Govt be robust in handling STEM – Ghana STEM Network

In today’s rapidly evolving global landscape, the era of fossil fuel-driven economic growth is giving way to one fueled by information, innovation, and technology.

Advancements in science and technology—especially in areas such as artificial intelligence—are reshaping economies and determining future trajectories. In this context, nations that fail to prepare their human resources—particularly children, youth, and women—for a data-driven future risk being left behind.

Ghana, despite its potential, has not yet fully implemented the Fourth Industrial Revolution on a large scale due to a combination of structural and functional challenges. However, the country has an opportunity to leverage a holistic, practical-based STEM education system to harness the benefits of this transformation.

The Ghana STEM Network, a STEM Ecosystem Network of 211 STEM stakeholders comprising professors, educators, innovators, product developers, service providers, policy experts, legal practitioners, fund managers, industry players, scientists, and advocates, recognizes the urgency of reform.

This position paper is presented as a contribution to educational reform in Ghana, offering insights into the challenges facing STEM education and providing actionable recommendations for the government—including the Ministry of Education, Ghana Education Service (GES), Ghana Tertiary Education Commission (GTEC), and the National Council for Curriculum and Assessment (NaCCA)—as well as other relevant stakeholders.

Challenges Confronting STEM Education

Several critical challenges hinder the effective delivery of STEM education in Ghana:

1. Lack of a Clear Vision and Focus:
   • The National Science, Technology, and Innovation (STI) Policy (2017–2020) prioritizes a knowledge-based economy, yet fails to provide a clear roadmap for integrating STEM into formal education to build the necessary human resource capacity.
2. Delayed Operationalization of Policies:
   • The Ghana STEM Policy has not been effectively implemented, resulting in an absence of a cohesive and visionary approach to STEM education.
3. Disconnect Between Theory and Practice:
   • There is a significant gap in applying classroom-taught science principles to real-world challenges, limiting students’ practical skills.
4. Inadequate Infrastructure:
   • Insufficient makerspaces, science fairs, and interactive environments (e.g., STEM museums, dedicated playgrounds) restrict opportunities for hands-on learning and exploration.
5. Limited Capacity Building for Educators:
   • There are few avenues for teacher training in modern STEM pedagogies, which affects the quality and delivery of STEM education.
6. Resource Constraints:
   • Financial limitations hinder the availability of quality teaching materials, equipment, and supportive learning environments.
7. Impact of Free Senior High School Policy:
   • The policy has adversely affected private schools—key stakeholders in STEM education—by straining their resources and limiting their contributions.
8. Fragmented Curriculum:
   • A cohesive, holistic STEM curriculum from basic to tertiary education is lacking, leading to discontinuity in skills development.
9. Weak Assessment and Monitoring Frameworks:
   • The absence of robust evaluation systems undermines efforts to measure the effectiveness of STEM programs.
10. Rural-Urban Divide:
    • Under-resourced rural schools and underserved urban areas face significant disparities in access to quality STEM education.
11. Inadequate Public-Private Partnerships (PPPs):
    • A top-down funding structure limits local schools’ ability to initiate STEM programs, as private sector engagement is minimal.
12. Curriculum Mismatch with Industry Demands:
    • Existing curricula do not align with the skills needed by the private sector, further widening the gap between education and employment.
13. Fragmented STEM Initiatives:
    • Multiple overlapping STEM organizations operate with limited coordination, reducing overall impact.
14. Partisan Influences and External Dependencies:
    • Political partisanship and reliance on Western frameworks—often designed to serve corporate interests—exacerbate inequality and environmental concerns. This dynamic can undermine local sovereignty and ignore cultural contexts, perpetuating exploitative practices.

Proposed Solutions for Promoting STEM Education

To overcome these challenges, the Ghana STEM Network recommends the following solutions:

1. Develop a National STEM Education Strategy:
   • Establish clear long-term development goals and strategies, outlining specific plans for the next 5, 10, 15, and 20 years. Operationalizing the existing STEM Policy is a crucial first step.
2. Invest in STEM Infrastructure:
   • Prioritize the creation of makerspaces, science museums, education parks, and other exploration centers across all 16 regions, ideally at the district level. These should be developed in partnership with the private sector.
3. Integrate Practical Learning into the Curriculum:
   • Reform curricula to include exploratory activities, hands-on tasks, educational tours, and real-world problem-solving projects that enhance practical application of STEM principles.
4. Establish a National STEM Database:
   • Create a comprehensive database of all STEM-based private sector organizations, their services and geography to facilitate coordinated local engagement.
5. Focus on Basic Education:
   • Prioritize STEM education at the basic school level to build foundational skills that are immediately applicable in the workforce, thereby addressing unemployment and underemployment.
6. Revise Assessment Frameworks:
   • Develop new models for assessing and promoting students that move beyond traditional examinations to include competency-based evaluations.
7. Strengthen the STEM Ecosystem:
   • Organize STEM organizations into a cohesive, structured network that collaborates with government bodies to implement targeted, strategic plans based on successful models from other sectors of the Ghanaian economy.
8. Embrace Pan-African and Decolonial Approaches:
   • Shift away from Western-centric frameworks by adopting policies and practices that emphasize community, health, environmental sustainability, and sovereignty. This includes learning from pre-colonial African models and ensuring that STEM initiatives benefit all sectors of society.
9. Engage Local STEM Companies:
   • Deliberately support and collaborate with local STEM enterprises to develop, manufacture and supply tools, services, and resources that align with the educational framework. This will create jobs and inspire innovation among young Ghanaians.
10. Foster Policy Dialogue and Protection for Vulnerable Groups:
    • Create policies that protect and support the most vulnerable members of society, ensuring that all citizens have access to quality STEM education. This includes addressing systemic issues related to colonial legacies and fostering equitable partnerships.
11. Incorporate Critical Thought and Further Readings:
    • Encourage a deeper understanding of historical and social contexts by integrating perspectives from scholars such as Oyèrónkẹ́ Oyěwùmí, Ngũgĩ wa Thiong’o, Kwame Nkrumah, Paulo Freire, Walter Rodney, Thomas Sankara, Angela Davis, Audre Lorde, bell hooks, Sarah Schulman, Lennard J. Davis, and Frances Ryan into STEM education discourse.

Conclusion

Ghana stands at a pivotal moment in its development. The transition to a data-driven, technologically advanced economy necessitates a robust, holistic, and sustainable approach to STEM education. The Ghana STEM Network calls on the government and all stakeholders to adopt these recommendations and work collaboratively toward a future where every Ghanaian has access to quality STEM education. By doing so, Ghana can not only bridge the current educational and economic divides but also emerge as a regional leader in STEM innovation and sustainable development.