Learning Pathways for Energy Supply Technologies: bridging between Innovation Studies and Learning Rates

Mark Winskela,*, Nils Markussonb, Henry Jeffreya, Chiara Candelisec, Geoff Duttond, Paul

Howarthe, Sophie Jablonskic, Christos Kalyvasf and David Wardg

a Institute of Energy Systems, School of Engineering, University of Edinburgh, EH9 3JL, UK.

b School of Geosciences, University of Edinburgh, EH9 3JW, UK.

c Imperial College Centre for Energy Policy and Technology, London, SW7 2AZ, UK.

d STFC Rutherford Appleton Laboratory, Didcot, Oxfordshire, OX11 0QX, UK.

e Dalton Nuclear Institute, University of Manchester, Manchester, M13 9PL, UK.

f Department of Earth Science and Engineering, Imperial College, London SW7 2AZ, UK.

g Culham Science Centre, Abingdon, Oxfordshire, OX14 3DB, UK.

* Corresponding author: Email: mark.winskel@ed.ac.uk; Address: Institute for Energy

Systems, University of Edinburgh, Kings Buildings, Edinburgh EH9 3JL; Tel. +44 (0) 131 650

5594

AbstractSupporting innovation and learning for different emerging low carbon energy supply

technology fields is a key issue for policymakers, investors and researchers. A range of

contrasting analytical approaches are used, often with little cross-over between them.

Energy systems modelling using learning rates provides abstracted, quantitative and output

oriented accounts, while innovation studies research offers contextualised, qualitative and

process oriented accounts. Drawing on research evidence and expert consultation on

learning for several different emerging energy supply technologies, this paper introduces a

‘learning pathways’ matrix to help bridge between the rich contextualisation of innovation

studies and the systematic comparability of learning rates. The learning pathways matrix

characterises technology fields by their relative orientation to radical or incremental

innovation, and to concentrated or distributed organisation. A number of archetypal

learning pathways are outlined to help learning rates analyses draw on innovation studies

research, and so better acknowledge the different niche origins and learning dynamics of

energy supply technologies. Finally, future research issues are outlined.

1

Keywords

Innovation; learning; niches; pathways; energy; electricity; technology

1. Introduction

National and international policy ambitions for greenhouse gas emissions reduction and low

carbon technology deployment have focused attention on energy system transformation [1,

2]. One of the key dynamics – and uncertainties – associated with this envisaged

transformation relates to the development and deployment of low carbon energy supply

technologies. While technological innovation holds out considerable promise as an enabler

of more affordable energy system change [3, 4], this promise is highly uncertain, particularly

over decades-long timescales.

Technological innovation in the energy sector is driven by a complex mix of incentives and

interests [5, 6], and there is now a large number of emerging low carbon energy supply

technology fields, each supported by particular policy initiatives, investment programmes,

developer firms and research institutions . Making sense of this activity – in terms of

systematic ordering, comparing and assessing its effectiveness and potential – has become a

major policy and research challenge in its own right [3, 7, 8].

A range of tools and frameworks are drawn on, including technology roadmaps [1, 9], energy

system models [3, 10] and explorative scenario planning techniques [11, 12]. Each provides

particular insights. Technology roadmaps specify the anticipated sequences involved in the

progressive commercialisation of emerging technologies in considerable detail. System

modelling provides ‘structured insights’ into the interactions and trade-offs between

different parts of the whole energy system [13, 14]. Explorative scenario exercises consider

alternative possible futures in the context of social and economic trends and potentially

disruptive events [15], and may therefore capture more diverse combinations of envisaged

social and technical futures than either system models or roadmaps.

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These different techniques are not mutually exclusive, and indeed, they are sometimes used

in combination [16]. At the same time, each approach has its limitations and blind-spots.

Roadmaps may under represent the wider socio-technical context for innovation, including

interactions between different technologies and the more socio-political aspects of

innovation, factors which are often especially important for energy technologies. Different

roadmaps may also articulate inconsistent levels of optimism or ambition across different

technology communities. This is especially problematic in early stage technology assessment

because of a lack of any empirical track record, and a tendency to ‘appraisal optimism’ [17]

or even hype [18].

Energy system models, in elaborating a broad system-level view, may over over-simplify,

either by under-representing the uncertainties, contingencies and non-linearities of system

change, or by only allowing for highly aggregated, crude representations of key system

drivers such as technological innovation. Even relatively detailed bottom-up energy system

models tend to characterise supply technologies by a small set of parameters, such as capital

and operating cost, resource availability and conversion efficiency, with innovation dynamics

often represented by a single parameter: the experience (or learning) rate [19] (the term

‘learning rate’ is used in this paper because of its resonance with the concern here for

learning effects). Reducing down innovation processes to a single aggregated parameter

means that many their important properties go unrepresented, such as the qualitative

difference between early stage and later stage innovation dynamics [20], or the often key

role of market diversity, including niche markets, in early stage innovation [21].

Finally, explorative scenarios often provide only rather ‘broad-brush’ characterisations of

socio-technical trends or possible reconfigurations, and tend to lack any detailed account of

the causal mechanisms (agents, institutions and policies) by which their envisaged outcomes

may be realised [22, 23].

Alongside these widely used tools and methods is a body of mainly qualitative social science

research, innovation studies, which also analyses the dynamics of emerging technology

systems. Low carbon energy innovation studies has become a highly active research field

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over recent years, developing and applying frameworks such as Technological Innovation

Systems (TIS) [24-26] and the multi-level perspective (MLP) on system transition [27-30].

Although TIS and MLP have distinctive strengths and weaknesses [31] both provide richly

contextualised and contingent accounts of innovation, in terms of interwoven and co-

evolving social and technical elements; case study research based on them has provided

many detailed accounts of the evolution of energy technology systems [20, 32, 33].

