While facing pressure caused by an uncertain climatic situation, increasing urbanization and demand for food production, and in view of the scientific knowledge produced to tackle or mitigate the possible outcomes, it is pertinent to ask how exactly science is included to decision-making processes at the different government levels. For example, how receptive are municipal authorities to existing science, regarding the sustainable management of their natural resources? The construction of scientific knowledge, as well as the gap felt between scientific production and decision-making have been issues of concerns for the experts assessing the Millenium Ecosystem Assessment carried on between 2001 and 2005, in an ex-post effort to determine the underlying factors responsible for restricting the scope of the overall achievement (Reid et al., 2006). Apart from concluding on the importance to incorporate local and traditional knowledge to scientific rendering of ecosystems’ dynamics, the experts stated that two other factors should be prioritized: the integration of multiscalar analysis to understand how ecological processes and human impact are carried on at the smaller scale of an ecosystem, and at the scale of individual communities; and that the findings should be informed and returned for ex-post evaluation to the multiple stakeholders sharing the resources and the responsibility within the limits of an ecosystem.

To follow up with these results, this paper uses the scale of a watershed to explore the challenges faced by a particular city, in order to grasp how knowledge surrounding water management is built and exchanged at multiple scales; how it is adopted and adapted by local managers; and how stakeholders in the watershed basin come together to co-manage the resource. The Grand River watershed in Southern Ontario has been chosen, and more specifically the city of Guelph, in view of the existing collaborative channels and the dynamic citizen involvement regarding the common goal of improving water management practices, and the health of the watershed. Actor-Network Theory (ANT) is applied as an approach facilitating the analysis of the pan-Canadian network that brought a number of water experts on the Guelph territory, and which seems to act as an attracting nexus for water innovations nowadays.

Although the Southern Ontario context has been favourable to the emergence of water awareness, the biophysical limits of the city of Guelph—with its limited supply of fresh water, over-burdened aquifers, and risk of drought—have increased the urgency of collectively achieving sustainable management of the resource (O’Flanagan, 2015; Veale, 2015). If we add to this the growth threshold imposed by the Ontario government to reduce population pressure in Toronto through its 2006 Growth Plan, and the immediate reaction of elected officials of the City of Guelph, who decided to tackle water supply and demand management, it is possible to see the strength of the alliances between elected officials and citizens, as they share aspirations and visions of development. The high rate of response to green municipal initiatives, and the overall acceptance of the water bill by the population of Guelph are signs of agreement and willingness on the part of Guelph residents to contribute to water management efforts.

Contrary to the belief that Guelph has been a lone pioneer in water management in Canada (Clean Air Partnership, 2012), this case study suggests that the pan-Canadian water network played a role in the creation and exchange of knowledge on water management and was a source of inspiration for Guelph municipal water staff. This multi-actor and multi-scalar water network comprises several affiliated institutions and organizations (universities, non-governmental organizations, watershed authorities) and governments (provincial and municipal) who meet and exchange knowledge during workshops and city staff gatherings, courses, conferences, etc. The impact of this Canadian water network is mainly felt in the provinces of British Columbia, Alberta and Ontario, as reflected in the influential work of the POLIS Project on Ecological Governance at the University of Victoria, British Columbia, and from its partnerships (POLIS, 2017).

