Actually existing smart forests: A proposal for pluralizing eco-technical worlds

The dis/connected forest

One of the primary reasons digital technologies proliferate in environments such as forests is to gather more data about environmental change. Within forests, deforestation, wildfire, disease, drought, and biodiversity loss are critical events that an increasing store of data—including real-time data—is meant to monitor and evidence (Lewis Hood and Gabrys, 2024). Yet within proposals for implementing more extensive monitoring networks or for synthesizing a greater number of data sets several contradictions arise. Visions about a near-total state of data capture through sensors can collide with concerns about inequality in accessing data (cf. Shelton et al., 2014). Sensor testbeds within scientific field sites can attempt to collect comprehensive data sets, while forest monitoring for community campaigns can focus on generating site-specific environmental data through sensors, drones, and remote sensing to mobilize legal cases (Millner, 2020). Those forests which are disconnected and without digital monitoring technology potentially will not register—or register in the same ways—due to a scarcity of instruments and data. Even within highly instrumented forests, “actually existing” forests are made evident through distinct variables and phenomena that technologies monitor. The smart forest materializes through data sets that are meant to establish patterns in changing forests. In this sense, the smart forest can be simultaneously speculative and “actual.” Forests are instrumented and monitored, but awaiting connections and consequences that are yet to be established within data sets for future use.

As part of our extensive review of smart forest projects, we met with a regional director of one major smart forests project to discuss the initial ideas, grant proposals, and eventual installation of digital technology in a forest at the Hubbard Brook Experimental Forest in central New Hampshire in the US. Hubbard Brook is a 3500 hectare field laboratory that was established by the US Department of Agriculture in 1955 (Campbell et al., 2021). This interviewee had extensive interdisciplinary training in ecology as well as philosophy and had a balanced yet optimistic view of what these devices could enable. Initial funding for this site’s smart forest initiatives came in the form of pieced-together funds, which allowed for the initial network setup. Within the funding applications, the forest organization proposed to set up a testbed that could demonstrate what was possible. As this interviewee notes:

“And it was really a ‘show me,’ it was a prototype, it was saying, ‘Gosh darn it, we can not only have data from one site, but what if . . . What if we had multiple wired forests talking to each other in real time.’ I mean it’s kind of mind-blowing, and we’re not there yet, but that was the idea.”

—Research Ecologist, New Hampshire

In our interview, we discussed the speculative potential of smart forest technologies, as well as the logistical challenges they present. While the interviewee describes the initial smart forest as a prototype, the development included sensor networks, data dashboards, and visualization and sonification tools. For this interviewee, the speculative contributions and insights that could be gained from wiring up forests with computational technologies align with many of the promises that smart environment proposals offer—comprehensive, real-time, and interconnected environmental data to measure and monitor critical ecosystems such as forests. The connected forest, in this sense, would be a more data-rich and manageable environment.

With this project and discussion, we found the speculative potential of the smart forest to be bound up with a more prolific generation of environmental data across the changing space-time conditions of forests. For this interviewee, the “actually existing” smart forest materializes as a highly connected and networked environment, from which new insights will surface through more sizable and interconnected data sets. Once digital technologies are installed and abundant data is generated, then advanced understandings of forest ecosystems are meant to arise. Speculation, in other words, emerges from connected and material conditions of smart environments, rather than as a vision preceding implementation. As this interviewee notes:

[. . .] we’re super excited about the plethora of other types of sensors and what they're going to tell us about our forest ecosystems.

—Research Ecologist, New Hampshire

The sensors and the data they generate become the source of insights that are yet to be fully realized. In turn, the formatting of data through dashboards, visualizations, and sonifications is seen to be a crucial step to making the most of these smart forest networks—in other words, technology begets more technology. While the actually existing smart forest was already interconnected and generating data, the potential insights and uses to be realized from these interconnected systems remained a site of speculation. In our conversation, we wondered how environmental sensor data was mobilized, and who might make use of it. In response to this question, the interviewee replied:

Who is using it? That’s to me the million-dollar question. These data are still pretty new. I don't know how to get people to use these data, I don't know how to bridge the divide between scientists producing Excel spreadsheets, and data graphs with millions of points, and the schoolteacher in town X, or the student, or the public manager, or any of those people.

