ORIGINAL PAPER

https://doi.org/10.1007/s10037-023-00193-6
Review of Regional Research (2023) 43:291–316

The geography of environmental innovation: a critical
review and agenda for future research

Sebastian Losacker1,2 · Hendrik Hansmeier3,4 · Jens Horbach5 ·
Ingo Liefner4

Accepted: 2 July 2023 / Published online: 18 July 2023
© The Author(s) 2023

Abstract This article provides a critical literature review on the regional determi-
nants of environmental innovation. The analysis of the relevant literature on supply-
side factors, demand-side factors, and institutional factors reveals the importance
of regional determinants in green technology development. Specifically, regional
R&D collaborations, university-industry collaborations, and technological related-
ness have positive effects on innovation activities in green domains. On the demand
side, regional environmental awareness and demonstration effects play a pivotal role
in the emergence and diffusion of environmental innovations. Environmental regula-
tions also induce environmental innovation, however, there is only limited evidence
at the regional level. Our literature review has informed the development of an
agenda for future research, which suggests three avenues for further investigation.
Firstly, we recommend abandoning the simple green vs. non-green dichotomy and
conducting more technology-sensitive studies on the determinants of environmen-
tal innovation. Secondly, we call for a more sophisticated and critical engagement
with regional institutions, with a focus on both formal and informal institutions.
Lastly, we propose a demand-side turn in research on the regional determinants of
environmental innovation in order to better understand their diffusion across space.
Overall, our findings suggest that policymakers need to adopt a more nuanced and

� Sebastian Losacker
sebastian.losacker@geogr.uni-giessen.de

1 Department of Geography, Justus Liebig University Giessen, Giessen, Germany

2 CIRCLE—Center for Innovation Research, Lund University, Lund, Sweden

3 Fraunhofer Institute for Systems and Innovation Research ISI, Karlsruhe, Germany

4 Institute of Economic and Cultural Geography, Leibniz University Hannover, Hanover, Germany

5 Faculty of Business, University of Applied Sciences Augsburg, Augsburg, Germany

K

https://doi.org/10.1007/s10037-023-00193-6
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292 S. Losacker et al.

comprehensive approach to eco-innovation policy, one that considers the spatial and
multi-level governance challenges and promotes inclusive regional development.

Keywords Environmental innovation · Geography of innovation · Sustainability
transitions · Regional development · Green technology

1 Introduction

The emergence and diffusion of environmental innovations is of utmost importance
to combat and mitigate negative environmental impacts brought about by human-en-
vironment interactions. Environmental innovations can contribute to solving global
challenges at the regional level, with regions being key arenas for developing envi-
ronmental innovation, for pioneering their application, and for promoting widespread
use and diffusion.

In recent years, the analysis of environmentally related innovations has become an
increasingly popular research topic in regional studies, which is evident, for exam-
ple, from multiple dedicated sessions at the ‘Geography of Innovation’ conferences
and growing numbers of research articles. Moreover, researchers from the broader
fields of innovation studies or environmental economics are increasingly focusing on
regional factors in their research as well (Antonioli et al. 2016; Cainelli et al. 2012;
Horbach 2014; Horbach and Rammer 2018). Consequently, a large body of litera-
ture has emerged in recent years that, to put it concisely, addresses the geography
of environmental innovation.

However, the literature on the geography of environmental innovation in re-
gional studies is very heterogeneous, with different communities exploring different
phenomena. Broadly speaking, we can distinguish three main (partly overlapping)
strands of research. (1) The first strand focuses on green technological innovations
and tries to understand which regional determinants matter for the development and
diffusion of these technologies (e.g. Barbieri et al. 2020b; Galliano et al. 2022; Li
et al. 2021; Losacker et al. 2023; Montresor and Quatraro 2020; Ocampo-Corrales
et al. 2021; Santoalha and Boschma 2021). This field originates from the traditional
literature on the geography of innovation at the intersection of economic geogra-
phy and innovation studies, mainly using quantitative analyses of innovation data
on the regional level. The field strongly builds on early work on the determinants
of environmental innovation, which has long been blind to spatial aspects and re-
gional contexts (Barbieri et al. 2016; Hojnik and Ruzzier 2016; Horbach 2008;
Rennings 2000). We will focus on this strand of research in this paper. (2) A second
and related research strand deals with the production of environmental innovations
and their markets, studying green industries and green regional development (e.g.
Bækkelund 2022; Gibbs and O’Neill 2017; Grillitsch and Hansen 2019; Trippl et al.
2020). This field predominantly draws on insights from the literature on evolutionary
economic geography and new industrial path development. (3) A third community
of researchers is working in the field of sustainability transitions and investigates
which spatial factors contribute to the diffusion of environmental innovations, which
might enable socio-technical change beyond the regional level (e.g. Binz et al. 2014,

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The geography of environmental innovation: a critical review and agenda for future research 293

Table 1 Main research strands on environmental innovation in regional studies (own compilation)

Field of
research

(1) Regional determinants
of environmental innovation
and green technologies

(2) Green regional indus-
trial path development

(3) Geography of sustain-
ability transitions

Aim Understanding (regional)
determinants of green tech-
nology development and
diffusion

Understanding how re-
gions can establish green
industrial paths

Understanding multi-
scalar dynamics of socio-
technical transitions

Conception
and oper-
ational-
ization of
geography

Regional factors for the
development and diffusion
of green technologies;
(inter)regional spillovers;
administrative borders of
regions

Development of green
industries in different
types of regions; regional
and extra-regional factors

Regional, national and
global transformation
processes; Local-global
interdependencies; Multi-
scalar and relational per-
spectives on space

Conception
of innova-
tion

Technological innovations Green industries supply-
ing technological, product
or service innovations

Technological and non-
technological innovation,
including social innova-
tion

Innovation
phase

Focus on inventions and
innovation development;
Few studies on innovation
adoption and diffusion

Focus on the production
of green technologies,
goods and services (i.e.
green industries)

Focus on innovation dif-
fusion and socio-technical
regime change; Niche
development

Methodology Mainly quantitative analy-
ses and econometric meth-
ods; cross-sectional and
panel designs; quantitative
innovation data (i.e. patents,
firm data)

Mainly qualitative anal-
yses and case-based
studies; single case or
multi case study designs;
qualitative interview and
document data

Mainly qualitative analy-
ses and case-based studies;
single case or multi case
study designs; qualitative
interview and document
data

Intellectual
origin

Literature on geography of
innovation; Literature on
determinants of environ-
mental innovation

Literature on regional
path development; Evolu-
tionary economic geogra-
phy

Science and technology
studies; Literature at the
intersection of human
geography and transition
studies

The classification into these three strands of research is not clear-cut, but rather a broad synthesis of the
main research directions. Of course, research overlaps to some extent.