Despite the idea expressed in the document produced by the Clean Air Partnership entitled Accelerating adaptation in Canadian communities, where the following can be read: “Many of the programs and regulations that Guelph initiated were the first of their kind in Canada and North America. […] This meant that the City researched new technologies and developed new standards with little external support and was unable to benefit from lessons learned from other experiences” (2012: 12), this paper suggests that without the pan-Canadian water network that facilitated scientific and technical support to the Guelph municipal staff, it would have been difficult to develop innovative practices in the city of Guelph and neighbouring watersheds (Grand River, Credit River, Lake Erie basin and Lake Ontario basin with the Peel Region initiative). The presence of the Grand River Conservation Authority (GRCA) should not be underestimated either, since it has also had a widespread influence over time in the region: As of 1948, this organization became a Canadian leader in river bank protection, rallying citizens to plant trees along the Grand River to control flooding (GRCA, 2013d; Veale, 2015: 342). Since then, it has developed communication tools to work with the riparian population in efforts to mitigate the impact of human activity in conservation areas and along the different tributaries of the Grand River (GRCA, 2013c; Veale and Cooke, 2017). The socio-environmental context of the Guelph-Kitchener-Waterloo region, with its concentration of higher education institutions and leaders in environmental management, has helped make Southern Ontario a winning region in the sense that George Benko and Alain Lipietz (1992) understood it: a place presenting an accumulation of human resources and political will to make change happen. This stock of human and social skills has been used by the Guelph City Council and local and regional environmental non-governmental organizations (ENGOs) to mobilize citizens and channel public action to achieve the common goal of water sustainability (City of Guelph employees, 2012: Interview).

This paper will examine the multi-scalar composition of the water network that allows for relevant knowledge production on water sustainability and its application to Canadian cities. The partnerships that were built around the principles of the soft path approach to water management combine scientific knowledge and practical know-how and are believed to have had an influence on municipal water management in some Canadian cities, such as Guelph.[1]

The history of water co-management in Guelph and in the Grand River watershed, as well as the history of their stakeholders will be presented, starting with the local and watershed scales, all the way up to the provincial level. First, the history of water activism in Guelph will be discussed, followed by the study of the influence of the territorial embeddedness of the city of Guelph within its watershed, the outreach of the influence of the GRCA, and the role of the Ontario provincial government as a leader in natural resource management.

ANT will be used to gain an understanding of the interconnections between the different actors, and of the structure of the network that sustains the efficient production of knowledge and communication. In the process, and according to the principles of ANT, external inputs and all things facilitating the communication process, whether human or non-human, will be taken into account.

A review of the water soft path approach, which inspired many of the Guelph water management and planning actors, as was expressed in the interviews, will be presented, followed by the presentation of ANT and its implications. As this paper deals with the application of ANT to a case study of water management, it does not offer an encompassing view on Canadian water management issues and its results are not meant to be generalized. The case study of water management in Guelph will be analyzed through the lenses of ANT, the possibilities it offers, as well as its drawbacks.

This research is based on a diversified data collection strategy during a one-year sabbatical as a professor at the University of Guelph in 2011-2012. This stay included participatory observation, networking activities within the local environmental network, attendance at conferences, visits to fairs, workshops and gardens, daily observation of residents’ practices, fifteen interviews with Guelph City staff and leaders of environmental groups, six conferences given by the main author as a guest speaker at Southern Ontario universities and at the POLIS Project on Ecological Governance of the University of Victoria (British Columbia), as well as interviews and on-site visits in the cities of Waterloo, Kitchener and Toronto, and on Salt Spring Island (British Columbia). The main question asked to interviewees was: “Where did the idea of water management in Guelph come from?” Other subsequent questions directed to key actors dealt with the influence of the water soft path approach on local decision-making, the identity of the main partners in water management, and how other Canadian cities have contributed to raising awareness about water resource planning and management in Guelph.