However, despite their common concern to take into account the role of innovation in socio-

technical system change, there is strikingly little cross-over between the abstracted

representations of learning rates and system modelling, and the contextualised, contingent

accounts of innovation studies. The premise for the learning pathways framing outlined here

is that there are missed opportunities for cross-disciplinary interaction here, and in

particular, that innovation studies offer a valuable research resource to enrich learning rates

analysis. For example, learning rates and system modelling tend to see techno-economic

performance, measured as unit cost, as the determining factor on technological change,

while innovation studies highlights a broader set of socio-cultural forces (such as the role of

knowledge flows and information sharing in early stage innovation, political legitimacy and

societal acceptability, and the enabling or blocking role of incumbent organisational

interests) [25, 32, 34].

The aim of this paper is to help bridge between system modelling and innovation studies by

developing a simple analytical framework that allows for systematic comparison of energy

technologies, while retaining some of the contextual richness of innovation studies. The

formidable task of developing a full synthesis of system modelling and innovation studies is

beyond our scope. Instead, we take technology-specific innovation studies as a starting

point, develop a 2x2 matrix to improve its comparability without losing too much specificity,

and then consider the cross-overs or implications for learning rates and system modelling.

Our efforts are inspired and informed by earlier attempts within innovation and

organisational studies at developing comparative frameworks for technology comparison

[35-41]. Within the ‘comparison-oriented’ stream of innovation and organisational studies,

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the learning pathways approach pays particular attention to the differing niche origins of

emerging energy technologies and their different development pathways. By describing a set

of archetypical or generic learning pathways, the prospect is opened up of learning

narratives that are part-contextualised but which also allow technologies to be compared.

The paper proceeds as follows. Section 2 summarises and contrasts system modelling using

learning rates and innovation studies; Section 3 introduces the learning pathways matrix,

drawing on detailed analyses of a few energy supply technologies; Section 4 applies the

learning pathways matrix to compare the niche origins and learning paths of selected

technologies. Section 5 presents a set of archetypal learning pathways for use in technology

forecasting for energy system change. Section 6 summarises and concludes the paper, and

identifies some areas for future research.

2. Review: Perspectives on Technology Learning

2.1 Learning Rates

Learning rates first emerged from historical evidence of cost reduction with cumulative

production in manufacturing industries [42, 43]. The learning rate is the percentage

reduction in technology ‘unit costs’ associated with each doubling of installed cumulative

capacity [44]. Over recent years, in the context of policy targets for energy system change,

learning rates have been used in many energy system modelling exercises [45-47], either

formulated endogenously within the model, or factored-in exogenously using off-model

calculations [48].

The learning rate is a powerful analytical construct, given its apparent ability to capture and

quantify innovation, and project it forwards as a key part of wider socio-technical system

change. In practice, technological innovation is more complex and less predictable than this

suggests, and comparing different technologies on the basis of learning rates disguises

important differences. As a number of observers have recognised, using learning rates for

long-term energy system projections raises particular concerns [43, 49-56]; these include:

the assumed correlation between deployment and cost reduction is not always

observed: history shows examples of some energy technologies, such as nuclear power,

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coal-fired steam turbines and offshore wind energy failing to lower costs despite

significant deployment [57-60].

even when a correlation is observed, the direction of causality is often unclear: unit cost

reductions may result from market growth, or be a driver of market growth [61].

over time, apparently small differences in learning rate estimates have dramatic impacts

on suggested investments needed for commercial breakthrough of individual

technologies, and, at the system level, optimal energy mixes [51, 56, 57].

cumulative deployment is a poor measure of learning for research-intensive

technologies. ‘Two-factor’ learning rates [62, 63] explicitly allow for learning by research,

alongside learning by doing, but they exacerbate the problem of input data

uncertainties. Junginger et al. [18] suggested that time rather than deployment may be a

better indicator of cost reduction potential for R&D intensive technologies.

using a single learning rate for a technology field is likely to disguise significant

contextual diversity over place, time and content:

o energy innovation policies are still determined, to a significant degree, at the

national and sub-national level, and innovation dynamics differ across regions,

nations and organisations

o discontinuities and step-changes in learning are often seen over time, through

different phases of development. Colpier and Cornland [64] distinguished

between price umbrella, shakeout and stability phases; Grubler [65] and Wilson

[66] identified four phases of development, including early phase

experimentation, unit scaling, industry scaling and global diffusion.

o learning effects often differ considerably between the component parts of a

technology system [67].

While these differences are ironed-out over long-run global learning rate studies, they

are significant for those operating at any level of detail, including policymakers, business

strategists and research programme managers.

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The need for improved representations of innovation in learning rates and energy system

modelling has been recognised by modelling researchers. Gielen et al. [68] outlined lines of

enquiry for a ‘technology learning research agenda’, including analysis of clustering of

interrelated technologies, identification of global and regional learning patterns, and

attention to underlying ‘autonomous trends’ such as increased computer capacity and

advanced materials. Berglund and Söderholm [69] suggested linking exogenous assumptions

about learning rates to different assumptions about policy, cumulative capacity and R&D

investment. Clarke et al. [61] (p593) called for study of ‘any distortions of policy conclusions

from models with limited representations of technological change’.

2.2 Innovation Studies

Learning rates are a widely adopted, influential tool, and their refinement has become a

highly active research area in recent years. At the same time, their well-documented flaws

suggest a need to draw on accounts of innovation able to retain greater complexity and

contextualisation. Reflecting its conceptual groundings in evolutionary economics and

sociology, innovation studies – especially in its more technology-rich strands – emphasises

the contingent nature of technological development, and the need to analyse technology

systems in their socio-historical context, rather than by reference to technical or economic

imperatives [70, 71]. A central insight offered by this body of research is that the various

elements that make up a technology system: technical artefacts and knowledge, and also

practices, institutions and expectations, interact together in co-evolutionary and path-

dependent ways over time [31]. Foxon [72] identified five key domains for energy system co-

evolution: technologies, institutions, business strategies, natural ecosystems and social

practices.