2020; Miörner and Binz 2021; Rohe and Chlebna 2021; Späth and Rohracher 2012;
Strambach and Pflitsch 2018). We compare these different fields of research in more
detail in Table 1.

As outlined above, the literature on environmental innovation in regional studies
is fragmented across several research fields and, in consequence, the regional studies
community lacks a critical overview of the importance of regions in the development
and diffusion of environmental innovations. The scholarly fields mentioned above
focus on different stages of the innovation process (e.g. invention, production, dif-
fusion), employ different epistemological and methodological approaches, and have
different understandings of why and how geography matters for environmental inno-
vation. Scholars in regional studies might therefore struggle to assess the importance
of regional (subnational) factors for environmental innovation.

While there are important review articles at the intersection of regional studies
and environmental innovation (Coenen et al. 2012; Grillitsch and Hansen 2019;
Truffer and Coenen 2012), we feel that they emphasize multi-scalar and exogenous

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294 S. Losacker et al.

processes that affect regional innovation activities in green domains. In recognition
of these important contributions, we argue that a review and agenda of explicitly
endogenous or region-internal factors is still missing in the literature. A seminal
contribution on regional factors has been put forward by Hansen and Coenen (2015).
However, they address regional transition paths towards sustainability and the role
of regions for the transition of socio-technical systems, which are long-term and
complex transformation processes of sectors. This paper will focus on regional
factors shaping the innovation process of green technologies that eventually enable
deeper system changes. In other words, we are interested in understanding regions,
not sectors (see also Boschma et al. 2017, p. 7). We therefore consider our paper
complementary to the previously mentioned contributions. As such, this paper will
focus on regional drivers of green technology development and diffusion (research
strand 1 in Table 1). We will occasionally refer to important insights from the other
two research streams throughout the paper.

Apart from that, we argue that previous research on regional drivers of environ-
mental innovation has been unbalanced. Analyses of the regional conditions affecting
the generation of environmental innovations tend to dominate, while the equally im-
portant aspects of scaling-up and diffusion have so far been under-researched. In
order to fill these gaps, this article has two main objectives. Firstly, the article aims
to review the current state of research on regional determinants of environmental
innovation and green technologies, including both innovation emergence and dif-
fusion. We thus seek to identify region-specific factors that can explain why some
regions show better conditions for environmental innovation than others. Secondly,
drawing on our critical review, the article aims to develop an agenda for further
research on the geography of environmental innovation and green technology in
regional studies.

The remainder of this article is structured as follows. In Section 2, we discuss the
conceptual background and the characteristics of environmental innovation and how
they are relevant from a regional perspective. Section 3 encompasses the literature
review, summarizing regional supply-side and demand-side determinants as well as
regional institutional and political determinants of environmental innovation that
have been identified in previous research. In Section 4, we provide suggestions for
future research. In this context, we point to important lessons from transition studies
and path development literature such as accounting for technology-specific dynamics
and regional informal institutions. We also indicate methodological advances that
have so far been insufficiently exploited in regional research on green technologies.
Lastly, we call for a demand-side turn in research on the geography of environmental
innovation. Our concluding remarks as well as implications for policy are presented
in Section 5.

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The geography of environmental innovation: a critical review and agenda for future research 295

2 Environmental innovation: what is it and why should we care about
its geography?

An environmental innovation or (eco-innovation)1 is a ‘[...] new or improved prod-
uct or practice of a unit that generates lower environmental impacts, compared to the
unit’s previous products or practices, and that has been made available to potential
users or brought into use by the unit’ (Kemp et al. 2019, p. 35). This definition builds
on earlier approaches (Arundel and Kemp 2009; Rennings 2000) and summarizes
the core meaning in a relatively straightforward way: an environmental innovation
is new and is introduced to the market (innovation part, see also OECD Oslo Man-
ual), and it reduces environmental harm (environmental part). The environmental
effect of eco-innovations can stem from lower resource use (e.g. energy efficiency),
lower levels of pollution (e.g. filtering technologies) or any other form of reduced
negative environmental impacts. Other definitions might further discern whether the
beneficial effects on the environment are intended or not, they might distinguish
between innovations according to the degree of environmental impact or they might
explicitly include social or organizational innovations as well. That said, the use of
the term environmental innovation in this article is largely limited to green technolo-
gies, goods and processes, and disregards other forms of innovation (e.g. business
models). It is important to note that the review in this paper is therefore also limited
to technological innovations. However, this does not imply that the regional level is
less important for non-technological environmental innovations.

From a social science perspective, green technologies and environmental inno-
vations feature some interesting peculiarities and they therefore differ from regular
technologies and innovations. Arguably the most important peculiarity of environ-
mental innovations is the so-called double-externality problem. That is to say, they
generate positive spillovers in two phases: innovation development and innovation
diffusion. The former is a general problem of innovations. Organizations that invest
in R&D produce knowledge that can be used by other organizations which, how-
ever, do not bear any of the costs. This chronic problem of free-riding is prevented
mainly through governmental R&D subsidies, first-mover advantages and an elab-
orate intellectual property rights system. However, environmental innovations also
produce positive spillovers in the diffusion phase, as adopters contribute to reducing
negative environmental impacts. While this has a non-excludable positive effect on
other organizations and on society as a whole, adopters alone bear the costs. Ac-
cordingly, this double-externality problem might cause firms and other organizations
to underinvest in environmental innovations (Beise and Rennings 2005; Jaffe et al.
2005; Rennings 2000).

1 We treat the terms eco-innovation and environmental innovation as synonyms in this paper, as do many
other researchers in the field (Hojnik and Ruzzier 2016). However, we do acknowledge that the two terms
evolved from different academic fields and might therefore be used differently in the literature (Ekins 2010;
Franceschini et al. 2016). For instance, the term environmental innovation is frequently used to describe
environmental policy induced technological innovations, following the innovation inducement hypothesis.
The term eco-innovation, on the other hand, is usually used more explicitly to describe innovations that
contribute to positive environmental effects.

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296 S. Losacker et al.

The second distinctive feature of environmental innovation is a natural conse-
quence of the double-externality problem. Environmental innovations require reg-
ulatory support to be successfully developed and compete in the market. From an
innovation economics perspective, technology push and demand pull mechanisms
provide an explanation for the emergence and diffusion of ordinary innovations, but
an additional triggering force, a regulatory push/pull, is required to stimulate en-
vironmental innovations (Rennings 2000). Regulations tend not only to encourage
innovation, but can even help offset the costs of innovation development and lead to
increased profits for the innovator. Environmental regulation can thus deliver a win-
win situation for competitiveness and for the environment through its knock-on ef-
fect on environmental innovation. This phenomenon is commonly referred to as the
Porter hypothesis and is yet another feature of environmental innovation (Porter and
van der Linde 1995; Rexhäuser and Rammer 2014).