The soft path approach was first developed by Amory Lovins to tackle energy production and consumption in the 1970s (Brooks et al., 2011: XIX). Its contribution was meaningful in recognizing the existence of numerous small-scale, often local, alternative energy sources and, parallel to that, the need to curb demand through better demand management. It became important to think of energy as a service and not an end in itself (Brandes and Brooks, 2005; 2006; 2007). Along with other Canadian water researchers, Brandes and Brooks from the POLIS Water Sustainability Project suggested that this thinking be applied to water using the following principles: “1) Treat water as a service rather than an end in itself; 2) Make ecological sustainability a fundamental criterion; 3) Match the quality of water delivered to that needed by the end use; and 4) Plan from the future back to the present” (Brandes and Brooks, 2007: 10; Binstock, 2010: 2; Maas and Porter-Bopp, 2011). The difference between water demand management and the water soft path approach is that the latter considers the carrying capacity and the long-term attainment of collective objectives. The water soft path approach encourages a community to draw scenarios for the next 15, 30, and 50 years. A collective reflection follows to delineate the contours of the kind of future the community wants. For example, if water consumption remains unchanged, a status quo scenario shows that the resource will become scarce and will not be sufficient to fulfill the basic needs of future generations at low cost. It may mean a stratification of society, where the wealthiest strata have greater access to cleaner water (Idem). Brighter scenarios can be achieved by a 20% or 40% reduction in demand, allowing the community to see the impact of water reduction on future generations’ quality of life. At the end of this collective exercise, the community draws a plan for managing water resources which respects the values and beliefs of its members. A community may choose a “zero-growth policy” where no new water supplies will be created. This can be attained through better resource management, leak repairs, more intelligent consumption (using clean water for consumption and grey water for domestic or commercial uses that do not require potable water, e.g., washing the car, flushing the toilet, etc.).

The different time horizons in this planning exercise must account for potential urban growth. The question is, how can a city under population growth pressure plan to use existing water sources without adding any new infrastructures, while fulfilling the needs of its population in the future? Part of the answer lies in the hands of governing bodies, such as municipal governments that can become leaders in water education (campaigns, activities, events, programs) and reach out to citizens and business owners, sometimes through the use of restrictive rules (under low water level conditions) and fines; and partly in the goodwill of citizens, civil society and elected city councillors. This finely tuned combination is difficult to achieve in most cases, but in the city of Guelph, Ontario, a special combination of thriving civic culture and citizens’ environmental awareness has made it possible. What follows will explain how it was possible in 2005 to adopt a plan for co-managing water resources and how citizens’ involvement has made a difference, with a participation rate above 50% (Binstock, 2010).

The pan-Canadian network of experts focused on the water soft path approach will serve as a framework of reference to understand how knowledge about water resource management is exchanged and generated across Canada, allowing for contacts between academics, water activists, conservation authorities and the different levels of government, including municipalities. A knowledge system can be defined as “a body of propositions actually adhered to (whether formal or otherwise) that are routinely used to claim truth” (Feyerabend, 1987, in Reid et al., 2006: 11).

Integrative knowledge systems allow for a merging of both scientific and local knowledge operating as a closed loop: Flexible feedback loops are allowed in order to learn from previous actions and from others’ experiences and be able to adjust the course of action. In the literature on knowledge production, “science is defined as systematized knowledge that can be replicated and that is validated through a process of academic peer review by an established community of recognized experts in formal research institutions” (Zermoglio et al., 2005, in Ibid.), whereas local knowledge refers to place-based experiential knowledge, knowledge that is largely oral and practice-based, in contrast to that acquired by formal education or book learning (Ibid).

Reasons why multiple knowledge systems should be integrated into decision-making processes for natural resource management are listed below (Idem: 11-12):

• They broaden perspectives and augment the data base;

• The inclusion of local knowledge and actors increase the legitimacy and veracity of findings as it taps into knowledge held by local environmental stewards;

• And local knowledge-holders will feel respected and included in decision-making.

Knowledge is hereby defined as “a construction of a group’s perceived reality, which the group members use to guide behavior toward each other and the world around them” (Zermoglio et al., 2005, in Ibid.). These knowledge systems embrace multidisciplinary research as described by the authors of The New Production of Knowledge (1994), who explained the role of alliances, exchanges and negotiations in more informal and constantly changing scientific contexts. According to them, this collective mode of knowledge production characterizes the post Second World War period, dominated by transdisciplinarity (Gibbons et al., 1994, in Lamy, 2007: 9). “Research groups are less firmly institutionalised; people come together in temporary works teams and networks which dissolve when a problem is solved or redefined” (Ibid.). In order to tackle complex and newly emerging problems, such as post-industrial watershed management, research networks have to be flexible to respond swiftly to the varied demands of society (Ibid.).