Part of it is getting our data out there on data dashboards and really delving into this relatively new field of data visualizations.

—Research Ecologist, New Hampshire

This interviewee clearly expresses and understands that much more work is needed to make data relevant for expanded publics. The speculative potential of the smart forest is to be realized through further technology that presents “actually existing” data in different and potentially more accessible formats. The smart forest in the form of digital devices and networks has been built, but the data that it generates have yet to fulfill its speculative applications.

Here, it is impossible to extricate the speculative potential of the smart forest as a site of enhanced ecological insights from the actual forest replete with sensor testbeds and data dashboards that is in search of applications. In their operation, digital technologies continue to generate speculative uses that would require more technology to realize. The actually existing smart forest becomes a never-quite-finished project to realize through the ongoing installation of interconnected digital technology that generates abundant data for eventual analytics and insights. However, as social studies of science and technology have suggested, data do not necessarily become effective through interconnectedness and abundance alone. Instead, it is through the formation of facts, conditions of relevance, local practices, and power dynamics that claims can be made, evidence can be circulated, and responsive actions can materialize (Gabrys, 2016; Goldstein and Nost, 2022; Loukissas, 2016; Nadim, 2021; Walford, 2015). A more pluralistic approach to forests as eco-social relations and practices could be a way to rework the potential relevance of data beyond technoscientific expectations about the uses of data.

Not all forests are as highly instrumented as this one, however, and uneven data sets can generate considerable discrepancies across environments. In this way, another interviewee emphasized how connected forests can create information asymmetries in comparison to disconnected forests, thereby further excluding less connected communities. This interviewee based in a Brazilian environment, science, and technology organization suggested that connected forests could have impacts on disconnected forests. While this well-established scientific researcher was engaged in multiple remote-sensing and geospatial analysis projects in the Amazon, often working with big-tech companies such as Microsoft and Google, they worried that digital technology and data were not evenly distributed. As the interviewee notes:

Digital inclusion or exclusion components: that worries me a lot. Because you take the asymmetry of access to information, some communities are not included in this digital network and that’s very, I think, a problem because this asymmetry information is power so communities that have more information can succeed in a way [that] sometimes affect[s] other communities.

—Spatial Analyst, Brazilian Amazon

As they identified, while computational technologies might promise an abundance of data, this was an abundance that was only available to those communities, researchers, nations, or companies best situated to take advantage of these devices and networks. In the context of the Brazilian Amazon, as communities attempt to mobilize technologies for protecting their livelihoods and addressing issues such as deforestation and wildfires, this inequality could have immediate and palpable effects. The interviewee describes these inequalities and says:

I will give you an example and then you [. . .] will know perfectly well. There are some tribes in the Amazon that are isolated but other communities are not as isolated, they are using GPS, satellite data [. . .]. So you’re creating asymmetry of information so it’s important to take into consideration.

—Spatial Analyst, Brazilian Amazon

“Actually existing” smart forests are not just located directly within extensive digital networks but also in their adjacent and residual effects. Varying access to technologies and communication networks, uneven engagement with partner organizations, inequitable resource distribution, language barriers, and geographical isolation are just a few of the ways in which smart forest networks could collide with and produce information asymmetries across connected and disconnected forests (cf. Cifuentes, 2023; Wainwright and Bryan, 2009). The potential consequences for livelihoods are especially notable, as this interviewee further remarks:

This is an extreme case that really worries me. But I see places in rural areas that don’t have access, for example implementing technical systems to improve agriculture. There are a lot [. . .] of applications but [. . .] they are so isolated sometimes they cannot use this, they cannot benefit from this technology.

—Spatial Analyst, Brazilian Amazon

The power dynamics that arise from smart forest networks can create marked data inequalities depending upon whether communities are comparatively connected or disconnected, which this interviewee sees as a central concern for digital technologies in forest environments. They note:

And that’s why I heard from an economist that this concept of asymmetry of information, how it leads to power. I started to worry about this, how to make this more inclusive, I think that’s the crucial challenge for dealing with this type of technology.