Alongside these peculiarities, empirical research on environmental innovations
and green technologies has uncovered a number of stylized facts that can be used
to differentiate them from non-green innovations. One important insight is that
green technologies differ from regular innovations in terms of complexity. Green
technologies generally require a higher degree of R&D cooperation and external
knowledge in the developmental phase (De Marchi 2012; Ghisetti et al. 2015; Orsatti
et al. 2020b; Quatraro and Scandura 2019), they rely on more novel and complex
knowledge inputs (Barbieri et al. 2020a) and they require higher levels of technical
expertise and cognitive skills to be developed (Consoli et al. 2016).

However, environmental innovations and green technologies do not form a ho-
mogeneous group. Instead, they can be further subdivided on the basis of various
characteristics such as technological domain or field of application, leading to both
different modes of innovation and different modes of valuation and market forma-
tion (Binz and Truffer 2017). Green technologies also differ in scale, with some
green technologies relating to large infrastructure systems and others relating to
consumer goods (Wilson et al. 2020). These technology-specific characteristics of
course translate into differences in the innovation and diffusion process. Most of the
peculiarities and stylized facts described above are, however, assumed to be common
to all environmental innovations.

Based on these insights, numerous empirical studies have examined the determi-
nants of environmental innovation in great detail (Hojnik and Ruzzier 2016; Horbach
2008, 2016, 2019; Horbach et al. 2013). Essentially, three different groups of deter-
minants can be distinguished, most of which take effect on the level of the innovator
and/or innovation adopter:

� Supply-side determinants (e.g. technological capabilities, competitive advantages)
� Demand-side determinants (e.g. expected market demand, environmental aware-

ness)
� Institutional and political determinants (e.g. environmental policies and regula-

tions)

This classification of the determinants of environmental innovations is well es-
tablished in the literature and widely used in empirical studies. However, it largely
ignores region-specific factors. Apart from the institutional and political determi-

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The geography of environmental innovation: a critical review and agenda for future research 297

nants, where some have an implicit geographical nature due to being linked to
jurisdictions, the importance of geography and regional factors has received rela-
tively little attention in empirical research on environmental innovation (Horbach
2014). This is surprising, given that the potential of environmental innovation and
green industries for regional development has been discussed intensely for many
years. In this context, it is generally assumed that green industries can have posi-
tive effects on regional economies and regional development (Capasso et al. 2019;
Gibbs and O’Neill 2017). Countries and regions with strong green industries, ex-
porting complex green goods, are, in fact, found to have increased capabilities to
further innovate in green technologies while having lower CO2 emissions (Mealy
and Teytelboym 2020). Regions in which green industries thrive are also less af-
fected by external economic shocks, meaning that green industries improve regional
economic resilience (Vona et al. 2019). However, because green industries typically
involve specialized jobs and rely on high levels of human capital, they present un-
even growth opportunities for regions with varying factor endowments (Consoli et al.
2016; Sofroniou and Anderson 2021). Many of the peculiarities of green technolo-
gies, for example their complexity and their dependence on institutional support,
also affect their geographical distribution, both in terms of innovation development
and in terms of spatial diffusion. Given these impacts on regions, their economies
and their environments, it is of significant value to better understand the regional
determinants of environmental innovation, complementing existing knowledge on
the general determinants listed above.

3 Critical review on regional determinants of environmental innovation

3.1 Review methodology and scope

In this section, we review the literature that deals with supply-side, demand-side and
institutional conditions affecting environmental innovation that are determined or co-
determined on the regional scale. While there are already useful systematic literature
reviews that deal with the determinants of environmental innovations (Barbieri et al.
2016; Hojnik and Ruzzier 2016; Horbach 2019), we limit our review to those studies
that help understanding why and how regions matter for environmental innovation.
The review mainly draws on scholarly work from the regional studies community
(see Table 1, especially research strand 1). However, we also include work from
related disciplines that have an explicit implication for environmental innovation
on the regional level. From a methodological perspective, our critical review of the
literature on the regional determinants of environmental innovation follows a semi-
systematic and integrative approach (Snyder 2019). The search process was initi-
ated by conducting keyword searches in Web of Science and Scopus, building on
a recently developed search string (see Hansmeier 2021 and Appendix). In addition,
we performed citation searches on key articles identified during the initial search.
Furthermore, we handpicked relevant publications based on expert knowledge. In-
clusion criteria for the articles were that they had to have implications for research
on environmental innovation in regional studies and regional science. All articles

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298 S. Losacker et al.

Fig. 1 Determinants of environmental innovation (own figure, based on Rennings 2000; Horbach 2008,
2019)

were reviewed and analyzed in detail, with a particular focus on the determinants of
environmental innovation that have an explicit geographic dimension.

As mentioned before, three different groups of factors have been examined in
detail in the eco-innovation literature: supply-side determinants, demand-side de-
terminants, and institutional and policy determinants (Horbach 2008). While most
of these determinants, particularly the pull factors that relate to expected market
demand, take effect on the firm or innovator level (Horbach 2019), many deter-
minants such as environmental regulations or technological capabilities and R&D
activities on the supply side bear an explicit geographic dimension. For the critical
review, we therefore use the established tripartite classification of the determinants
of environmental innovations and reflect on them from a regional angle. We use this
classification in particular because of the intellectual origins of this literature in the
non-spatial analysis of environmental innovations and thus refrain from using an es-
tablished classification from the regional studies literature (e.g. Hansen and Coenen
2015). In Fig. 1, we present the three groups of determinants, adding the regional
dimension to each of these factors. Of course, basic regional characteristics such
as demographics, infrastructure, socioeconomic development or environmental and
physical-geographical factors will also play a role for environmental innovation. An-
other important regional characteristic is the local banking and financial (sub)system.
The spatial organization and geographical concentration of the banking and financial

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The geography of environmental innovation: a critical review and agenda for future research 299

Table 2 Regional determinants of environmental innovation

Regional supply-side determinants

Green technologies are (on average) more complex than non-green technologies and therefore require
additional (local) knowledge and research inputs

Universities and other research facilities play a particularly important role for green technology develop-
ment due to local knowledge spillovers, local human capital supply and university researchers involved in
collaborative R&D processes