ANT, also called “the sociology of translation” or “the sociology of actor-network”, is a concept both anthropological and sociological. ANT was mainly developed by researchers from the French School of Mines, Michel Callon, Bruno Latour and Madeleine Akrich, and by John Law, sociologist currently at the Open University in the United Kingdom, and proponent of ANT.

It combines conceptual and methodological tools based on the controversial idea that technologies and scientific discoveries are socially adopted because networks of scientists, engineers, entrepreneurs and others allow scientific objects and new concepts to be taken for granted. The ANT approach is used in the social sciences; it is different from the analysis of social networks, an approach employed in sociology that focuses on the study of social networks (individual or organizational) (Case, 2016).

The actor-network approach takes into account humans, as well as objects (non-human) and discourses, also called actors or actants. The application of ANT is based on the following concepts (Akrich et al., 2006) (figure 1):

The network means an organization that brings together humans and non-humans. All players participating in the network operate with each other.

Translation is a type of interpretation, a linkage that always implies a transformation, that is to say, an operation that clarifies the meaning of the issues around which the network is formed. It brings together the different issues and actors of the network.

Controversy is the process that allows facts to build. The analysis of controversies is important to ANT, because it highlights the oppositions and alliances among actors.

In-between definition (l’entre-définition) is a kind of explanation that is established between the fact and the network. The fact is the result of the network that carries it, which makes sense only by the situation around which the network has formed.

The principle of symmetry requires the researcher to give equal importance to humans and non-humans, and also to study the controversies that animate the research by paying attention to both failures and successes.

One of the most discussed sources using ANT was written by Michel Callon in 1986 and is entitled Some elements of a sociology of translation: Domestication of the scallops and the fishermen of St. Brieuc Bay. Through this case study, Callon illustrates the contribution of ANT in an analysis of a fishermen’s network within an unpredictable, shifting and unstable society. The case study analyzes resource management at a fishery: Saint-Brieuc Bay, its St. James scallops, its scientists and its fishermen. In a masterful demonstration, Callon applies a bottom-up approach, making use of three principles. The first is the objectivity of the observer, who shall be impartial, avoid censuring actors, refrain from judgments and not favour any one perspective. The second is that one should not change register when going from the technical/scientific to the social dimension of a problem. The third principle is that of free association between acting entities. The study showed that the actor-network approach enabled the establishment, through a continuous improvement process, of an acceptable method for managing the fishery resource.

According to Callon (1986), one can understand the management of change processes through four major stages: problematization, incentive, enrolment and mobilization (explained below). Many studies use these four stages to understand the build-up of interest and mobilization for a cause.

The Governement of Ontario’s Places to Grow Actof 2005 orients development and legislation for the next 25 years in the region centered on the province’s largest city, Toronto (in 2015, the Greater Toronto Area was home to 8 million people). According to the plan, it is expected that decentralizing population growth and work opportunities to neighbouring areas will improve quality of life in the metropolis. This should also help achieve environmental conservation objectives, such as reducing car exhaust pollution, increasing shared green spaces in the city, reducing the need to commute to work and creating lively planned green neighbourhoods. The protection of the Lake Ontario shoreline (part of the Great Lakes) is also a sensitive issue where partnerships between towns and municipalities within its watershed were made possible (e.g., the Peel Region Climate Change Strategy was issued in 2011 and is a result of a collaboration between seven governing bodies and local ENGOs). Municipalities drawing water from Lake Ontario are encouraged to return water to the lake after appropriate treatment (Region of Peel, 2011; 2012; Peel Region Staff, 2012: Interview). Nonetheless, nowhere in the Ontario government’s Places to Grow Act are there any provisions for a water policy, despite the fact that a growing population with a high water-consumption rate—Canada has the fourth highest water consumption per capita in the world (Statista, 2016)—can mean expensive construction of new water facilities (new sources, transport, and treatment with attendant environmental costs).

