Submitted:
04 July 2026
Posted:
06 July 2026
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Abstract
Keywords:
1. Introduction: Reframing Innovation as a Metasystem
1.1. The Need for a New Paradigm
1.2. Objectives of Innovationology
2. Ontological and Epistemological Foundations of Innovationology
2.1. Ontology of Innovation: Emergence, Metasystem, and Transformative Potential
- Emergence:Novelty arises from interactions within and across cognitive, social, technological, ecological, and spiritual layers. Emergence is lawful yet context-dependent, producing patterns that are neither fully predictable nor arbitrary.
- Systemicity:Innovation operates in nested networks of interdependent subsystems, where local interventions ripple through broader socio-technical and ecological systems.
- Ethical Embeddedness:Innovation inherently entails moral responsibility, linking epistemology and ethics, action and consequence. This aligns with Heidegger’s call for a more contemplative, non-instrumental relationship with technology and the world.
- Multi-modal Intelligence Integration:Human, artificial, collective, and spiritual forms of intelligence converge within Innovationology to generate context-aware, resilient, and adaptive innovations (Moleka, 2026a, 2026b).
2.2. Epistemology: Knowledge Co-Creation in Mode 4
- 1. ° Transdisciplinary Integration
- 2. ° Participatory Co-Creation
- 3. ° Iterative Adaptation
| Dimension | Mode 1 – Disciplinary Science | Mode 2 – Applied/Contextual | Mode 3 – Quadruple Helix | Mode 4 – Innovationology (Proposed) |
|---|---|---|---|---|
| Epistemic Core | Disciplinary rigour, internal validation | Application-oriented, socially robust | Hybridisation, reflexivity, democracy | Integration, transdisciplinarity, systemic transformation |
| Knowledge Location | Universities, labs | Problem contexts, industry | Networks of academia–industry–government–society | Global pluriversal networks of intelligences (human + AI + ecological) |
| Validation Criteria | Peer review, disciplinary norms | Usefulness, applicability, accountability | Participatory legitimacy, inclusivity | Integrative coherence, systemic impact, anticipatory intelligence |
| Ontology of Knowledge | Linear, reductionist | Contextual, problem-driven | Co-evolutionary, reflexive | Emergent, systemic, planetary, pluriversal |
| Role of Society | External observer | Stakeholder, co-producer | Active co-creator | Constitutive, co-evolving with knowledge itself |
| Technology Role | Auxiliary tool | Instrumental driver | Enabler of co-production | Co-intelligence, AI-driven generativity, knowledge catalysts |
| Representative Authors | Gibbons et al. (1994) | Nowotny et al. (2001) | Carayannis & Campbell (2012) | Moleka (2025d); Horvath et al. (2025) |
| Shift | From (Modes 1–3) | To (Mode 4 – Innovationology) |
|---|---|---|
| Epistemic unit | Disciplinary/sectoral knowledge | Systemic integration of diverse knowledges |
| Temporal orientation | Retrospective or present-focused | Anticipatory and future-oriented (innovation singularity) |
| Intelligence framework | Human cognition, institutional processes | Multi-intelligence field (human, AI, ecological, spiritual) |
| Governance of knowledge | Peer review, expert/stakeholder participation | Fractal governance of pluriversal epistemologies |
| Innovation role | Application of knowledge | Ontological driver of knowledge evolution |
| Ethical grounding | Normative (discipline- or society-based) | Integral ethics: planetary sustainability, justice, dignity |
| Epistemic ambition | Explanation and application | Transformation and meta-integration |
2.3. Epistemic Implications
2.4. Ethics and Metamoral Responsibility
2.5. Conceptual Model: Innovation as Relational Metasystem
- Knowledge (K): encompassing scientific discoveries, indigenous traditions, experiential wisdom, and artistic imaginaries (Moleka, 2026a; Gibbons et al., 1994; Nowotny, Scott & Gibbons, 2001).
- Context (C): socio-cultural, ecological, political, and economic environments that condition both the possibility and trajectory of innovation (Geels, 2002; Ostrom, 2009).
- Intelligence (I): diverse modalities of cognition—human, artificial, collective, and spiritual—that collaborate in knowledge production and system transformation (Clark, 1997; Brynjolfsson & McAfee, 2017; Lévy, 2013).
- Ethics & Responsibility (R): the normative compass guiding innovation, embedding justice, sustainability, and moral accountability into design and deployment (Floridi, 2013; Jonas, 1984; Taddeo & Floridi, 2018).
2.6. Philosophical Significance
- Ontological Reorientation: Innovation is not a derivative function of technology or markets; it is a meta-force of becoming, structuring socio-technical evolution itself. This aligns with process philosophies (Whitehead, 1978) and complexity-oriented metaphysics (Prigogine & Stengers, 1984; Morin, 2008), which treat emergence and transformation as fundamental properties of reality.