Green technologies generally benefit from additional external knowledge and open innovation modes,
which emphasizes the relevance of efficient green regional innovation systems

Regions and countries are more likely to diversify into green technologies if local technological capabili-
ties are related, even if a region is specialized in related dirty technologies

Relatedness to the local technological capabilities will also increase the probability that a region special-
izes in green technologies

A local knowledge base that is diversified over unrelated technologies (unrelated variety), will be more
important for the development of green technologies that are in the early stage of the life cycle, while
mature green technologies benefit from related variety

Regional demand-side determinants

The demand for environmental innovation triggers the emergence of green industries in a given region
(local demand-pull)

The agglomeration of pioneering firms that use environmental innovations will increase the likelihood
that other firms in the region will also adopt green technologies

Similar demonstration effects occur on the level of individuals and households, with geographic proxim-
ity to early adopters increasing diffusion rates

Regional environmental awareness and green political orientation induce the development and diffusion
of green technologies

Regional institutional and political determinants

Environmental regulations and policies trigger market demand for green technologies that local firms and
other innovators are likely to respond to, increasing regional green technology development

Environmental regulations and policies in a given region or country force the adoption of cleaner tech-
nologies, counteracting the double-externality problem associated with the diffusion of environmental
innovations

Based on innovative and stringent environmental policies, regions and countries might become lead mar-
kets that demonstrate the benefits of an environmental innovation

Regulations and policies in other regions might trigger green technology development in the focal region

Place-based innovation policies that combine supply-side and demand-side rationales can trigger regional
environmental innovation

The diffusion of environmental innovations also depends on informal institutions such as technology
legitimization, which can differ profoundly between regions

The results presented in this table are largely based on quantitative studies using established innovation
indicators such as patent data. Many of these studies treat green technologies and environmental innova-
tions as a homogeneous group of technologies. However, doing so fails to acknowledge the heterogeneity
and specificity of many environmental innovations. While the results are certainly valid for the majority of
green technologies, they should not be interpreted as universally applicable. Given that we predominantly
review quantitative studies, we provide only limited information on factors that are difficult to measure
(e.g. informal institutions).

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300 S. Losacker et al.

system differs greatly between countries, with some countries having a very cen-
tralized financial system and others having a more decentralized financial system
(Klagge and Martin 2005). In any case, both the development and the diffusion of
environmental innovations will depend on the systemic conditions offered by the
regional financial and banking subsystem, e.g. driven by local availability of green
venture capital (Demirel et al. 2019). In addition, extra-regional factors and multi-
scalar processes are crucial for understanding how environmental innovations emerge
and diffuse in regions (see among others Binz and Truffer 2017; Castellani et al.
2022; Njøs et al. 2020), which is why we have included these factors in the figure
even though we do not consider them in the paper. Figure 1, in that sense, visualizes
the underlying conceptual framework of this article and the structure of Sect. 3.
Table 2 provides an overview of the most important insights on the determinants
of the geography of environmental innovation that have received much attention in
the literature so far. It is important to note that some of the findings presented in
this Section relate to more than one group of determinants. For instance, regional
environmental awareness can be considered as a demand side determinant while
also being a region-specific informal institution. Another example are regional de-
ployment policies that trigger demand for green technologies. This exemplifies that
many factors as well as the groups of determinants are interdependent.

3.2 Regional supply-side determinants

On the supply side, determinants of environmental innovation mainly involve the
technological capabilities of the innovator, including input factors such as R&D and
(external) knowledge (Hojnik and Ruzzier 2016; Horbach 2008, 2019). These input
factors for (environmental) innovations, however, depend not only on the innovating
organization itself, but particularly on external knowledge, research collaborations
and local knowledge spillovers, which the literature on the geography of innovations
and regional innovation systems (RIS) has been demonstrating for more than two
decades (Asheim et al. 2016). Regional innovation systems refer to the networks,
institutions, and organizations that promote innovation and knowledge exchange in
a specific geographic area. They are characterized by the close interactions between
actors, such as universities, research institutions, firms, and public agencies, which
create an environment conducive to innovation. RISs play an important role in pro-
moting economic development by facilitating the creation, diffusion, and application
of new knowledge and technologies within a particular region (Cooke et al. 1997;
Tödtling et al. 2022). However, given their higher complexity (Barbieri et al. 2020a),
green technologies will need additional (local) knowledge and research inputs when
compared to regular innovations. A number of studies have analyzed these addi-
tional efforts needed for the development of environmental innovations, many of
which include explicitly geographical features. For instance, Horbach (2014) finds
that environmental innovations benefit more from spatial proximity to universities
and research institutions than regular innovations. In addition, green technologies are
more likely to emerge when academic inventors are involved in their development
(Quatraro and Scandura 2019) while they also require higher human capital inputs
(Horbach 2014). These empirical findings emphasize the importance of universi-

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The geography of environmental innovation: a critical review and agenda for future research 301

ties in ‘green regional innovation systems’ (Cooke 2010; Radinger-Peer and Pflitsch
2017), marking them as crucial actors in analyses of (the geography of) environmen-
tal innovations. The findings also highlight the complexity of green technologies, as
they depend on more knowledge inputs that might be sourced from local partners
or universities. Other supply-side regional determinants of green technology devel-
opment include, inter alia, local knowledge stocks, agglomeration economies, and
public research subsidies (Arranz et al. 2019; Corsatea 2016; Giudici et al. 2019). In
that regard, it is noteworthy that green technologies are more likely to be invented
in regions that are generally characterized by high technological capacity (Corradini
2019). Moreover, green technologies often stem from teams of inventors who are
able to creatively recombine existing knowledge (Orsatti et al. 2020b). They also
generally require a higher degree of R&D cooperation and external knowledge in
the developmental phase (Cainelli et al. 2015b; De Marchi 2012; De Marchi et al.
2022b; Ghisetti et al. 2015; Horbach et al. 2013). Collaborative R&D processes
will be particularly beneficial to environmental innovation emergence if partners
are located in close geographic proximity (Ardito et al. 2019; Cainelli et al. 2012;
Chiarvesio et al. 2015). The majority of the studies reviewed so far focus on the
innovator and how the regional context as well as regional knowledge spillovers
can lead to the development of green technologies. The findings carry important
implications. That is to say, efficient innovation systems and open innovation modes
will be crucial for successful eco-innovation efforts, with regions being a promising
scale for innovation emergence. In other words, efficient green regional innovation
systems are conducive to the development of green technologies because they fa-
cilitate the creation, diffusion, and application of new knowledge and technologies
within a particular region, with universities, research institutions, firms, and pub-
lic agencies all playing important roles in developing these systems (Cooke 2010,
2011).