—Spatial Analyst, Brazilian Amazon

In contrast to ideas of information abundance and insights that will flow from digital technologies and that resonate with typical smart city narratives, here every device and infrastructure brings with it the potential for inequalities within and among communities. Such speculative inequalities could have direct consequences for which communities can benefit from digitally informed land practices, and which cannot. If one community has access to deforestation alerts and can patrol its lands, but another does not, this could displace illegal deforestation practices to the community without digital monitoring equipment. Considerations of access, use, and mobilization of environmental data could, in turn, transform how smart forest networks are imagined and constructed. Here, the actually existing smart forest could generate inequalities for other forests that do not have access to digital resources. While not officially “smart” such disconnected forests could experience digitally aligned impacts that do not readily feature as the development of a smart environment, but rather as the fallout from adjacent smart forests. The “actually existing smart forest” can therefore create speculative and actual harms for more disconnected forests.

A forest might only be episodically “smart,” moreover, where discrete and time-limited uses of digital technology could enable data collection. For many Indigenous, traditional, and local forest communities, environmental data collection takes place as part of projects for informing land practices, making claims and protecting land, and raising legal cases when infractions occur. In this sense, specific data can be mobilized toward particular projects and objectives, rather than delivering speculative insights through an ongoing abundance of data. Another interviewee working on conservation technology in India described this as a central feature of their organization. In their work, drones, remote-sensing data sets, sensors, and data analytics came together often on a case-by-case basis to support campaigns, legal challenges, risk assessments, and policy. As this interviewee describes:

Going back and turning to this question about partners. We, you know, again, we started and worked with people like Deloitte and PwC as well on risk assessment in this particular issue, right. And to give an example of that work, we convinced them that actually looking at biodiversity risk from the perspective of how biodiversity affects the investment risk of their projects. You know, assessing that and using that to make better decisions which would both make sense from a business perspective as well as for conservation [. . .].

So large-scale assessments of road networks across the country, looking at where their clients were investing in road networks [. . .]. It was a risk from the fact that biodiversity exists over there.

—Conservation Technologist, India

Here, the connected forest is a momentary installation for gathering data to address environmental problems and building community networks, especially for addressing road-construction projects. With this proposal, the interviewee suggests that taking a broader view of biodiversity data, as well as making connections with understandings and projections of risk, could allow for a different analysis of the impact of road networks on the land. When deploying digital technologies to monitor new road projects, different connections can be made across data sets by considering how environmental problems are interlinked. In this sense, data is less about abundance surfacing scientific insights through comprehensive digital infrastructures, and more about a project of mobilizing data to make a case for joined-up environmental practices and policies. While digital technologies might be in constant operation or episodically deployed, they gather their effectiveness through targeted uses. The “actual” technology is underwritten by its speculative potential, where data have the potential to evidence environmental harms. “Actual” technologies are less exclusively the grounded example of how smartness takes hold, and more expansively the multiple eco-social and eco-technical practices that could be activated.

As one iteration of the “actually existing” smart forest, the dis/connected forest is not characterized by pervasive or limited digital monitoring, but instead by these shifting constellations of how technology, milieus, speculations, and interventions are co-constituted and mobilized. The “actually existing” smart forest is not a single environment, empirical reality, or lived condition, but instead a pluralistic range of practices, installations, speculations, inequalities, data-in-waiting, and site-specific projects to document forest changes and mobilize data and communities. These different smart forests can be held in play, rather than reduced to one universal framework, to consider the contributions that can be made by each, as well as the concerns that different approaches might raise or encounter, as the next section further describes.

The present forest

“Actually existing” would seem to suggest a smart environment or forest that is most present, self-evident, or material. However, digital technologies co-constitute forests in distinct ways. With many digital technologies, forests become present as stores of carbon and biodiversity, and as sites of environmental crime and dispossession. Sensors, satellite imagery, and camera traps might respond to some environmental concerns and make forests present in response to these agendas, but they can also exclude other knowledges and values to which sensors might not be responsive (Gabrys et al., 2022). In this way, a smart forest could most frequently be envisioned and developed as one that responds to the objectives of environmental scientists and policymakers, who seek to preserve forests as carbon stores or biodiversity reserves (Gupta et al., 2012; Nel, 2017). In making the forests present, the “actually existing” analytic directs our attention to the multiple transformations that take place in and through technologies.