Two prominent conceptual frameworks have developed within innovation studies over the

last two decades: the Technological Innovation Systems (TIS) approach [20, 24-26, 32] and

the Multi-Level Perspective (MLP) on system transitions [27-30]. TIS studies emphasise

multiple agency and distributed learning in innovation processes. Rather than all-powerful

technologists, or linear knowledge flows, the focus tends to be on interaction and feedbacks

across different system elements: actors, networks and institutions [73]. Two broad phases

of technology development are often identified: an initial, formative phase, characterised by

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the generation of technological variety, the testing of different designs, interactive learning,

niche markets, and efforts to establish organisational and political legitimacy; and a

subsequent market expansion phase, in which positive feedbacks between market growth,

learning by doing and scale economies enable diffusion of a dominant technology into mass

markets, allowing for the run down of public policy support mechanisms [20, 25, 32].

The MLP conceives technological innovation as an outcome of the interplay of social and

technical elements over three distinct levels of aggregation: micro-level niches, meso-level

regimes and macro-level societal landscapes [74, 75] Within this, ‘system innovations’

(innovations with the greatest impact on the design and character of systems, including their

environmental performance) are seen to originate mainly in radical niches, which over time

become stabilised in dominant designs, and which may subsequently break through to

reconfigure regimes [76]. Case research using the MLP has often involved long-term

historical studies, such as the transition from coal- to gas-based energy supply in The

Netherlands [77]. In the context of the ‘managed transitions’ of energy systems to meet

decarbonisation targets, Shackley and Green [78] suggested that the approach could usefully

supplement modelling and scenario-based analysis. Verbong and Geels [79], for example,

described three different prospective ‘transition pathways’ for the electricity system and grid

infrastructures, based on different niche-regime-landscape interactions. Foxon et al. have

elaborated different transition pathways for UK electricity system transition [16].

The rising prominence of TIS and the MLP in innovation studies provoked some criticism. For

TIS, and innovation systems studies more broadly, criticisms included inconsistencies across

different studies in terms of system delineation and measures of system performance, and

reliance on mainly ex-post qualitative analysis [80, 81]. Criticisms of the MLP included

inconsistent conceptual framing, a neglect of agency, an over-emphasis on niches as drivers

of system change [38, 82]. Later contributions to both theories have sought to respond to

these criticisms. In TIS, this involved the development of a more standard, prescriptive

analytical framework, based on a set of system ‘functions’ (including, for example,

knowledge development, market formation and resource mobilization) [24, 25]. In MLP

studies, in an effort to overcome ‘niche-driven bias’, Geels and Schot [28] introduced a small

set of archetypal transition pathways, based on particular niche-regime-landscape

relationships.

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These later contributions have directed innovation studies towards greater comparability

between different cases. In offering these more standardised accounts, there is a danger of

under-emphasising significant differences of content or context between different

technologies. For example, TIS’s framing by system functions and inter-functional patterns

may fail to capture important differences in niche origin and learning paths (such as different

levels of importance of learning by doing, interacting, and researching, scale economies, or

learning by transfer from other industries [18, 61, 83-85]. Bergek et al. [25] identified a need

for a taxonomy of archetypal development pathways for emerging innovation systems;

Section 5 of this paper offers such a taxonomy.

Case research using the MLP is deeply concerned with niche context, and a particular strand

of transitions research based on ‘innovation journeys’ has paid particular attention to the

shifting dynamics of technology learning over time [33, 86]. Even so, the MLP tends to a

niche-led account of system innovation, with more significant system change arising from

radical and disruptive niches. By doing so, like TIS, it may under-represent the different

origins and learning paths of different technologies, or the powerful role, over time, of

incremental innovation. Smith et al. [87] called for greater attention to be paid to the

plurality of niches and ‘niche-regime’ interactions. The learning pathways matrix can be seen

as a response here, and also, to the prospect of regime-led system innovation under urgent

change imperatives [88]. Foxon [72] has noted the neglect of cost and economic factors in

much innovation studies based on the MLP; this strengthens the case for seeking bridges

between innovation studies and cost-based methods such as learning rates.

2.3 Summary

This section has outlined two contrasting accounts of technological innovation: learning

rates, a highly abstracted, quantitative representation, and innovation studies, a

contextualised and mainly qualitative account. While learning rates and energy system

modelling allow comparison between different technologists, and attention to wider energy

system effects, they are a grossly simplifying measure of complex socio-technical processes,

and well-recognised concerns about their use in technology forecasting. By contrast,

9

innovation studies, while offering rich insight on the socio-technical dynamics of innovation,

has developed standard explanations of socio-technical change which neglect the different

niche origins of technologies, and also, the influence of relative cost.

There has been some recent recognition, from both learning rates and innovation studies

scholars, of the potential rewards of establishing links between these two fields. Junginger et

al. [18] considered the possibilities here, both for historic and prospective studies. Van Sark

et al. [89] suggested that a combination of experience curves and innovation systems could

produce a useful ‘hybrid framework mixing quantitative and qualitative data’ (ibid., p265);

the rest of the paper introduces and applies of one such tool.

3. Method: the Learning Pathways Matrix

3.1 Characterising Technology Learning

The learning pathways matrix is built on detailed analysis of the niche origins and innovation

dynamics of a number of emerging energy supply technologies, developed from reviews of

relevant research literature (both innovation studies and the more economics-oriented

literature of learning rates and energy systems analysis), and also, from consultations with

experts in particular energy supply technologies.

Table 1 summarises some issues highlighted in the research literature and expert accounts

(some of the many research papers consulted are listed in the table). The technology fields

were selected because previous research [2, 10] has suggested their possibly significant role

in UK energy futures. (As well as the five technologies in Table 2, two others – bioenergy and

hydrogen fuel cells – were included in the overall analysis; they are omitted here for brevity).

The focus here is on electricity generating technologies; while this excludes important non-

electricity energy supplies, there are suggestions that electricity may become more

pervasive part of future energy systems [3, 10].