Additional insights can be gained from an evolutionary perspective on green tech-
nology development in regions, shifting the focus from eco-innovators to the regional
level. Much of this literature builds on the relatedness approach, stating that regional
knowledge development depends on the availability of related knowledge in the re-
gion (Balland 2016). For instance, regional diversification into green technologies
will depend on the local existing competencies, with relatedness playing a major
role (Perruchas et al. 2020). Against this background, relatedness is relevant for
green diversification processes irrespective of the technological domain, with some
green technologies emerging in regions specialized in fossil fuel technologies (San-
toalha and Boschma 2021; van den Berge et al. 2020). In other words, regions have
many opportunities to diversify into the development of green technologies drawing
on their existing competencies. However, Barbieri et al. (2020b) find that the role
of related knowledge bases for developing green technologies will also depend on
the technology life cycle. They show that unrelated variety, i.e. a local knowledge
base that is diversified over unrelated technologies, will be more important for the
development of green technologies that are in the early stage of the life cycle. For
inventing mature green technologies, on the other hand, related variety will be more
important. Technological relatedness also affects regional specialization processes,
with relatedness increasing the likelihood of a region specializing in green technolo-

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302 S. Losacker et al.

gies. In that sense, the local availability of key enabling technologies and digital
skills is found to moderate the effect of relatedness on green regional specialization
(Montresor and Quatraro 2020; Santoalha et al. 2021). While the literature reviewed
in this section offers many important insights into green technologies and their re-
gional drivers, many of the findings certainly do not apply to every green technology
in the same way. More specifically, in many empirical studies, green technologies
are treated as a homogeneous group, thereby failing to consider technology-specific
characteristics.

3.3 Regional demand-side determinants

While demand-side determinants of environmental innovations have traditionally
been associated with characteristics of the innovator or adopter, i.e. anticipating
future market demand, high levels of environmental consciousness and environ-
mental awareness (Horbach 2008), demand-side factors can also take effect on the
regional level. The demand for environmental innovation can, in fact, trigger the
emergence of green industries in a given region, highlighting the importance of lo-
cal demand-pull mechanisms (Bednarz and Broekel 2020). Moreover, it is found that
environmental awareness differs between regions or countries and positively affects
the development of environmental innovations and the creation of green start-ups,
which is a unique feature of environmental innovations when compared to non-green
innovations (Corsatea 2016; Giudici et al. 2019; Horbach 2016). Regional demand
can thus induce the development of environmental innovations. However, regional
demand-side determinants might play a more important role in the diffusion phase.
Many environmental innovations are very specifically tied to local environmental
conditions and/or environmental problems and therefore tend to have strong region-
alized demand and market formation processes (Binz and Truffer 2017). This does
not apply to products in mass markets such as electric vehicles, but ranges from
renewable energies (e.g. dependence on wind, sun, water) to climate change adap-
tation technologies (e.g. flood protection or water scarcity technologies). However,
most quantitative studies on green technologies neglect these technology-specific
features.

In addition, innovation diffusion is a social process in which early adopters can
influence further potential adopters to use an innovation (Rogers 1962). This process
unfolds through various channels of information exchange, being both simpler and
more likely in geographical proximity (Hägerstrand 1967). While these diffusion
mechanisms apply to all types of innovations, it is very likely that they are more im-
portant for environmental ones. Given the assumption that many potential adopters,
particularly firms, often fail to anticipate the benefits of environmental innovations
due to incomplete information as well as organizational and coordination problems,
it is reasonable to conclude that demonstration effects from peers are particularly
important for the diffusion of environmental innovations (Montalvo and Kemp 2008;
Porter and van der Linde 1995). In fact, several lines of evidence suggest that the
agglomeration of pioneering firms that use environmental innovations will increase
the likelihood that other firms in the region will adopt environmentally benign tech-
nologies as well (Antonioli et al. 2016; Cainelli et al. 2012; Horbach and Rammer

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The geography of environmental innovation: a critical review and agenda for future research 303

2018), emphasizing the importance of local demonstration effects for environmental
innovations. Of course, demonstration effects are not limited to innovation diffusion
in firms, they also occur on the level of individuals or households, for instance in the
case of PV installations (Graziano and Gillingham 2015; Wolske et al. 2020). Given
that technological complexity hinders innovation diffusion in space (Balland and
Rigby 2017), it is reasonable to assume that many green technologies characterized
by high complexity will diffuse more slowly compared to non-green technologies.
However, evidence on this relationship is scarce (Losacker et al. 2023).

3.4 Regional institutional and political determinants

It has long been recognized that regulations and policies are key to environmental
innovation (Dupuy 1997; Jaffe et al. 2005; Rennings 2000). Internalizing exter-
nal costs associated with the adoption of environmental innovations by means of
adequate policies and regulations implies that administrative areas such as cities,
provinces or nations with stringent environmental policies have higher diffusion
rates of environmental innovations than areas with rather lax policies (Cainelli et al.
2015a; Frey 2012; Popp 2010;Woerter et al. 2017). Essentially, the same inducement
effect applies to the diffusion of environmental innovations as to their development.
While from a theoretical viewpoint, regulations ought to counteract the double-ex-
ternality problem in the diffusion phase (Jaffe et al. 2005; Rennings 2000), they also
induce the invention of green technologies, and not merely their use. More stringent
environmental policies will lead to an increase in green technology development in
a given region or country, with different types of policy instruments being effective
for different green technology domains (Dechezleprêtre and Sato 2017; Johnstone
et al. 2010, 2012). The immediate consequence of this causal relationship is an
uneven distribution of green innovation output (and use) across space. Stringent
policies that promote innovation development and diffusion in a region or country
can, moreover, result in a so-called regulatory advantage that favors the creation
of a lead market for environmental innovation, eventually driving global diffusion
processes (Beise and Rennings 2005; Losacker and Liefner 2020). However, from
a geographical perspective, the role of regulation and policies is much more com-
plex. It is possible, for instance, that foreign environmental policies induce domestic
green technology development and vice versa (Dechezleprêtre and Glachant 2013;
Herman and Xiang 2019; Popp 2006). In particular, policies on the national or supra-
national level can foster the diffusion of environmentally benign technologies, for
instance via carbon pricing (Baranzini et al. 2017). In fact, most studies on the effect
of environmental regulation and policy on the development and diffusion of environ-
mental innovations are at the level of nation states. The importance of regulation at
the subnational level is less frequently studied, but might show similar inducement
effects (Cao et al. 2019; Corsatea 2016; Losacker and Liefner 2020). One reason for
the poor scholarly engagement with the innovation inducement effects of regional
environmental regulations is the limited data availability on regional policies and
policy stringency, with some authors using proxies such as political support to envi-
ronmental protection or the regional exposure to regulations (Castellani et al. 2022;
Losacker 2022; Santoalha and Boschma 2021). However, most countries simply de-

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304 S. Losacker et al.

sign environmental policies on the national (or supra-national) level, with exceptions
for a few countries and specific local environmental concerns (e.g.waste regulations
in China, see Losacker and Liefner 2020).

