Modern nuclear systems typically fail not because of technological shortcomings but because institutional memory is not preserved.

Globally, nuclear knowledge is threatened less by isolated failures and more by the convergence of short cycles, including political terms, economic fluctuations, project deadlines, workforce turnover, technological advancements, and institutional restructuring. When these cycles remain disconnected, knowledge deteriorates, decision-making becomes less effective, and nations struggle to safely construct, operate, and manage complex systems. Africa encounters these challenges as well, yet possesses distinctive strengths.

Long-term thinking has been integral to human history. Across eras, individuals initiated projects with the understanding that they would not witness their completion.

In Europe, cathedrals such as Chartres Cathedral (begun in 1194), Notre-Dame de Paris (1163), Cologne Cathedral (1248), and St. Stephen's Cathedral in Vienna (founded in 1137) required centuries to complete. The masons who established the foundations recognized the enduring significance of their contributions, even if incomplete. Craft guilds upheld standards across generations. Artisans traversed regions, unified by common rules, techniques, and a commitment to quality. Michelangelo, an Italian, received commissions throughout Europe, demonstrating that excellence transcended political boundaries.

In India, the rock-cut temples of Ellora and Ajanta in Maharashtra were constructed over centuries, integrating engineering, astronomy, and spirituality into enduring stone structures. These projects were conceived for perpetuity, not merely for a single generation.

In Latin America, the Mayan and Inca civilizations constructed cities such as Chichén Itzá and Machu Picchu, aligning them with celestial cycles and employing design principles that continue to challenge modern comprehension.

These civilizations shared a common trait: they planned beyond the constraints of political cycles.

Africa has a longstanding history of contributing to this tradition. In Egypt, the pyramids of Giza were constructed with mathematical and engineering precision that has persisted for nearly 5,000 years. These undertakings exemplified long-term commitments, necessitating sustained knowledge transfer, standardized methodologies, and deliberate management of expertise.

In Nubia, now part of present-day Sudan, the Kushite kingdoms developed pyramid complexes, iron industries, and advanced water management systems. Although less recognized internationally, these achievements were equally sophisticated.

In Ethiopia, the rock-hewn churches of Lalibela were carved directly into solid stone during the 12th century, representing architectural achievements intended to endure indefinitely, rather than merely outlast a single reign.

In Mali, the scholarly city of Timbuktu preserved written knowledge in disciplines such as astronomy, mathematics, medicine, and law for centuries, protected by networks of scholars and custodial families.

In Southern Africa, Great Zimbabwe remains one of the largest pre-colonial stone structures globally. Constructed without mortar, it has endured for over 700 years, demonstrating standardized construction knowledge and sustained institutional continuity.

In West Africa, the Benin Empire produced bronze and brass artifacts of remarkable technical sophistication, managed by rigorous guild systems that preserved metallurgical expertise across generations.

In Nigeria, the Igbo-Ukwu bronze castings from the 9th century exemplify advanced metallurgy that predated their era, while Sungbo's Eredo, an extensive system of defensive earthworks spanning over 160 kilometers, was constructed over centuries through coordinated community effort.

Throughout the continent, historical evidence demonstrates that Africa established institutions, infrastructure, and knowledge systems designed to persist beyond the lifespans of their founders.

In recent decades, long-term planning has increasingly been supplanted by short-term pressures:

While such pressures may be manageable in less complex systems, they can prove catastrophic in nuclear contexts. Nuclear systems are designed to operate for 60 to 100 years. Knowledge related to design, safety, fuel behavior, regulatory frameworks, and operational culture must be maintained across generations. Rebuilding nuclear competence each decade incurs significant costs and risks, and undermines national sovereignty.

It is now imperative to transcend short-term cycles, especially in the context of nuclear energy. Nuclear energy is not experimental; it constitutes established and operational infrastructure. This is particularly evident in high-temperature gas-cooled reactor technology.

In China, the HTR-PM (High-Temperature Reactor – Pebble-bed Module) has been fully constructed, connected to the grid, and is operational. As the world’s first commercial application of Generation IV pebble-bed reactor technology, it demonstrates large-scale viability. This advancement carries important implications for Africa.

Africa has played a significant role in this progress over many years. South Africa’s Pebble Bed Modular Reactor (PBMR) program, formerly known as HTGR, produced foundational research that has shaped numerous advanced reactor designs, including those currently operational in China and under development in the United States, such as the Xe-100.

South Africa also possesses some of the most advanced TRISO fuel research capabilities globally, with its designs now serving as the foundation for PBMR-type reactors worldwide.

With the resurgence of PBMR activities under NECSA, Africa is not simply importing nuclear technology; it is reconnecting with a tradition of expertise it helped to establish. This represents a continuation, not a new beginning.

Alongside established nuclear nations, more African countries are officially recognized as nuclear newcomer states—countries that have taken significant steps toward nuclear energy through policy, regulatory preparation, international cooperation, and institutional development. These include Ghana, Kenya, Nigeria, Uganda, Zambia, Rwanda, Senegal, Morocco, and Namibia, among others.

Although each country progresses at its own rate, all acknowledge that nuclear energy constitutes a long-term national commitment, demanding sustained knowledge, institutional continuity, and expertise that extends beyond individual political terms. This collective endeavor signifies a continental return to long-term energy planning.

By 2050, Africa's population is expected to exceed 2.5 billion. By 2100, Africa will be one of the largest centers of global economic growth, labor, and demand.

Population reduction is not a viable solution. Instead, Africa must develop systems that fully harness human potential. The continent’s youth require:

Intermittent energy systems alone are insufficient to address these needs. Clean, continuous, and scalable baseload energy is essential. Nuclear energy offers this foundation, supporting education, healthcare, manufacturing, research, and digital infrastructure for future generations.

Africa possesses a substantial proportion of the world’s natural resources, whereas other regions increasingly struggle to secure them. However, resource extraction frequently proceeds without fostering sustainable capacity for Africa’s expanding population.

The future will favor regions that convert resources into knowledge ecosystems, where standards are upheld, expertise is cultivated, and institutions persist beyond short-term cycles.

There is even speculation that the lost civilization of Atlantis may have been in North Africa—a reminder, whether mythological or not, that Africa has long held a central place in humanity's civilizational history.

The central question for Africa is not the viability of nuclear energy, as its effectiveness is already established. The true challenge lies in whether Africa will develop institutions that plan for centuries, preserve knowledge beyond political transitions, and prioritize expertise over short-term interests.

Our ancestors achieved this without the benefit of modern tools, digital systems, or global supply chains.

There is no justification for failing to achieve this today. Nuclear energy necessitates it, Africa’s youth merit it, and the next century depends upon it. Africa need not merely envision this future; it has already experienced it and must reclaim it.