The city of Guelph (population 115,000) lies on the outskirts of the Greater Golden Horseshoe region (figure 2), West of the Toronto greenbelt, and is targeted by the Growth Plan despite the fact that it has important constraints in its access to water (controversy according to ANT). Guelph is among the fastest growing cities in Canada (Binstock, 2010: 7). Due to a lack of streams and rivers on its territory, almost only groundwater is available (two rivers cross the city but have low water levels year-round and experience problems with their discharge capacity). For the whole Grand River watershed, 70 % of the supply for drinking water comes from underground and 30 % comes form superficial waters (Veale and Cooke, 2017: 380). Groundwater is a finite source of water, renewable at a very slow rate and some beverage companies are already exploiting aquifers (bottled water and beer production). Nestlé’s Aberfoyle Springs plant operate in the hamlet of Aberfoyle, located at the south-eastern end of Guelph, and withdraws water from the Gasport aquifer beneath (at an annual rate of 762 million liters, in 2015) (Robinson, 2016). Nestlé Waters Canada benefits from special advantages and rates for bottling Guelph’s water and selling it around the world “because of outdated regulations that allows for the wholesale extraction of the water” (Mike Nagy, 2016: Interview) (other controversy according to ANT). Local water activists have been opposed to the multinational corporation’s withdrawing activities for more than two decades in relation to the potential environmental costs it may induce to the Aberfoyle Creek ecosystem and local underground water, and to the loss of sovereignty over this aquifer (Leslie, 2016; Robinson, 2016).

With its limited water sources and highly variable annual precipitation, the Guelph area can be semi-arid, particularly during hot summer seasons. In the past 15 years, it has registered increased temperatures and particularly dry periods: the 1997-2003 span were considered drought years, with other dry years in 2007 and 2011 (Clean Air Partnership, 2012: 9). Despite its humid continental climate, with average annual precipitation of 905 mm, the bulk of it is distributed between the months of April and November, and the river flow varies widely within the watershed (Farmzone, 2013; GRCA, 2013b).

The Eramosa and Speed rivers (figure 3), which cross the city of Guelph, are among the slowest flowing rivers of the watershed and their average summer flows are 0,9 and 1,7 m³/s, respectively, compared with other tributaries of the Grand River such as the Conestogo and Nith rivers, each of which has an average summer flow of 3,9 and 2,6 m³/s (GRCA, 2013a). This low water flow induces constant problems with wastewater disposal through river channels in Guelph, as water volumes are not sufficient for efficient drainage.

In the current state of affairs, the carrying capacity of the Eramosa and Speed rivers is expected to be reached in 2024, thus limiting potential population growth (this was the response of Guelph’s City staff to the Ontario government Growth Plan, which initially ignored these ecological limits) (Binstock, 2010: 9). In 2009, the City of Guelph proposed its water conservation and efficiency program (Galliher, 2010) and began negotiating “with the provincial government to reduce its growth target under the Growth Plan to reflect the assimilative capacity of the Speed River” (Binstock, 2010: 9). Its population was originally expected to reach between 175 000 and 195 000 by 2031 (Idem).

Prior to this negotiation, Guelph was already recognized in the province as being an environmentally progressive city. De Loë et al. found that this environmental awareness, apart from factors such as size and human resource capacity that play in its favour, was due to “political commitment, citizen involvement, linkages with outside agencies, and institutional arrangements” (2002, in Binstock, 2010: 9). According to these authors, the “main feature that distinguishes Guelph from the other municipalities studied was ‘continual and multidimensional’ community involvement” (Ibid.) (in-between definition according to ANT). After a decade, Guelph is drawing attention as a regional leader in water conservation and efficiency strategies (Ibid.). Researchers have shown that municipal staff, local politicians and the broader community have always insisted on integrating sustainable principles in their discourse and actions, thus influencing multilevel governmental administrations to adopt water-wise planning strategies (Idem).