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Field Origins and Development Key Learning Effects

Wind [60, 85, 90-94]

- Onshore wind emerged in the 1970s, mainly from small scale experimental devices which were gradually upscaled.

- Devices underwent rapid upscaling and improvement from the mid-1990s

- Offshore wind is much less mature, and has experienced cost increases typical of early stage technologies

- Onshore wind evolved over decades of learning-by-experience, with later incorporation of learning-by-research.

- Offshore wind innovation dynamics are still unclear, but are likely to differ from onshore, given differences in physical environment, social attitudes and relative costs of capital and operation (with greater emphasis, for example on scale economies).

Marine (Wave and Tidal Flow)[91, 95-97]

- The marine energy field emerged in the 1970s. It re-emerged in the early 2000s, largely by small private developer firms.

- The field is still immature, with limited experiences in operating conditions.

- The field spans a wide variety of designs, especially for wave power, though with some generic aspects.

- Investment focuses on a small number of full-scale prototype devices, which make use of relatively conventional designs and components.

- Given limited learning-by-doing opportunities, many developers focus on learning-by-research though small-scale testing and modelling.

- There is potential for knowledge / technology transfer from related industries, but these face commercial barriers.

Solar PV[32, 98-102]

- The solar PV field emerged in the 1960s within the NASA space programme.

- the field has since greatly diversified its production technologies and market applications.

- PV systems are highly modular, with distinctive system components: modules and ‘balance of systems’ (BoS).

- Learning effects differ for different generations, and between modules and BoS components.

- For 1st generation technology, innovation efforts focus on feedstock, manufacturing and economies of scale. For 2nd and 3rd generation technologies, emphasis is on R&D, e.g. advanced materials for improved efficiencies.

- BoS costs are location and application-specific, and driven by learning-by-experience.

Carbon Capture and Storage (CCS)[88, 103-108]

- CCS as a power plant technology only emerged relatively recently, in the 1990s.

- CCS is an assembly of technologies from chemical processing, power generation and oil and gas

- It involves large scale capital and infrastructure, creating an investment threshold; its development is led by large manufacturing and energy firms

- Learning involves the scaling-up of capture technology, and the integration of capture and power generation.

- Integration with the wider energy system poses multiple technical, economic, organisational and regulatory challenges.

- Three different capture technology types are emerging: post- and pre-combustion, and oxyfuel capture; these present differing levels of continuity or disruptiveness for established fossil fuel interests.

Nuclear Power [58, 59, 109]

- Civilian nuclear power emerged from post WWII nuclear weapons development programmes

- Until the 1980s, nuclear fission technology development was carried out by state-owned ‘national champions’.

- Since the 1990s, a small number of international producers have emerged.

- Nuclear power is a large scale technology system suited to centralised generation and transmission, and ‘fleet build’ economies using standard plant designs.

- It has a poor record of learning with deployment due to changing designs, high construction costs, weak financial scrutiny, complexity of safety systems and costs of regulatory compliance.

- Nuclear fusion involves experimental prototypes developed in highly co-ordinated international public programmes.

Table 2: Niche Origins and Learning Paths of selected Electricity Supply Technologies

3.2 Generic Issues in Energy Innovation

Although there are deep-rooted technical, organisational and institutional differences

between the technologies in Table 2, a comparative reading of the research literature and

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expert accounts revealed a number of common themes related to their innovation

dynamics; these include:

Design variety or consensus: emerging energy technologies tend to span a wide

variety of designs, more mature ones to design consensus and standardisation.

Innovation studies case research has identified an early stage trade-off between

‘variety and volume’, and has recommended an emphasis on variety rather than

scale [20]

Distributed or concentrated organisations: some emerging energy technology

systems are organisationally distributed, while others are highly concentrated.

Innovation studies research has suggested that successful early-stage innovation is

associated with organisationally distributed, highly co-ordinated fields, with strong

feedbacks between developers, users, testers and regulators [85, 90].

Radical or incremental innovation: more mature energy technologies tend to be

characterised by incremental innovation, while less mature fields may emphasise

step-change improvements from radical innovation; however, energy case research

highlights a powerful role of incremental innovation over time [35, 37, 110].

Scale or modularity: innovation studies research points to the advantages of smaller

scale, more modular technologies, which tend to offer greater opportunities for

learning by experience [55], and have greater variety of applications. Larger scale

systems tend to design and application standardisation and replication economies.

While scaling dynamics vary by technology, there is some evidence of historical

patterns and a generic sequence of scaling effects, from small-scale experiments,

technology units, industry sectors and global diffusion patterns [65, 66].

Dedicated learning or technology transfer: technology and knowledge transfer have

been historically important mechanisms for technologies such as wind turbines

(transfer from agricultural machinery [90] and gas turbines (transfer from aerospace

jet engine programmes [111]. However, there are often powerful barriers to

transfer, such as adaptation costs and intellectual property rights.

Niche or mainstream markets: niches offer key opportunities for supporting early

phase learning [21]. Where niches are absent, either though lack of application

variety or dedicated support mechanisms, learning may be limited [33, 98]. Given

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the lack of natural product differentiation, innovation investments for electricity

technologies may be predicated on capturing mainstream market share.

Innovation support policies: innovation studies case research has emphasised the

benefits of market-pull and technology-push policies to be run in parallel, with

strong feedbacks between deployment and research [112]. There is a suggested

tendency to over-emphasise technology push and neglect commercial prospects,

and wider societal influences [33, 98]. Regulations, such as performance standards,

have also been key policies for creating demand for environmental technologies [5].

Sources of finance: private finance is disinclined to support longer term or more

radical innovation, and typically requires high returns over relatively short timescales

[113]. Private capital also tends to favour less capital intensive, more modular

technologies, presenting barriers for scale intensive energy technologies.

System integration: low carbon energy supply technologies have significantly

different operating characteristics than established technologies, with implications

for network management, storage and infrastructure. The technical, organisational

and institutional challenges of system integration may be under-appreciated.