For ecologists, digital technologies can present a challenge for their relative connection or distance from forests. Technologies can remove researchers from the field, but they can also remove the field from the technology. For example, estimating the number of birds as a critical indicator for ecosystem biodiversity is difficult in high biodiversity environments like tropical forests (Metcalf et al., 2022). Traditionally, “point counts” are used as a rapid assessment for capturing bird biodiversity in a particular area (Leach et al., 2016; Metcalf et al., 2022). This method is done by recording all the birds that are seen or heard at a specific location and time (Klingbeil and Willig, 2015). Nonetheless, this approach poses challenges in regions with rich biodiversity, where data overload can overwhelm observers and lead to the omission of certain species. Discrepancies in observers' expertise can hinder accurate survey comparisons, and the mere presence of observers in the field may alter bird behavior. Furthermore, the costs of extensive in situ fieldwork can also be prohibitively expensive (Leach et al., 2016).

In response to these problems, Autonomous Recording Units (ARUs) have been developed as a supplement due to their ability to reduce several types of bias associated with the point count method and to enable consistent data collection among surveys that facilitate the improvement of species detection and richness (Klingbeil and Willig, 2015). ARUs collect and record data about the habitat, behavior of the birds, and changes in the sound without the presence of a human observer (Symes et al., 2022). While these digital technologies can address some of the point-count problems, Klingbeil and Willig (2015) show that the accuracy and richness of biodiversity estimates from the point-count method was greater than the from ARUs. For instance, the technology does not seem to detect organisms such as woodpeckers. One interviewee who had set up an acoustic monitoring project in Malaysian Borneo spoke to these challenges across automated, remote, and in situ technologies and practices, and noted:

But obviously there’s subtleties to the data that someone doing the point count gets that an automated approach wouldn’t [. . .] such as they might know the sex of a call, for example, or the breeding stage of a call, and you might not have implemented that in your algorithms. You know you talk to a field assistant who’s been doing a job like this for six months [. . .] and they say, “Well actually, how about this?” This, that, and the other that the scientist who’s coordinating the project maybe hasn’t come up with, and it’s that intuition that you gain from just being in the field.

—Bioacoustic Sensing Researcher, Borneo

Here, experience gained from being in the field informs how the digital technology is mobilized. Rather than insights flowing from the technology, these must be gained through a complex negotiation across prior field experience, data, algorithms, and ecological methods. The “actually existing” smart forest can be differently composed through the presence or absence of technologies, researchers, and variables sensed or detected. This is not a singular smart forest, but one differently activated through eco-social practices that could value some species or ecosystems over others. Different iterations of forests materialize across in situ, remote, instrumented, and/or automated encounters. Describing how intuition reshaped the research, this interviewee emphasized:

It’s so invaluable just to go and see the field site for a day or two as much as you can, because you just get some intuition for the kind of place that you’re surveying and the data you’re working with. So, if you go to automated you can lose that intuition and ignore quite obvious things that would be apparent if you go there.

—Bioacoustic Sensing Researcher, Borneo

This interviewee suggests that automated digital technologies could erase or supplant insights that can only be gained through field experience, described here as intuition. With automated observation technologies continually taking measurements, there is the potential that these devices could even create a new baseline for common sense. Within this interviewee’s analysis, there are at least two types of observers: one who is present in the forest, having a knowledge of local conditions; and the second who is developing algorithms and interpreting data but is remote from the field. Both observers are connected to a different yet similar forest (cf. Awan, 2016). Whether these different observations and practices intersect is not always guaranteed. “Actually existing” forests are to be monitored for their biodiversity. However, different conceptual formations of biodiversity, as well as evaluation technologies and practices, can make different types of biodiverse forests present (Westerlaken, 2024). A multiplicity of forests materializes here, which could complement each other or serve as the basis for contestations in spaces of environmental management and governance.