On the regional level, place-based innovation policies are important to support
green industries and to leverage the application of sustainable technologies. In that
sense, it is important to support both green technology development, i.e. the supply
side, and diffusion processes, i.e. the demand side, depending on the regional con-
text and place specificities (Hansmeier and Losacker 2021; Tödtling et al. 2021).
In fact, regional administrative bodies exhibit great potential to support diffusion
processes using green public procurements, also nurturing early market formation
and early adoptions (Ghisetti 2017; Lauer and Liefner 2019; Nesterova et al. 2020).
Green public procurement, however, also exhibits positive effects on future green
technology development within a region (Orsatti et al. 2020a).

While most of the studies mentioned so far focus on formal institutions such as
regulations and policies, mainly driven by the double-externality problem associ-
ated with environmental innovation, less is known about the role of region-specific
informal institutions (cultural-cognitive and normative institutions). In that regard,
scholarly work in transition studies and regional path development provides useful
insights. For instance, the diffusion of environmental innovations depends very much
on legitimization or, in other words, on the willingness of consumers to adopt an
environmentally benign technology (Bergek and Mignon 2017; Hekkert et al. 2007).
As technology legitimization results particularly from place-specific factors such as
localized informal institutions, legitimacy will differ between regions, leading to
differences in diffusion rates across space (Heiberg et al. 2020; Rohe and Chlebna
2021). Moreover, regional legitimacy for a particular green technology is likely to
depend on informal institutions and legitimacy of other technologies and industries
in the region, underlining the local nature of cognitive and normative institutional
support for environmental innovation (Jolly and Hansen 2022; Punt et al. 2022).

4 Suggestions for future research

As outlined in Sect. 3, several traditional determinants of environmental innovation
bear an explicit regional imprint and scholars in regional studies have studied these
factors assiduously. However, there are many open challenges that we have not been
able to tackle. In this section, we propose three avenues for further research on
the geography of environmental innovation, aiming at understanding the drivers of
green technology development and diffusion in regions:

� Accounting for technology-specific dynamics and critically reflecting on the pre-
dominant binary distinction between green and non-green technologies.

� Exploring novel empirical opportunities to study both formal institutions, such
as environmental regulation, and informal institutions, such as the legitimacy of
technologies at the regional level.

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The geography of environmental innovation: a critical review and agenda for future research 305

� Shifting the focus of regional research on green technologies from innovation de-
velopment towards the demand side and thus the diffusion of environmental inno-
vations.

Again, the agenda mainly addresses the first research strand as depicted in Table 1.
In order to inform and motivate the agenda, we will refer to other research strands
on environmental innovation in regional studies, i.e. the geography of transitions and
the green regional path development literature. On a personal note, we feel that there
is limited interaction between these different research communities despite apparent
shared concern about environmentally friendly regional development. We believe
that this lack of scholarly exchange is due in part to differences in the preferred
methodological approaches where the first strand of research predominantly relies
on quantitative methods and econometric models, while the other two tend to work
in a more case study-based manner using qualitative research designs. An implicit
goal of this agenda is to bridge the divide between these communities. We believe
that it will be very promising for the first research strand to integrate the conceptual
and theoretical advances of the literature on green path development and transition
studies into their quantitative research designs, which will also help the latter two
fields to ‘reach for generic insights between cases’ (Köhler et al. 2019, p. 18). One
crucial issue in this regard is the empirical operationalization of green technologies,
where many quantitative studies fail to acknowledge insights from transition studies.

4.1 Towards technology-sensitive research

Most of the research papers that we have reviewed in Sect. 3 treat green technologies
as a homogenous technology group, ignoring technology-specific dynamics. This is
striking given the extant literature in transition studies that highlights how the impor-
tance of geographical scales for innovation and market formation processes differs
between technological domains (Binz and Truffer 2017). As such, it is unclear to
what extent the regional determinants of green technology development and diffu-
sion described in Sect. 3 might vary across different technological domains. This
is not only true for differences between technologies with local markets (e.g. wind
power) and global markets (e.g. electric vehicles), but also for differences between
granular (e.g. solar PV) and large-scale (e.g. CCS) technologies (Huenteler et al.
2016; Wilson et al. 2020). While all these technologies are considered ‘green’, they
have distinct (spatial) characteristics in terms of technology development and, more
importantly, in terms of diffusion. For instance, green technologies in the energy
or transportation sectors face additional diffusion barriers due to sunk costs of ex-
isting physical infrastructure and local assets that strengthen unsustainable regimes
(Negro et al. 2012; Unruh 2000). For example, transportation, supply infrastruc-
tures and waste infrastructures correspond to and perpetuate existing patterns of
urban land use and the use of established types of buildings, and are thus extremely
difficult to change. Moreover, in the energy sector, markets are often shaped by nat-
ural monopolies, i.e. access to infrastructure. These monopolistic bottlenecks hinder
the market entry of new innovating firms, limiting sustainable action to dominant
incumbents (Walz 2007). These barriers directly translate into regional path-depen-

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306 S. Losacker et al.

dencies, making it more difficult for some regions to develop and diffuse certain
types of green technologies (Martin and Sunley 2006; Truffer et al. 2015). Another
promising but so far under-researched technological field in this regard are circular-
economy innovations, which are likely to show a distinct regional pattern (Anto-
nioli et al. 2022). More generally, it is questionable to what extent some of the
‘stylized facts’ on environmental innovation described in Sects. 2 and 3 might be
invalid for certain green technologies. For instance, while green technologies are
found to be, on average, more complex than non-green technologies (e.g. Barbieri
et al. 2020a) and to depend on high levels of (regional) knowledge inputs (Cainelli
et al. 2015b; Horbach 2014), additional research is required that digs deeper into
variation of these stylized facts between technological domains. This will help to un-
derstand the regional determinants of green technology development in more detail,
considering both place-specificities and technology-specificities. Future research on
green technologies in regional studies should thus go beyond the use of green tech-
nology domains as simple ‘control’ variables and engage more meaningfully with
technological characteristics.