3.3 The Learning Pathways Matrix

To enable comparison between technology fields, the rich socio-technical data outlined in

Sections 3.1 and 3.2 was simplified and abstracted by developing a 2x2 matrix. While this

inevitably involves a loss of case detail, it still allows for important differences between

different cases (in our case, technology fields) to be represented. In their seminal paper,

Abernathy and Clark [34] described this as ‘depict[ing] the pattern of effects [by using]

composite … scales for each domain as the axes of a two-dimensional diagram … with four

quadrants representing a different kind of innovation’ (p.7). The aim here is not to precisely

define the size and position of the cases on the scales, but to use the matrix to

approximately locate technologies with respect to key socio-technical features, trace how

these have changed over time, and compare between different technology cases.

The scales chosen for the learning pathways matrix are (i) the relative emphasis on

incremental or radical innovation; and (ii) the relative degree of organisational concentration

or distribution. Other scales could have been chosen, but as we go on to show, we have

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found that these two are able to capture important aspects of the socio-technical character

of technology fields, and to describe their niche origins and development paths of

technology fields. Clearly, the two dimensions of the LP matrix need to be complemented

with additional information for any comprehensive telling of each technology’s history, but

we believe that the matrix helpfully focuses the analytical gaze onto important features.

Though it draws on several similar framings within innovation studies and organisational

studies, the LP matrix is distinctive. For example, the unit of analysis of the LP matrix is

technology fields, rather than the firms, organisations or more specific technology systems in

organisational studies contributions [35-37, 114, 115]). Also, unlike similar matrices devised

for non-energy sectors, the LP matrix focuses mostly on differences in production systems

rather than application or product differences, since one defining feature of electricity

systems is the lack of product differentiation. (As discussed in Section 4, however,

application or market diversity is important for some electricity technologies, such as solar

PV, and representing this has involved some modification to the LP matrix).

Other 2x2 framings conceived in innovation studies, especially sustainable innovation

studies, share our focus on energy technologies. Even here, there are differences. For

example, while Smith et al. [38] focus on sectoral level transitions, the LP’s attention is on

the lower level of aggregation of technology fields. Also, where Smith et al. [38] distinguish

between different resourcing for transitions (internal or external to regimes), we distinguish

instead between the relative radicalness of different technology fields: these are related

parameters, but the latter is more appropriate for our level of analysis.

Unlike Raven [40] and Kemp [41], the LP matrix makes no upfront distinction between

disrupting niche-led and sustaining regime-led innovations. Instead, following Abernathy and

Clark [35], we seek to represent technology fields as ‘pathways through emerging

landscapes’ which have complex, changing relationships with niche and regime agents and

structures. The LP matrix allows for the possibility that technology fields span different

combinations of disruptiveness or continuity at any point in time, and that these

combinations change over time.

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4. Application: using the Learning Pathways Matrix

4.1 Introduction

In this section we use the LP matrix to trace the historical development of different power

supply technologies, drawing on relevant innovation studies research literature.

Technologies are represented in the matrix as bounded and relatively coherent socio-

technical domains, or fields. Typically, the major share of resources and activities within a

field are directed to more mature, incremental designs, with lesser effort on more radical

designs; this is depicted in the matrix as fat incremental ‘bodies’ with thin radical ‘tails’.

Following Green et al.’s tracing of the evolution of food production and consumption

systems [39], the matrix is also used to show the evolution of technologies over time, shown

as arrows between fields at different times. The position of the fields and the direction of

the arrows in the diagrams is based on research evidence from innovation studies, with

some references provided in the main text; this was supplemented by consultation with

energy technology experts from within our research team.

In Section 5 we use the LP matrix to support discussion of future energy innovation, partly as

a response to the need for rapid decarbonisation of the energy system. This leads to the

presentation of a typology of archetypal learning pathways for different emerging energy

technologies, emphasising that there can be no ‘one-size-fits-all’ policy model, or innovation

theory, for energy supply innovation.

4.2 Historic Learning Pathways

Figure 1 shows the evolution of the onshore windpower technology field, from its

emergence in the 1970s as a mainly distributed and incremental field, to its current status as

a concentrated, mature field, dominated by a small number of international manufacturers

and a dominant design. Historically, the successful innovation system for windpower (with

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origins in Denmark) was characterised, initially, by small-scale developers and the relatively

incremental adoption of conventional components drawn from other sectors [34, 90]. Over

time, this predominantly incremental system was able to incorporate technology and

knowledge from more radical development programmes [85, 91].

Figure 1: Onshore windpower learning (Incremental pathway)

While windpower has developed via a predominantly incremental pathway, from an

organisationally distributed to a concentrated field, Figure 2 characterises nuclear (fission)

power’s development in terms of high levels of organisational concentration, from its radical

origins in the 1940s and 1950s, to its current status as relatively mature technology [4, 109].

Nuclear fusion remains a radical, highly concentrated technology field.

Figure 2: Nuclear Power Learning (Breakthrough pathway)

ConcentratedDistributed

Radical

Incremental

1970s and 1980s 2010T-Transfer from

other fields

T-Transfer from within the

windpower field

ConcentratedDistributed

Radical

Incremental

1970s and 1980s 2010T-Transfer from

other fields

T-Transfer from within the

windpower field

DistributedConcentrated

Radical

Incremental

1940s and 1950s

Gen III

Gen III+

Gen IV

Gen I

2010

DistributedConcentrated

Radical

Incremental

1940s and 1950s

Gen III

Gen III+

Gen IV

Gen I

2010

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While some energy technology fields, such as windpower and nuclear power can be shown

as single, bounded spaces, other fields show more diverse patterns of production and

application. For example, the solar PV field, in commercialising away from its highly

concentrated national public programme niche origin, has diversified in terms of both

product design and market application [99]. Figure 3 shows that solar PV has distinctive

production and application domains, with relatively centralised production fields, of more or

less radical or disruptive character for different generations of PV technology. In essence, the

highly modular character of PV technology has enabled a wide range of product designs and

applications. At the same time, production systems for first generation PV have close

associations with the semiconductor industry: a global high technology field supported by

large commercial and state interests [8, 116].