These different registers of forest presence are also evident in the Hubbard Brook forest site discussed above. This field laboratory was developed to detail the relationships between streamflow, vegetation, and the chemistry of the precipitation (Campbell et al., 2021). Hubbard Brook has one of the longest field records of soil frost, where their technicians have measured tactile frost depth manually since 1956 (Campbell et al., 2010). Manual measurements of soil frost were made at a single point at each location at weekly time intervals (Campbell et al., 2010). These measurements led to variations in the observed soil forest depth and disagreement between the predicted and observed values due to errors during the manual measurements (Campbell et al., 2010). Responding to the adoption of the limitation of manual measurement, the Hubbard Brook interviewee highlighted the contrast between manual measurements and the use of digital sensors:

Instead of having weekly measurements, I can have measurements every hour, every 15 minutes, every minute. And I don't have to depend on a technician going out to do these. And then if we wire it up effectively, we can have these transmitted to our base stations through telemetry, and we can have these measurements at the palm of our hand.

—Research Ecologist, New Hampshire

Forest ecologies become present here through a greater frequency and granularity of data, as well as by transmitting distant events to researchers in their base stations. Such an approach promises greater immediacy and accuracy. Emphasizing how transformational this digitally informed approach to environmental science can be, our interviewee continued:

So, realize that the old way of doing business was collecting measurements, putting it in spreadsheets, somehow uploading those into databases, and if we were lucky, we might get the data six months, a year, 18 months later. Now all of a sudden, we had the promise of having real-time data, big data like the urban data [. . .].

—Research Ecologist, New Hampshire

Contrasting the “old way” of measuring forests with digital approaches, this interviewee draws attention not just to the contrast between in situ or remote experiences of forest events but also to the multiple transformations that take place to data depending upon the formats and frequencies in which it is gathered and processed. The episodic and partial qualities of hand-gathered field data can make for a less expansive data set than a digital sensor network. In this interviewee’s perspective, wired forests can even approximate cities by generating big data sets with streamlined and automated processes. “Actually existing” smart forests would then be differently composed and materialized, depending upon whether data sets are more immediate and expansive, the variables used, and the absence or presence of researchers, among many other factors.

While data collection and analysis might be common practices, their implementation can take place through different tools or techniques that differently constitute forests. This can, in turn, also contribute to different understandings of forest events based on proximity, experience, interpretive techniques, and further responses that these could generate. Are remote scientists better placed to describe biodiversity in tropical rainforests, or are forest dwellers who live alongside these organisms and ecosystems? Whether wired or not, the multiple observations and data sets that forests generate can make forests present in different ways, both as speculations and lived sites. They are “actually existing” as distinct sites due to measurements and data protocols, the scientific objectives to which these respond, and the analogue or digital practices that evidence and solidify these versions of forests. In this sense, different eco-social and eco-technical practices can make a multiplicity of forests present. This in turn can also inform the power dynamics of who can or cannot speak for or about forests.

The proxy forest

If the previous two examples show how digital technologies are often deployed to connect up forests and co-constitute them through registers of data dis/connection and presence, this section considers how the very indicators of what counts as a forest can be subject to scrutiny, depending upon which entities stand in for forest health or ecosystem integrity. While the concepts of “smart” and “forest” help to investigate a range of power dynamics between speculative and lived conditions of digital and forest environments, our interviews also revealed how the “actually existing” smart forest is co-constituted along with multiple other entities that would ordinarily not count as a “forest.” Within numerous interviews, we identified multiple proxies that served as approximations of forests. These proxies reworked the focus on forests and technology, and showed how these are not fixed or singular concepts or relations. Forest worlds, in other words, consist of other entities that can reconfigure “actually existing” forests as they are usually designated.

One example of how digital technology indirectly produces such an expanded forest world emerged through the medium of water in the context of the Brazilian Amazon. Here, the Brazilian senior researcher whose insights are included above explained how issues of deforestation and carbon emissions can be challenging to communicate to general publics. Water, on the other hand, is mobilized as an idea that can more directly reveal issues that help people to understand the risks of climate change:

I think that the challenge is how to communicate [environmental issues] to ordinary people [. . .]. That’s really the challenge. And [we] start[ed] to work with water because water is connected to [. . .] climate change.