4.2 Solving empirical challenges on regional institutional factors

In Sect. 3.4, we have pointed to the fact that institutional factors, both formal in-
stitutions such as regulations and informal institutions such as societal norms or
beliefs, will contribute to how successful a region can develop and diffuse green
technologies. Yet, several challenges remain in empirically measuring institutions,
making it difficult to assess their importance against other factors. For formal in-
stitutions, it is evident that regulations and environmental policy play a decisive
role in the development and diffusion of environmental innovations. However, most
empirical studies examine this relationship at the (inter)national level rather than at
the (inter)regional level. Since regions face different environmental pressures and
demands, regional differences in regulation and environmental policy do exist in
some cases, e.g. in waste management or air pollution. We feel that there is much
room for further research on regional regulations, particularly for countries with
strong regional governments (China, Germany, USA, etc.) where differences in en-
vironmental policy stringency between regions are pronounced. However, in most
cases, environmental policy is implemented at the national (and sometimes supra-
national) level. Still, this does not mean that regions are homogeneously affected by
these environmental policies. In fact, environmental regulations will affect regions
differently, for example depending on the local industrial structure. Environmental
regulations at the national level therefore have varying regional impacts, which at
the same time translate into different regional incentives for green technology de-
velopment and use. Empirical studies therefore can choose to not directly monitor
regional environmental policy, but rather the regional exposure to environmental pol-
icy. Some empirical studies already use this approach to measure regional effects of
regulations (Castellani et al. 2022; Losacker 2022), yet the same problem arises that
we discussed in Sect. 4.1. That is to say, empirical studies fail to acknowledge tech-
nological and sectoral specificities within the green technology sphere. For instance,
studying the effect of the regional exposure to one pollutant (e.g. NOx) on regional

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The geography of environmental innovation: a critical review and agenda for future research 307

green technologies, does not do justice to the scope of green technologies that exist
(e.g. from water treatment technologies to climate change mitigation). To counteract
this problem, we propose two possible approaches. Either studies need to be more
technology specific and stop treating green technologies as a homogeneous group
(see Sect. 4.1), or studies need to take into account the multi-dimensionality of envi-
ronmental policy. The latter means that regional indicators of environmental policy
must also take into account the variety of environmental regulations, and not just
encompass one pollutant or one environmental problem. This also raises the need
for research approaches employing multi-level designs that take into account both
regional and national policy factors. In this context, there is also a need for further
research on the synergies or conflicts between environmental policy and innovation
policy (van den Bergh et al. 2011), and the multi-level governance thereof.

Given the significance that eco-innovation researchers attach to the role of formal
institutions such as environmental policy and regulation, they often neglect the role
of informal institutions (cultural-cognitive and normative). While informal institu-
tions, predominantly the regional legitimization of green technologies, are already
being studied in the geography of transitions and regional path development liter-
ature, quantitative evidence on their impact on green technologies is still lacking
(Jolly and Hansen 2022; Rohe and Chlebna 2021). We believe that research on the
regional determinants of environmental innovation has much to learn from the afore-
mentioned literature on the legitimacy of green technologies and at the same time
can contribute to improving the empirical evidence on that relationship. We also
feel that eco-innovation researchers do not per se underestimate the importance of
informal institutions, but merely fail to operationalize and measure them empirically
at the regional level. While some initial attempts have been made in regional studies
(Punt et al. 2022), we argue that the potential of studying regional informal institu-
tions remains unexploited. There are various sophisticated methods for measuring
legitimacy and norms based on textual data, and research on this topic is evolving
rapidly, as are the machine learning and natural language processing techniques used
(e.g. Dehler-Holland et al. 2022; Weiss and Nemeczek 2021). However, these studies
have so far been blind to spatial issues. We therefore argue that the combination of
modern techniques for measuring informal institutions and innovative regionalized
textual data sources (e.g. Ozgun and Broekel 2022) have huge potential for mapping
the regional legitimacy for a given green technology. In summary, we suggest that
researchers working on regional determinants of environmental innovation need to
interact more closely with other fields, both in terms of theoretical concepts and in
terms of methodological advances in order to unveil the effects of institutions.

4.3 Towards a demand-side turn in regional research on green technologies

One of the most important issues in the geography of environmental innovation liter-
ature, in our view, relates to technology adoption and diffusion. Traditional research
on the geography of innovation has for many years focused on the regional hotspots
of innovation development. As a result, researchers were able to gain a broad un-
derstanding of the regional (supply-side) factors that contribute to the emergence of
innovations (Asheim et al. 2016). However, this perspective is not sufficient for the

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308 S. Losacker et al.

analysis of environmental innovations, since environmental innovations only unleash
their positive effects on the environment when they are widely diffused. Put simply,
society will not solve ecological and climate crises by inventing green technologies,
but they must be adopted on a large scale. This implies that we not only need to
understand which regional factors contribute to the emergence of innovations, but
we need to comprehend, in particular, which regional factors on the demand side
facilitate the market success and adoption of environmental innovations (see also
Gibbs 2006). Research on the geography of environmental innovation should thus
refrain from focusing too much on the supply-side factors for the development of
green technologies. In contrast, more attention should be paid to regional factors
relating to the diffusion of green technologies. The demand side is already receiving
increasing attention in the two related research strands on environmental innovations
in regional studies (see Table 1). In the literature on green path development, it is
generally assumed that the regional industry structure poses significant opportunities
and challenges for different types of regions (Grillitsch and Hansen 2019). Yet, little
research has been conducted on how the regional industry structure relates to the
use and diffusion of green technologies. Research should not only focus on how
regions can build green industries to drive employment and regional development.
Instead, future research should focus on how the existing (or new) local industries
can use green technologies to establish more environmentally friendly production
processes.

Furthermore, research in transition studies has already identified many factors
that influence the use and diffusion of green technologies from a socio-technical
perspective (Hansen and Coenen 2015). However, many of these factors have not
been sufficiently studied in empirical research, and we believe that there needs to
be a general turn in research on environmental innovation. This demand-side turn
in geographical research on green technologies will have far-reaching consequences
for the way research is designed. First and foremost, the research focus will shift
to regions that are typically ignored in the literature, such as rural areas that do
not contribute to the development of innovations. However, these regions are in
a significant position to use environmental innovations, e.g. in energy, agro-food or
in transportation sectors, and to provide feedback effects on the further development
of green technologies. Secondly, researchers will need to develop methodological
approaches that capture the use of green technologies rather than their development
in order to successfully unveil the regional dimension of innovation diffusion (e.g.
Losacker 2022).

5 Conclusion

This article set out to achieve two research objectives, which were (1) a critical
literature review of the regional determinants of environmental innovations and
(2) the development of an agenda for future research in regional studies on the
geography of environmental innovations.