Figure 3: Solar PV Learning (Diversification pathway)

The matrix was also used to illustrate the learning dynamics of more conventional power

supply technologies. As with solar PV, the combined cycle gas turbine (CCGT) technology

field drew on a state sponsored high technology niche: the jet aero engine. The major

growth phase of the CCGT field from the late-1980s involved a combination of the jet aero

engine field with industrial gas turbines (the latter was a long-established incremental

technology field [111, 117] The CCGT learning pathway can therefore be characterised by

technology transfer and combination (what Hargadon [118] referred to as ‘recombination’)

across two distinctive fields: aerospace and power generation, and two distinctive learning

pathways: incremental and breakthrough. This proved to be a powerful combination, and

since the late-1980s, CCGT has been a mainstay of power generation internationally. The

ConcentratedDistributed

Radical

Incremental

c-Si

20101st Gen

3rd Gen

2nd Gen

1960s

ConcentratedDistributed

Radical

Incremental

c-Si

20101st Gen

3rd Gen

2nd Gen

1960s

17

mature CCGT learning pathway involves highly co-ordinated incremental innovation (Figure

7).

Figure 4: CCGT Learning Pathway (Recombination pathway)

In the late-2000s, an increasingly urgent policy imperative for decarbonisation stimulated

efforts at accelerated innovation for low carbon energy supply technologies, and this has

reconfigured the learning pathways of emerging fields. For example, the marine energy field

first emerged as a radical high-technology niche in the nationalised and concentrated energy

systems of the 1970s, in the wake of the first energy crisis [119]. By the mid-1980s, this

initial dynamism subsided and innovation activity remained low for many years. More

recently, the field re-emerged, but in the much more organisationally distributed energy

system of the late 1990s [97]. In the 2000s, the marine field was characterised by small

developer firms progressing more conventional systems and components, with more radical

devices and components developed in university-based public R&D programmes. More

recently, under a gathering innovation imperative, larger public-private development

programmes have encouraged the participation of utilities and international power

equipment manufacturers [96].

Figure 5 shows the changing learning pathways for the marine energy field. For much of the

2000s, the marine field followed a predominantly incremental pathway, with small firm

Distributed Concentrated

Radical

Incremental

Industrial Gas

Turbines

Combined Cycle Gas Turbines

Jet aero-engines

1930s

1940s

1980s

2010

Distributed Concentrated

Radical

Incremental

Industrial Gas

Turbines

Combined Cycle Gas Turbines

Jet aero-engines

1930s

1940s

1980s

2010

18

developers gradually improving prototypes through learning-by-doing and gradual upscaling;

in parallel, a more radical pathways were pursued in relatively small university-based R&D

programmes. More recently, an accelerated incremental pathway for mature devices has

emerged via strengthened market-pull incentives, and in parallel, a breakthrough pathway

for more radical 2nd and 3rd generation concepts and components has emerged, via

expanded RD&D programmes; the latter shares some breakthrough aspirations of the initial

niche activity of the 1970s and 1980s.

Figure 5: Marine Energy Learning Pathways

5. Prospective Learning Pathways

5.1 Introduction

The marine energy case exemplifies a wider contemporary phenomenon: under a global

accelerated innovation policy imperative, more concentrated and highly co-ordinated

innovation systems for energy supply technologies are being developed nationally and

internationally, as increased resources and incentives attract the participation of larger

private and public organisations. This is a significant shift: for much of its recent history, the

energy sector had little interest in technological innovation, other than the incremental

development of conventional plant, and in some countries, the gradual progression of more

mature renewables technologies such as onshore wind.

Breakthrough Pathway

Incremental

DistributedConcentrated

Radical

Accelerated Incremental Pathway

More Radical Devices and Components

More Conventional Devices and Components

1970s

1980s

2000

2000

2010

2010

Re-emerged Niche

Initial Niche

Breakthrough Pathway

Incremental

DistributedConcentrated

Radical

Accelerated Incremental Pathway

More Radical Devices and Components

More Conventional Devices and Components

1970s

1980s

2000

2000

2010

2010

Re-emerged Niche

Initial Niche

19

While this is an appropriate response – the decades long timescales for incremental learning

in renewables innovation since the 1970s reflected a less urgent system context – history

highlights the risks and potential pitfalls of more co-ordinated ‘top-down’ efforts. In the case

of windpower, the incremental pathway pursued by some countries: distributed, interactive

systems with high levels of early stage design variety – what Garud and Karnøe [90] referred

to as a ‘bricolage’ style of innovation – proved, over time, more successful than the

breakthrough style pursued elsewhere. As others have noted [5, 8] a breakthrough style of

energy innovation may not be suitable responses to the decarbonisation imperative.

5.2 Archetypal Pathways

The analysis presented in this paper suggests that there is no ‘one best way’ response to the

accelerated energy innovation imperative. Table 3 shows the relative strengths and

weaknesses of a number of archetypal or generic learning pathways, articulated with the

help of the learning pathways matrix and by reference to the research literature survey and

expert consultations. The pathways are not mutually exclusive, and may co-exist within a

technology field; for example, the early onshore wind energy field spanned both incremental

and breakthrough pathways. However, the pathways do represent distinctive, coherent and

at times durable socio-technical configurations.

Because different technology fields emerge from distinctive socio-technical niche origins, not

all pathways are feasible for all emerging technologies. For example, the diversification

learning pathway is much more credible for modular technologies with multiple prospective

applications and markets.