- Epistemic Pluralism: Innovationology embraces epistemological polyphony, recognizing that valid knowledge emerges from the interaction of multiple epistemes—scientific, indigenous, artistic, algorithmic, and spiritual (Santos, 2014; Escobar, 2018). This stance resonates with Feyerabend’s (1975) call for “epistemological anarchism” and with contemporary accounts of Mode 4 knowledge (Moleka, 2025b).
- Ethical Imperative: Innovation is inherently normative. As Jonas (1984) argued in The Imperative of Responsibility, every act of technological creation entails obligations toward future generations. Innovationology advances this imperative by embedding ethics into the systemic conditions of innovation itself, not as an external afterthought but as a constitutive dimension (Floridi, 2013; Taddeo, 2020).
- Transformative Integration: Innovation is the arena where human and artificial intelligences co-evolve under ethical and ecological constraints. This view transcends anthropocentrism by situating intelligence within broader networks of life, technology, and environment (Clark, 1997; Brynjolfsson & McAfee, 2017; Bostrom, 2014).
3. The Universal Innovation Equation (UIE): Formalizing Transformative Potential
3.1. Rationale for a Formal Framework
3.2. Definition of the Equation
3.3. Philosophical and Epistemological Dimensions
- Ontological primacy of innovation – Innovation is not an output of human will alone; it is an emergent property of systems, shaping evolution across socio-technical and ecological domains (Morin, 2008).
- Plurality of intelligences – Human ingenuity, AI, collective decision-making, and spiritual wisdom interact dynamically (Wilson, 2012; Floridi, 2014).
- Ethics as constitutive – Responsibility is not peripheral but structural, ensuring innovation supports justice, inclusivity, and sustainability (Taddeo, 2020).
- Emergence and non-linearity – Innovation follows complex adaptive dynamics, consistent with complexity theory and systems thinking (Westley et al., 2011; Prigogine & Stengers, 1984).
3.4. Operationalization Through Real Cases
3.5. Case Illustration: Community Solar Microgrids in Tanzania
3.6. Philosophical Significance
4. Innovationology in Action
4.1. Frugal and Contextual Innovation: Solar Microgrids in Burkina Faso and Kenya
4.2. AI-Augmented Scientific Discovery: Europe and Asia
4.3. Socio-Technical Systems and Climate Resilience: African Communities
- Transdisciplinary co-creation: integrating cognitive science, AI, social sciences, ethics, and local knowledge.
- Emergence and systemic dynamics: minor interventions can trigger cascading societal and ecological effects.
- Ethical primacy: all interventions are guided by responsibility (R), ensuring long-term sustainability and justice (Floridi, 2014; Taddeo, 2020).
5. Philosophical Implications of Innovationology
5.1. Ontological and Epistemic Primacy
5.2. Emergence, Systemic Interdependence, and Ethics
5.3. Intelligence Integration
6. Synthesis and Future Perspectives
- Innovation as Ontological ForceInnovation is not merely a by-product of human action but an ontologically emergent property of complex socio-technical systems. It structures social, ecological, and technological domains, shaping trajectories of knowledge, societal organization, and resource distribution. This aligns with the philosophy of complex systems (Morin, 2008; Prigogine & Stengers, 1984), emphasizing that small-scale interventions can trigger cascading, system-wide transformations.
- Ethical Responsibility as Core DriverEthical responsibility (R) is embedded at every stage of innovation, from design to deployment. Case studies demonstrate that interventions that prioritize equity, environmental stewardship, and social justice—not only efficiency or profitability—generate more sustainable and resilient outcomes (Floridi, 2014; Taddeo, 2020). Ethical responsibility thus functions as a meta-constraint ensuring that emergent potential (P) translates into societal benefit rather than harm.
- Transdisciplinary, Mode 4 Knowledge ProductionInnovationology operationalizes Mode 4 knowledge production, wherein scientific expertise, local knowledge, and machine intelligence co-create solutions (Moleka, 2024b). Human-AI collaboration extends cognitive capacity, while participatory governance ensures socio-cultural alignment. This approach challenges traditional, linear models of innovation by emphasizing co-creation, reflexivity, and emergent dynamics.
- Pluriversal Futures and Cultural IntegrationBy integrating local epistemologies and global scientific knowledge, Innovationology produces pluriversal solutions that respect cultural diversity, social norms, and ecological constraints (Escobar, 2018). Innovation is therefore both context-sensitive and globally informed, fostering adaptability across spatial and temporal scales.
- Future Research and OperationalizationSeveral avenues are critical for extending the science of Innovationology:
7. Limitations and Critical Reflexivity
8. Conclusion and Implications
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