What allows the actors of the water soft path network to disseminate information so efficiently is the way in which their network bridges geographical scales, creating links between decision-making authorities and knowledge-production sites, from the local scale (and even micro sites) to the national and even continental scales (Fabricius et al., 2006). The diversity of water conservation techniques available on the municipal website of the city of Guelph and in brochures allows consultative bodies and citizens to implement solutions that are most appropriate to their needs and context (non-human component of the network). In 2009, after consulting its citizens, the municipality of Guelph established sustainable water management as a priority, followed in 2011 by the neighbouring municipalities of Fergus and Elora (Waterbucket, 2011; Leslie, 2016).

The most significant groups of actors in Guelph water management will be presented in what follows, along with their strategies to reach out to the public. For each, their role in terms of the four types of knowledge generation according to Morgan and Murdoch (2000, in Le Heron, 2002: 84) will be outlined: 1) “know-what” (information, facts); 2) “know-why” (science, laws and principles); 3) “know-how” (capabilities); and 4) “know-who” (social skills, networking). The latter authors state that “these components of knowledge are forged within particular institutional structures” (Ibid.). Networking allows these structures to come together and share information, human and financial resources and know-how. It enables them to learn from each other, as in a learning community (Idem).

Several key success factors in the co-management of Guelph’s water resources were identified through the application of ANT. This method has the merit of bringing to the table different elements on an equal footing (humans and non-humans alike) in a pluralistic context, without any preconceived notions, to try to understand the forces that bring them closer in a common network. ANT has made it possible to analyze and understand the networking activities of actors by considering the multiple tensions inherent to innovations. The translation process is also used to understand how people cooperate within different contexts and the reasons for success or failure in organizations. By combining the technical and social dimensions, ANT offers an original interpretation of technological development and implementation (Missonier, 2008).

The research analyzes how the pan-Canadian network of water stakeholders contributed to define Guelph water policies aiming at sustainable water policies, and a healthier and more resilient watershed basin in face of climate variability. Based on the findings of the POLIS Project contributors at the University of Victoria presenting various cases of Canadian cities applying the water soft path approach, we were able to figure out the existence of communication channels united under this approach and including academics and interest groups from sites such as Salt Spring Island, Kitchener, Elora, and Guelph. Upon discovering the presence of links between the university-led network and municipal spheres, the research line of inquiry about how this Canadian water connection influenced Guelph decision-makers began to take shape. This step revealed what appears to be a common goal for all parties concerned, as well as the existence of a human and physical network that allows the multi-scalar construction of knowledge between water stakeholders from provincial governments, research centres, conservation authorities, and municipalities. The physical parts of the system are represented by the new information and communication technologies, including web platforms, allowing for rapid flows and exchanges of information. In the wake of these collaborations, Guelph’s municipal Water Service staff has forged its own path in applying water conservation knowledge shared among Canadian thinkers to prepare the Guelph Water Conservation and Efficiency Strategy Update (2009) (which will be called herein the Guelph Water Strategy) (City of Guelph Water Service employees, 2012: Interview). Despite the fact that water managers and planners in Guelph did not explicitly acknowledge that they were applying the water soft path (Idem), this approach in fact appears to have had a tangible impact on the design of the Guelph Water Strategy and there is no doubts that they knew of its existence (Idem; Binstock 2010). In the preamble of his report, Binstock explicitly said that Guelph is to be used as a “pilot project […] to identify enabling conditions that have allowed Guelph to pursue measures that align with the soft path’s core principles” (2010: i).