(1) After conducting a critical analysis of the relevant literature, we have iden-
tified the significance of regional factors in driving the development and diffusion

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The geography of environmental innovation: a critical review and agenda for future research 309

of green technologies. Our findings highlight the positive influence of regional de-
terminants, such as regional R&D collaborations, university-industry collaborations
and technological relatedness. Furthermore, regional environmental awareness and
demonstration effects have been found to play a crucial role in the emergence and
diffusion of environmental innovations. Although evidence at the regional level is
somewhat limited, we find that environmental regulations also contribute to eco-in-
novation activities. (2) The insights gained from our literature review have paved the
way for future research endeavors, suggesting three avenues for further investigation.
Firstly, we propose moving away from a simplistic green vs. non-green categoriza-
tion and conducting more nuanced studies that take into account specific technolog-
ical contexts. Secondly, we advocate for a comprehensive and critical exploration of
regional institutions, encompassing both formal and informal institutions. By doing
so, we can deepen our understanding of their influence on environmental innovation.
Lastly, we propose a demand-side turn in research on the regional determinants of
environmental innovation to understand the diffusion of green technologies across
space. Shifting the research focus to less innovative regions could lead to greater
use of environmental innovations and ultimately, positive environmental effects.

Given the synthesis of the rich literature in the field of the geography of en-
vironmental innovation, our review and agenda for future research have important
implications for (regional) policy, particularly in the fields of innovation and envi-
ronmental policy. While it is widely acknowledged that a well-designed policy mix
combining supply-side and demand-side instruments is necessary to support green
technology efforts, there has been less critical scrutiny of the spatial reach and multi-
level governance of such an approach (Hansmeier and Losacker 2021; Tödtling et al.
2021; van den Bergh et al. 2011). Innovation policy tends to be region-specific, while
environmental policy is typically established at the national level, leading to gover-
nance challenges in harmonizing the two. Regional governments should thus design
innovation policies in a place-based fashion and pay attention to their interplay
with regional or national environmental policies, which are often sector-specific or
technology-specific. Our review also highlights the potential of regional public pro-
curement to promote the development and diffusion of environmental innovations
and contribute to environmentally friendly regional development. However, regional
resource endowments may result in increasing interregional divergence, with envi-
ronmental innovations emerging and diffusing only in prosperous regions, thereby
reinforcing socio-economic disparities. Policymakers face the challenge of mak-
ing the green transition as inclusive as possible. Overall, our findings suggest that
policymakers need to adopt a more nuanced and comprehensive approach to eco-in-
novation policy, one that considers the spatial and multi-level governance challenges
and promotes inclusive regional development.

Last but not least, there is at least one more crucial issue that we need to men-
tion in this article. That is to say, while the focus of this paper explicitly lies on
regional factors for the development and diffusion of environmental innovations,
we would like to emphasize the value of a global and multi-scalar perspective that
we have largely ignored in this paper, as global and extra-regional processes, both
in innovation development and in market formations, are essential for many green
technologies. This relationship has not only been investigated in transition studies

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310 S. Losacker et al.

(Binz et al. 2014; Binz and Truffer 2017) and in the regional path development
literature (Njøs et al. 2020; Trippl et al. 2018) but is increasingly recognized in the
literature on (regional) determinants of green technologies as well (Castellani et al.
2022; De Marchi et al. 2022a). On a personal note, this theme might be a good
starting point for more scholarly exchange between the different research streams in
the future, which we would like to encourage.

6 Appendix

The semi-systematic and integrative approach to the literature review that we adopt
in this paper builds on methodological considerations discussed by Snyder (2019).
The search strings we used for the initial scoping of the relevant literature were
developed by Hansmeier (2021).

Search string in Scopus TITLE-ABS-KEY ( ( “eco-innovation” OR “environ-
mental innovation” OR “sustainab* innovation” OR ( ( clean-tech OR cleantech )
PRE/0 ( innovation OR industr* OR sector OR “start-up” OR startup ) ) OR ( green
PRE/0 ( innovation OR “tech* development” OR “industr* development” OR “tech*
innovation” OR growth OR diversification OR entrepreneur* OR “start-up” OR
startup ) ) ) AND ( geograph* OR ( spatial PRE/0 ( scale OR dimension OR con-
text ) ) OR ( local PRE/0 ( scale OR context OR development OR knowledge OR
network ) ) OR ( regional PRE/0 ( scale OR level OR development OR econom* OR
diversification OR branching OR analys* ) ) OR ( ( transnational OR international )
PRE/0 ( linkages OR level ) ) ) ) AND ( LIMIT-TO ( SRCTYPE , “j” ) )

Search string in Web of Science TS=((“eco-innovation*” OR “environmental in-
novation*” OR “sustainab* innovation*” OR ( ( clean-tech OR cleantech ) NEAR/0
( innovation* OR industr* OR sector* OR “start-up*” OR startup* ) ) OR ( green
NEAR/0 ( innovation* OR “tech* development” OR “industr* development” OR
“tech* innovation*” OR growth OR diversification OR entrepreneur* OR “start-
up*” OR startup* ) )) AND ( geograph* OR ( spatial NEAR/0 ( scale* OR dimen-
sion* OR context* ) ) OR ( local NEAR/0 ( scale* OR context* OR development
OR knowledge OR network* ) ) OR ( regional NEAR/0 ( scale* OR level* OR
development OR econom* OR diversification OR branching OR analys* ) ) OR
( ( transnational OR international ) NEAR/0 ( linkages OR level )))) and Articles
(Document Types)

Acknowledgements An earlier version of this paper has been presented at the annual AK Industriegeogra-
phie meeting in November 2021. We thank all participants for their comments. We are particularly grateful
for critical comments by Johan Miörner on the working paper version of this article during the EU-SPRI
Winter School on Geography of Innovation at CIRCLE in Lund, Sweden, in February 2022. A previous
version of this paper has been published as a working paper with CIRCLE (Papers in Innovation Studies
no. 2021/15). We acknowledge financial support from the German Research Foundation (DFG Li981/18-
1) and from the German Federal Ministry of Education and Research (BMBF 031B1281).

Funding Open Access funding enabled and organized by Projekt DEAL.

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The geography of environmental innovation: a critical review and agenda for future research 311

Open Access This article is licensed under a Creative Commons Attribution 4.0 International License,
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you give appropriate credit to the original author(s) and the source, provide a link to the Creative Com-
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are included in the article’s Creative Commons licence, unless indicated otherwise in a credit line to the
material. If material is not included in the article’s Creative Commons licence and your intended use is not
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from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.
0/.

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