People don’t understand much why we are worried about the Amazon becoming our source of emissions, instead of a sink. This concept, it’s hard to be understood by ordinary people. But water: it’s straight. It strikes people directly, and there you can connect water forms to other environmental issues. That’s the strategy at least that we are trying to implement now.

—Spatial Analyst, Brazilian Amazon

As this interviewee suggests, by focusing on water rather than the usual dynamics of forests and carbon, it could be possible to raise public awareness about the risks of deforestation and climate change. In this interviewee’s assessment, it can be challenging for publics to understand or engage with forest data and technologies. Indeed, forests are almost too abstract in their “actually existing” form since carbon-based ways of documenting environmental change often do not adequately connect to public concerns. Instead, when traditional, local, and Indigenous people are faced with continued degradation of the Amazon through diminishing water supplies, the risks of climate change become more immediate in the context of ongoing drought and water restrictions. This example shows the “actually existing” analytic is more than a self-evident description of forests as trees, but also includes an extended range of forest proxies that could activate different eco-social relations and practices. Water is more immediate as a lived condition and experience of scarcity, which simultaneously activates an anticipation of forests under threat.

In the context of the Brazilian Amazon, digital technologies and data infrastructures have been sites of global and local political tensions for decades (Sanches et al., 2021; Vurdubakis and Rajão, 2020). While these extensive remote sensing data sets, sensors, and data dashboards enable this researcher to understand environmental change in forests, such digital technologies for carbon offsetting and deforestation are becoming increasingly complex. Technological developments for deforestation, carbon offsetting, or tree planting are now being co-opted for corporate growth or political gain (Urzedo et al., 2023; van der Hoff et al., 2018). This interviewee worked on an online platform with other partners that uses satellite data to create a timeline that visualizes how above-ground water, specifically in lakes and rivers, has disappeared since the 1980s. Here, “actually existing” smart forests show up in the medium of water, as a more immediate connection and point of both speculated and lived concern. Digital forest technologies enabled the creation of evidence to show diminished water supplies, as well as the consequences for Amazonian forests. Such technologies are conceptually attuned to the idea that water will be more aligned with public concern. In other words, by using water as an entity that affects both people and forests, in both its lived and potential understanding, the interviewee sought to shift focus and raise public awareness about the need to restore and protect Amazonian forests. This example shows how the development of smart forest technologies can be grounded in connections across people, water, and forests, as well as a more vivid if speculative sense of increasing water shortages.

While water can stand in for forests in the Amazon, in the Midlands of the United Kingdom another interview participant proposed that the very notion of a forest needed to be rethought in the context of the UK landscape. In these environments, they argued, carbon capture and biodiversity restoration cannot take place exclusively in forests as usually understood in the sense of the Amazon (although the cerrado is an important if overlooked aspect of these landscapes) but must instead include mixed woodland and meadowland. This participant describes the importance of the concept of a wood-meadow:

It depends on your definition of forest, to be honest, if you look at the old English term forest, it was almost a parkland landscape that was used for hunting, so it wasn’t necessarily full of trees in the UK, so you’ll find that there are forests in the UK that are not just trees. [. . .] One of the terms that’s coming to the fore is the use of the word called wood-meadow, so that is, if you like, the concept of a mixed woodland and meadowland, and the aim there is to capture carbon but also address the biodiversity loss that we’ve had.

—Biodiversity Social Enterprise Founder, UK Midlands

The notion of a wood-meadow shifts the attention from forests toward more mixed landscapes that involve a variety of landscape restoration practices. This wider speculation about what a forest involves can subsequently inspire different ways of calibrating technologies to monitor such sites. For this participant, automation processes enabled by digital technologies—particularly satellites—play an important role in determining where restoration can take place across these landscapes:

There’s about 40 layers of GIS information that are relevant to a plan such as this [. . .]. So, one of the things technology could do is automate that process, so we put a shape around a new county, push a button, and a day later, depending on how much data is being crunched, a map would be produced, and I think that would be entirely feasible, in fact, I know it is. It would need a check, and it would need verification, and it would need consultation, and it would need the stakeholders to adopt it, but it would be a good start and it would save everybody quite a lot of time and money.