Since this network predates the research, unlike other experiments conducted in action-oriented research such as that of Akrich et al. (2006) on the sustainable reproduction of the St. James shells, it was necessary to work back up the thread of the “spiderweb” in order to understand the structure of the network in an ex-post process. The advantage of working after the fact is being able to observe the modes of knowledge appropriation favoured by citizens and their willingness to adopt water-wise practices. Several indicators, such as citizen participation in various activities organized by the City, the voluntary conversion of lawns, and the presence of rain barrels in private lots, have been useful for determining the degree of citizen involvement. It appears that over time, collective knowledge has been shaped and shared, thus forming the citizen base of the network that will ensure its continuity after the departure of elected officials and/or staff of the City.

Below are summarized the various stages in the process of forming the water conservation network in Guelph according to the principles of ANT as presented by Callon (1986).

Let us first recall that if ANT absolutely refuses to decide a priori on issues of scientific relevance, it has nevertheless provided opportunities for the development of analysis tools in the technical, scientific, social, economic and political spheres (Lamy, 2007). ANT provides a foothold into complex terrain and a variety of fields (sociology, science, geography, politics, economics, etc.). According to Latour (2006), the social world is something of a construction site. ANT offers opportunities to observe the operation of the site, the work carried out, and the equipment, tools and devices that are developed there, rather than limiting the analysis to the completed project as if it had always existed, disregarding the building process that led to the final result.

As noted by Cazal (2007), in a context of action research, ANT provides support for participatory development planning at the community level. The tools it offers help external stakeholders and interest groups work together to: 1) identify the key success factors of development; 2) understand the participation strategies of different entities in a network; and 3) build consensus on development priorities. Furthermore, it provides a series of toolkits designed to support the participatory process, which begins with an analysis of the present situation and ends with planning for the future and confidence building between the different actors. Qualitative and quantitative data used jointly allow for a better understanding of the situation as a whole (FAO, 2002). Furthermore, by including both human and non-human elements in its approach, ANT can provide sound information for analyzing a situation in its entirety.

In the case of water management in Guelph, ANT has helped to understand the interrelationships in a system that grows through differentiated contributions from its stakeholders over a given period of time. It provides an external cross-cutting look at the process of creating a multi-scalar network of knowledge-holders on water management. Studying the context of development of the network provides insight on how ideas spread (websites, e-newsletters, conferences, workshops, newspapers, studies, etc.), are endorsed by influential players and accepted by interest groups who appropriate the cause (enrolment) through various administrative bodies, and at different times.

ANT has proved useful to examine the building processes of the pan-Canadian water network and of shared knowledge about water management, rather than looking only at the results or history of the policies. It is necessary to study the processes behind the construction of scientific knowledge and the contribution of each elements of a network to identify the next steps towards making blue cities. The use of ANT has revealed the existence of a wide pan-Canadian water experts network whose interactions have been influencing decisions at various geographical scales, as far down as the city councils. The study of the pan-Canadian water network explains the accumulation of know-how on water conservation and sustainability in a number of different Guelph-based institutions, which contribute to make the city of Guelph a municipal leader in water conservation in Canada. It has also added some insights on the Ontario water governance model stressing the role of conservation authorities in coordinating and monitoring water management strategies and establishing an enduring communication with the Grand River watershed interest groups and residents, through time. The coming together of various water experts on the Guelph territory suggests the presence of a nexus favourable to water innovations. Such nexus is found in geographical studies explaining why some regions win and others lose (Benko and Lipietz, 1992). The attraction of the Guelph/Grand River Watershed territory and the readiness of its actors to embrace collaborative watershed management practices have opened up possibilities to put in practice water soft path principles and think about sustainable water management for the future. The sustained influence of the GRCA cannot be overlooked in the process, as we must recognize the importance of the territorial embeddedness of Guelph in its region and watershed basin. The territory and water themselves are part of the physical elements of the systems and do create a pole for converging interests. The shared alignment of conservationist ideas among local and regional stakeholders has propelled innovation in municipal water management in the City of Guelph. As such, Guelph could very well be used as a “pilot project” as suggested by Binstock (2010) in the application of the water soft path for other Canadian cities. Nonetheless, the territorial attraction of water intelligentsia may not always be present on distinctive territories and results may therefore differ.