Given the major technical, economic and socio-political uncertainties facing energy system

transition, and the absence of any technology ‘silver bullet’ easily able to reconcile

imperatives for decarbonisation, security and affordability, any coherent energy innovation

system should span a range of more emergent and more mature technologies. The added

implication of the analysis presented here is that energy innovation policies – and innovation

20

theories – must also take into account the different learning pathways associated with

different technologies within such a portfolio. This supports other recent suggestions of the

need for more technology specificity in energy innovation policy [120]. Efforts to consolidate

energy innovation institutions and organisations into integrated, unified ‘best-practice’

arrangements [121] are valuable, but recognise the need for a variety of institutional

arrangements for technology-specific learning.

Learning Pathway

(with examples)Typical Learning Effects Pathway Strengths Pathway Weaknesses

Incremental, early stage(e.g. early

onshore wind, marine energy)

Small firms developing adapting components and systems from other sectors. Learning by transfer, by experience, by interacting, gradual upscaling.

Gradual learning over time. Strong feedbacks between developers, users, testers, policymakers and public. Can support design variety and flexibility, avoiding early ‘lock in’.

Long development timescales; no rapid step-change improvements. Niches vulnerable to changing policy context or emergence of rival technologies

Incremental, mature stage(e.g. coal and

gas fired turbine plant, nuclear

fission)

Gradual improvement of mature technology systems by incumbent organisations (utilities, large equipment manufacturers and affiliated research bodies).

Supported by significant institutional, organisational and financial resources within the regime; builds on established capital assets and knowledge bases.

Emphasis on incremental improvements may offer diminishing returns; may offer an inadequate response in a rapidly changing context.

Breakthrough(e.g. nuclear

power, jet engines,

possibly CCS)

Highly co-ordinated and concentrated e.g. defence programmes. Formalised learning by R,D&D..

Capable of step-change improvements across or within technology fields. Can support innovation in underpinning / enabling technologies (e.g. IT, materials).

Risk of early failure, or failure to commercialise over longer term. Weak links to wider society, so risk of public backlash. Needs sustained high levels of public funding.

Diversification(e.g. advanced PV, fuel cells, and advanced

bioenergy)

Small, high technology research groups, firms and networks. Emphasis on learning by research for modules. For applications, emphasis on learning by experience via small scale trials. Multiple niche markets may exist in parallel.

Capable of radical / disruptive innovation. Small scale, modular systems offer many opportunities for learning by experience. Multiple niche markets offer diversity and flexibility, so learning is more likely to be sustained over time.

Limited core resources, so may tend to ‘start-stop’ learning. High cost modules may not commercialise. State-sponsored niches vulnerable to changing policies / rival technologies. May be ‘locked out’ by large scale incumbents.

Recombination

(e.g. early CCGTs,

possibly CCS)

Combinations of technologies, practices or knowledge from multiple fields or sectors. Learning by formal transfer / adaptation, and by experience.

Able to ‘piggy back’ learning investments from other fields and sectors. Novel combinations may enable step change improvements over relatively short timescales.

Transferred technology may be disruptive in its new context; incumbents may resist transfer. Adaptation and collaboration barriers / costs (e.g. IP barriers) may be under-appreciated.

Table 2: Generic Learning Pathways for Electricity Technologies

21

5.3 Learning Scenarios

Reflecting calls by Junginger et al. [18] and van Sark [89] for the incorporation of innovation

theory insights into learning rates analysis, the generic learning pathways described in Table

2 may be used to construct ‘learning scenarios’: coherent, qualitative socio-technical

narratives used as a basis for quantitative datasets of future technology cost-performance

trends. Alternative scenarios could be devised which place more or less emphasis on

different learning pathways or learning effects (R&D, demonstration, deployment,

replication and scaling effects) for different technologies.

Such scenarios should reflect a detailed assessment of the relative prospects of different

pathways for different technologies. For example, credible incremental learning curve

scenarios should not assume cost reductions during the (perhaps long) period of early phase

experimentation. Greater possibilities for step change unit cost improvements may be

associated with a breakthrough pathways, but also, for early-phase cost increases (as more

ambitious socio-technical challenges are confronted), and also, of the prospect of premature

lock-in to high cost designs or societal opposition, manifested in cost terms as increased

costs of regulatory or planning compliance. Figure 6 shows two examples of stylised

incremental and breakthrough learning curves reflecting these dynamics; other learning

curve scenarios should be developed in any systematic analysis.

Figure 6: Stylised Learning Curves for Incremental and Breakthrough Pathways

Incremental Pathway

Breakthrough Pathway

Unit cost

Cumulative Investment or Deployment

Incremental Pathway

Breakthrough Pathway

Unit cost

Cumulative Investment or Deployment

Incremental Pathway

Breakthrough Pathway

Unit cost

Cumulative Investment or Deployment

22

Following Berglund and Söderholm’s [69] suggestion, these scenarios should also be

informed by explicit assumptions on the role policy, regulation and organisational strategy in

promoting particular learning effects and pathways. Useful insight can be provided here on

the diversity of national policies, with technology fields such as CCS and smart grids being

developed in different ways reflecting local orientations to incremental or breakthrough

pathways. Technology learning pathways do reflect particular niche origins, but also, the

social arrangements for their development.

As Sahal [36] described, the set of regulations and institutions which incline technology fields

to different learning paths may be conceived as a socio-technical topography (Figure 7).

Particular technology fields are suited to different landscape conditions: for example, the

solar PV field is well-suited to a decentralised landscape. The relationship between

technology learning paths and the wider energy and economy landscape is a key area for

further research.

(a) Concentrated System Landscape (b) Distributed System Landscape

Figure 7 : Sociotechnical Landscapes for Learning Pathways

6. Summary and Conclusion

Technological innovation holds out a compelling promise as an enabler of the envisaged

transformation of energy systems. However, this promise is highly uncertain, and there are

multiple ways of analysing and comparing the dynamics of emerging technology systems.

This paper considered two contrasting methods for comparing emerging technology

systems: learning rates, a quantitative, abstracted and output-orientated approach, and

innovation studies, a qualitative, contextual and process-oriented approach.

