships for M.Sc. and Ph.D. candidates, and visits of junior (volunteering Ph.D. students) and senior researchers from outside the continent to Africa for transfer of knowledge. In addition, PSS experts and advocates in Africa would encourage existing research groups to take advantage of opportunities within NASA, the European Space Agency, and other space agencies to contribute to missions.

The Africa Initiative also fosters greater use of open access data and publications and leverages Africa’s geological record to offer fertile ground for understanding processes on other planets. Africa hosts 20 confirmed bolide impact structures and contains several planetary analogs (such as the Great Rift Valley’s Afar region and the Kaapvaal Craton in South Africa), and some of its arid lands offer prime locations to search for meteorites.

Benefits from Expanding PSS in Africa

In Africa, as in the rest of the world, government investment in research and education is motivated by projected social and economic benefits. Expanding PSS may help to address several of the United Nations’ Sustainable Development Goals that have already captured the interest of African governments: quality education, economic growth, reducing inequalities, climate, and peace.

Planetary and space sciences inspire people to think of the world as a single planet, not as a collection of countries.

PSS focuses on universal questions, such as the origin of life and the evolution and habitability of planets, and they inspire people to think of the world as a single planet, not as a collection of countries. This favors international and intra-African cultural exchanges, which may contribute to peace and economic and social development.

Wider sharing of knowledge may have positive impacts on the private sector: Facilitated access to space-based geostrategic data may attract investment in mineral resources as well as infrastructure development. Increasing innovation and patents with economic spin-offs requires an increasing number of professionals with engineering skills. The wider use of satellite data can assist in finding solutions to environmental, agriculture, and health issues (e.g., desertification, deforestation, artisanal mining, farming by satellite, and identification of factors controlling the spread of disease).

The knowledge gained and resources developed by current PSS efforts in Africa are only the beginning. As PSS grows in Africa, so too will its capacity to address the multiple challenges that this continent is facing for sustainable and inclusive economic growth. The pioneers of PSS in Africa that we highlight here have shown us that this is possible, and the Africa Initiative for Planetary and Space Sciences will hopefully build on this to help us reach our common goals.

Editor’s note: For more details on the Africa Initiative for Planetary and Space Sciences, read the Eos.org opinion piece. A Reddit Science “Ask Me Anything (AMA)” focused on planetary sciences and featuring a couple authors of this piece will occur 16 June 2017. Mark your calendars!


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Author Information

David Baratoux (email: david.baratoux@get.omp.eu), Géosciences Environnement Toulouse, Centre National de la Recherche Scientifique (CNRS), Institut de Recherche pour le Développement, Université de Toulouse, Dakar, Senegal; also at Institut Fondamental d’Afrique Noire Cheikh Anta Diop, Dakar, Senegal; Hasnaa Chennaoui-Aoudjehane, Géosciences Appliquées à l’Ingénierie de l’Aménagement (GAIA) Laboratory, Department of Geology, Faculty of Sciences Ain Chock, Hassan II University of Casablanca, Morocco; Roger Gibson, School of Geosciences, University of Witwatersrand, Johannesburg, South Africa; Atmane Lamali, Centre de Recherche en Astrophysique et Géophysique, Département de Géophysique, Laboratoire de Géomagnétisme et Paleomagnétisme, Bouzaréah, Alger, Algeria; Wolf Uwe Reimold, Museum für Naturkunde Berlin, Germany; also at Humboldt-Universität zu Berlin, Germany; also at Geochronology Laboratory, University of Brasilia, Brazil; Marian Selorm Sapah, University of Ghana, Accra; Moulley Charaf Chabou, Institut d’Architecture et des Sciences de la Terre, Université Ferhat Abbas, Sétif, Algeria; John Bosco Habarulema, Sansa Space Science, Hermanus, South Africa; Mark W. Jessell, Center for Exploration Targeting, University of Western Australia, Perth, Australia; Aberra Mogessie, Institute of Earth Sciences, University of Graz, Austria; Zouhair Benkhaldoun, Oukaimeden Observatory, Laboratoire de Physique des Hautes Energie et Astrophysique, Université Caddi Ayad, Marakesh, Morocco; Elyvin Nkhonjera, Young Earth Scientists (YES) Network, Lilongwe, Malawi; Ndivhuwo Cecilia Mukosi, Council for Geoscience, YES, Polokwane, South Africa; Maram Kaire, Association Senegalaise pour la Promotion de l’Astronomie, Dakar, Senegal; Pierre Rochette, Centre de Recherche et d’Enseignement de Géosciences de l’Environnement, Aix-Marseille University and CNRS, Aix-en-Provence, France; Amanda Sickafoose, South African Astronomical Observatory, Cape Town; Jesús Martínez-Frías, Consejo Superior de Investigaciones Científicas, Complutense University of Madrid, Instituto de Geociencias Spain; Axel Hofmann, Department of Geology, University of Johannesburg, South Africa; Luigi Folco, Dipartimento di Scienze della Terra, Università di Pisa, Italy; Angelo Pio Rossi, Jacobs University Bremen, Germany; Gayane Faye, Institut des Sciences de la Terre, Université Cheikh Anta Diop, Dakar, Senegal; Katrien Kolenberg, Katholieke Universiteit Leuven, Belgium; also at Physics Department, University of Antwerp, Belgium; Kelali Tekle, East African Regional Office of Astronomy for Development, Addis Ababa, Ethiopia; Djelloul Belhai, Laboratoire, Géodynamique, Géologie de l’Ingénieur et Planétologie (GGIP), Faculté des Sciences de la Terre, de la Géographie et Aménagement du Territoire, Université des sciences et de la technologie Houari-Boumédiène, Bab Ezzouar, Algeria; Meriem Elyajouri, Galaxies, Etoiles, Physique et Instrumentation (GEPI), Observatoire de Paris, Paris Sciences et Lettres (PSL) Research University, CNRS, Université Paris-Diderot, Sorbonne Paris Cité, France; Christian Koeberl, Natural History Museum Vienna and University of Vienna, Austria; and Mamdouh M. Abdeen, Geological Applications and Mineral Resources Division, National Authority for Remote Sensing and Space Sciences, Cairo, Egypt


Baratoux, D.,Chennaoui-Aoudjehane, H.,Gibson, R.,Lamali, A.,Reimold, W. U.,Sapah, M. S.,Chabou, M. C.,Habarulema, J. B.,Jessell, M. W.,Mogessie, A.,Benkhaldoun, Z.,Nkhonjera, E.,Mukosi, N. C.,Kaire, M.,Rochette, P.,Sickafoose, A.,Martínez-Frías, J.,Hofmann, A.,Folco, L.,Rossi, A. P.,Faye, G.,Kolenberg, K.,Tekle, K.,Belhai, D.,Elyajouri, M.,Koeberl, C., and Abdeen, M. M. (2017), The state of planetary and space sciences in Africa, Eos, 98, https://doi.org/10.1029/2017EO075833. Published on 13 June 2017.

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