ABSTRACT
Clean modern energy and improved waste management are two well-recognised challenges
in the global transition to sustainable development. There exist synergistic opportunities in
simultaneously tackling the two issues via the generation of bioenergy from suitable waste
streams. This potential has been successfully exploited elsewhere in the world; however,
South Africa, despite having significant potential, lags behind in the implementation of these
technologies and the respective conditions to use them. To understand slowly evolving
technology trajectories and how to facilitate the pace of implementation, sustainability
transition approaches such as the Technology Innovation System (TIS) framework have been
found to be useful.
The aim of this thesis is to explore the utility of a TIS approach to investigate how the
potential of waste-based bioenergy in South Africa can be unlocked to recover energy from
waste using anaerobic digestion technology (EfWviaAD). Going beyond previous TIS studies,
this thesis also aims to experiment with aspects of the TIS approach, so as to observe steps
towards implementation. Key to the TIS approach is the notion of critical activities and
processes around an emerging technology called system functions. Seven of these system
functions detailed in Chapter 2 are proposed. These include knowledge development and
diffusion, market forming activities, mobilisation of resources etc. The thesis sets out to
answer two key research questions:
The first question seeks to establish whether the technology innovation system approach be
used to locate and describe elements of technological transitions in South Africa’s nascent
energy-from-waste industry, using the seven functions proposed by Hekkert et al. (2007)?
Also whether insights gained from testing the TIS approach on the more mature solar
water heater technology are useful in describing the evolution of the anaerobic digestion
industry in South Africa?
Results of TIS analyses show that the emergent Biogas Innovation System (BIS) can indeed
be identified and its evolution described using the TIS approach. By assessing the
applicability of the TIS approach in the context of the solar water heater (SWH) sector in
South Africa, insights on how these transitions evolved were gained. Subsequent to the SWH
study, the TIS approach was employed to examine South Africa’s BIS. For both of these
technologies, the periods of notable inertia are characterised by the occurrence of few critical
activities, which do not reinforce one another, and if they do, it is downwards directed
reinforcement of so-called vicious cycles. The periods of increased momentum are
symbolised by the individual fulfilment of system functions, and their cumulative
reinforcement into so-called virtuous cycles. This thesis shows that, for the BIS, six of the
seven key system functions suggested by the TIS approach are heavily involved at the end of
the period studied play a crucial role in facilitating the evolution of the BIS into a system
building mode. The absence of market formation activities limits the extent to which the BIS
can be propelled into a sustained market dynamic, as observed elsewhere in more mature TIS,
as well as in the case of the SWH Innovation System (IS) in South Africa. In addition, this
thesis finds that the seven TIS functions described in Chapter 2, adequately described the
trajectories of the SWH IS and BIS. Moreover, the results also identify some elements that
are unique to transitioning economies. For example, resources are mobilised and knowledge
is developed in a unique way. Grants, donor funds and climate change finance have been
observed to ignite knowledge development activities, which themselves are dominated by
pilot projects and feasibility studies, as opposed to the technical research that is observed in
more mature economies.
Locating the status of innovation and technology development and identifying limitations to
its growth was the first step in more effectively exploiting the potential in the use of
bioenergy in South Africa. The question of how to influence the course of development
positively is captured by the second research question:
Which of the seven functions can academic research most influence and strengthen? How
would one go about influencing identified functions, consequently contributing to
improved operation of an innovation system?
It was hypothesised that of the seven system functions, this project could most likely
influence BIS through knowledge-based functions, viz. knowledge development and
diffusion. A participatory action-based approach was adopted to plan and participate in three
knowledge development and diffusion activities. The former entailed planning and
implementing two biogas pilot projects, and the latter entailed organising and hosting a
specialist workshop with identified BIS actors. The impact of these interventions on the BIS
was tracked via semi-structured interviews with the pilot projects’ visitors on the one hand
and the workshop participants on the other hand, at least one year after the visit. The results
show that the intervention, through the described activities and events, led to a number of
other activities considered critical to the evolution of a TIS. On the one hand, the knowledge
development activities led to other activities that fulfilled other knowledge-related TIS
functions and those that give clarity to the direction of the BIS. The knowledge diffusion
activity on the other hand contributed to the fulfilment of all the other TIS functions – except
for the resource mobilisation and market formation function.
In summary, this thesis firstly reaffirms that systemic approaches to understanding
technology transition, in this case the TIS framework, are useful in locating and explaining
technology trajectories. The notions of system functions and cumulative causation describe
why the mere presence or absence of certain activities or events (barriers and drivers) does
not sufficiently explain technology success or failure. In fact, it is the interaction of specific
factors that explains the emergence of technological innovation systems and their
development into mature markets. Further, it has been demonstrated that planned
interventions by a set of actors (in this case the emergent South African BIS) can steer a TIS
towards a more mature structure and functionality
Melamu, R (2021). Waste-Based Bioenergy: Operationalising Technology Innovation System Analysis to Go Beyond Assessments of Potential into Implementation. Afribary. Retrieved from https://afribary.com/works/waste-based-bioenergy-operationalising-technology-innovation-system-analysis-to-go-beyond-assessments-of-potential-into-implementation
Melamu, Rethabile "Waste-Based Bioenergy: Operationalising Technology Innovation System Analysis to Go Beyond Assessments of Potential into Implementation" Afribary. Afribary, 25 Apr. 2021, https://afribary.com/works/waste-based-bioenergy-operationalising-technology-innovation-system-analysis-to-go-beyond-assessments-of-potential-into-implementation. Accessed 27 Nov. 2024.
Melamu, Rethabile . "Waste-Based Bioenergy: Operationalising Technology Innovation System Analysis to Go Beyond Assessments of Potential into Implementation". Afribary, Afribary, 25 Apr. 2021. Web. 27 Nov. 2024. < https://afribary.com/works/waste-based-bioenergy-operationalising-technology-innovation-system-analysis-to-go-beyond-assessments-of-potential-into-implementation >.
Melamu, Rethabile . "Waste-Based Bioenergy: Operationalising Technology Innovation System Analysis to Go Beyond Assessments of Potential into Implementation" Afribary (2021). Accessed November 27, 2024. https://afribary.com/works/waste-based-bioenergy-operationalising-technology-innovation-system-analysis-to-go-beyond-assessments-of-potential-into-implementation