Radical

Dis

tribu

ted

Con

cent

rate

d

Incremental

Con

cent

rate

d

Dis

tribu

ted

Radical

Incremental

23

While learning rates and innovation studies both address the uncertain promise of

innovation, they are almost entirely unrelated research fields. The premise in this paper has

been that there are opportunities here for bridge-building, and especially, that innovation

studies can inform and enrich learning rates and system modelling. As a contribution to this

developing agenda, and drawing on detailed accounts of technology specific learning, a

number of generic issues were identified, and two of these – the orientation to radical or

incremental innovation, and organisational concentration – were selected as the axes of a

learning pathways matrix.

The learning pathways matrix sets out a socio-technical landscape for locating and

comparing the origins and learning paths of different technologies. Though simplifying and

abstracting, it retains sufficient complexity to capture important differences in the socio-

technical character of different technologies. Drawing on historic pathways, a small number

of generic learning pathways were elaborated to bridge over to learning rates scenarios.

There are limitations to the framework outlined here. More attention is needed on how to

represent the prospect of radical change such as highly decentralised electricity production

and consumption, of changes in ‘enabling’ technologies such as electricity storage, and for

demand-side technologies, such as more or less centrally co-ordinated arrangements for

smart metering. More work is also needed on systematically differentiating between the

production and application parts of technology systems. Finally, the landscape would need

further development to explore the multi-regime aspects of socio-technical transitions [122,

123].

Nevertheless, the learning pathways approach has highlighted important differences in the

niche origins and learning dynamics of energy supply technologies which tend to be

neglected within learning rates and also, innovation studies. For both policymakers and

innovation theorists, the implied need is to take seriously the specificities of energy

innovation, and the varied conditions for learning for different technologies.

24

Acknowledgements

This research was undertaken as part of the research programme of the UK Energy Research

Centre, supported by the UK Research Councils under Natural Environment Research Council

awards NE/C513169/1 and NE/G007748/1.

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Biographical Notes

Mark Winskel is an applied social scientist working on energy supply and energy systems problems based at the Institute for Energy Systems, University of Edinburgh. His research addresses the dynamics of innovation in energy systems, especially the relationship between technological change, investment and policy. He is as Research Co-ordinator for the UK Energy Research Centre (UKERC); he led UKERC’s research on Technology Acceleration for Future Sources of Energy, part of UKERC’s whole energy system research programme.

Nils Markusson is a sociologist of technology, with 16 years worth of experience of studying technological innovation, and with a background in engineering and innovation studies. He works as a researcher at the University of Edinburgh, mainly at the Scottish Carbon Capture and Storage research centre, studying carbon capture and storage and other low-carbon innovations. He is predominantly a qualitative researcher, and favoured data sources include documents and interviews, analysed as case studies, but also has experience of, for example, statistical analysis, scenario-based work and foresight methodologies. He mainly use concepts and models from Science and Technology Studies (STS) and Innovation Studies.

Henry Jeffrey is a Senior Research Fellow at the Institute for Energy Systems, University of Edinburgh. He has extensive energy sector experience of working in marine renewable energy, both in academia and industry. He was a key member of the project team that installed the worlds first commercial, grid connected wave energy generator. He has extensive experience and demonstrable success in delivering project results, and co-wrote the UK Energy Research Centre road map for marine energy that has been widely adopted by the sector across Europe, Canada and the USA.

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Chiara Candelise is an experienced energy economist. Her research interests span from techno-economic assessment of PV technologies to wider economic and policy analysis of energy and climate change issue. She has contributed to several research projects including the UK academic and industrial consortium PV Supergen 21 – PV Materials for the 21st Century, several UK Energy Research Centre (UKERC) projects and Intelligence Energy Europe (IEE) BioSolEsco Project. Prior to that she has built up sound experience on economics and policy. She worked as economist for several private and public institutions, including the UK Department for Environment, Food and Rural Affairs (Defra).

Dr Geoff Dutton is a senior research engineer in the Energy Research Unit at STFC Rutherford Appleton Laboratory in the UK. He is a Chartered Engineer, a member of the Institution of Mechanical Engineers, and a theme leader in the Supergen Wind Energy Technologies project. He provided technical expertise on wind energy to the UK Energy Research Centre’s Energy 2050 project.

Paul Howarth is Managing Director of the UK’s National Nuclear Laboratory. Paul co-founded the Dalton Nuclear Institute at the University of Manchester. Prior to working at the University, Paul spent eleven years with the BNFL Group and progressed from Commercial Manager to Head of Technology for Nuclear Generation and eventually Programme Director for Advanced Reactors and Head of Group Science & Skills Strategy.

Sophie Jablonski is an Energy Engineer at the European Investment Bank, where she focuses on investments in renewable energy and energy efficiency. She holds a PhD in Energy Technology and Policy from Imperial College London, an M.Phil in Environmental Science from the University of Cambridge, and an M.Sc in Engineering from Ecole Centrale Paris (France). Sophie was previously a Research Associate at Imperial College Centre for Environmental Policy in London. She also worked at the World Bank in Washington DC, where she was dealing with energy and transport infrastructure operations in the Middle East & North Africa region.

Christos Kalyvas is Research Fellow, holding an EPSRC/NPL Post-Doctoral Research Fellowship at Imperial College London, focussing on novel diagnostic techniques for the study of fuel cells. Previously, Christos was a Research Associate at the Department of Earth Science and Engineering, Imperial College, specialising in the performance of catalysts for solid oxide fuel cells.

David Ward is a Senior Researcher at the Culham Centre for Fusion Energy (CCFE) and Visiting Fellow at the Smith School of Enterprise and the Environment, University of Oxford. He has worked in energy research for over 20 years as part of the UK fusion research programme and the wider European programme. Much of this time he worked on secondment to JET, the main European fusion experiment, based at Culham Science Centre in Oxfordshire. David now leads the UK work on DEMO, a demonstration power station. He also takes a strong interest in developments in other future energy technologies and leads UK work on socio-economic aspects of fusion.

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