—Biodiversity Social Enterprise Founder, UK Midlands

The interviewee proposes to apply automation technology not only in the context of tree-dominated landscapes, but across a variety of other restoration landscapes, from peatlands to grasslands. They highlight the importance of restoring soils and wildlife to create a more balanced, native, and mosaic landscape. Throughout the interview as well as in the quote above, it also becomes clear that such an approach involves several stakeholders and networks that influence restoration projects, leading to new power dynamics that may largely become directed by automation technology. Here, restoration informed by automation remakes the landscape matrix into a woodland meadow. The “actually existing” smart forest does not settle into a tree-dominated landscape, but instead is reconstituted as a patchwork of different sites that can be variously enrolled into restoration objectives.

As these projects show, forest environments can be differently constituted through digital technologies that intersect with a broad set of ideas and speculations about what forests are or should be. Different entities become vehicles for mobilizing attention toward forest protection and restoration. In Iraqi Kurdistan a different entity has also materialized to mobilize people in conflicted forest and mountain landscapes. Here, camera traps were used to identify wildlife in an area where many forests are lost because of fires caused by drought, but also because of human-made fires and attacks in conflicts between Iraq, Iran, and Türkiye. While monitoring forest events in 2011, one of the camera traps documented a Persian Leopard, an animal that was considered extinct in this region. The Persian Leopard became an important entity for sparking negotiations about land protection and freedom for local communities. As the interviewee based in this region noted:

[. . .] everybody was very excited [when we recorded the leopard], because then you could use this charismatic species to bring more projects. And using it as like an umbrella species to receive more attention, not just locally, but also internationally.

[. . .] Iraq’s forests are lost by at least 50 percent—more than 50 percent—compared to 20, 25 years ago. And these are related to natural forest fires or human forest fires related to war and raids along the borders, but especially recently with continuous bombardment and raiding on both the Turkish and Iranian borders. And mind you, that these border areas are really important for wildlife, because they allow the migration of these animals, especially an animal like the Persian leopard.

—Wildlife Conservationist, Iraqi Kurdistan

With camera traps, conservationists were able to visually document the leopard. This evidence in turn could raise international attention not only for this particular species but also draw attention to this conflict and the struggles of local Indigenous populations in their territories (Horeni et al., 2022). Since then, camera traps have been used in different regions to document the leopards. The Persian leopard’s range spans across forests and landscapes in 11 countries, and camera trapping has become more popular in these regions. Digital documentation of the leopard has also stirred up cross-border politics in Türkiye, Afghanistan, Russia, Georgia, Azerbaijan, and Armenia (Goodall and Tehrany, 2022). The “actually existing” smart forest is mobilized through camera traps, image data, infrequent leopard sightings, lived experience of forest loss, and the speculative promise of greater forest protections in a landscape under threat.

However, the use of forest technologies to document leopards can have other social-political impacts beyond forests. In 2018, the Iranian authorities attempted to charge eight staff members of the Persian Wildlife Heritage Foundation with “corruption on Earth” (which carries a death penalty) for the charge of spying against Iran with camera traps using foreign-made technologies and exchanging camera footage abroad. Kavous Seyed-Emami, academic and director of the organization, was arrested for the use of camera traps and died in jail (Goodall and Tehrany, 2022). Through international intervention, the sentence of the remaining seven prisoners was reduced, but the conservationists served 6 to 10 years in prison before eventual release. Camera traps are a key technology within smart forests but the images they collect and the locations in which they are placed can lead to present or future impacts within and far beyond the forests in which they operate (Adams, 2019; Benson, 2010; Sandbrook et al., 2021). As a more-than-human entity moving across different forests and borders, and showing up in unexpected places, the leopard shapes territorial conflicts and political power dynamics. The forests through which these leopards roam are transformed by documentation that would alternatively protect their habitats, prevent knowledge sharing, or enable further forest protections.

The proxy forest could materialize through digital technologies, but it also can upend usual ways of encountering the “actually existing” smart forest. Besides the numerous ways in which smartness is conceptualized in forests, including as connected sensors, digital platforms, networked satellites, algorithmic operations, or data infrastructures, the notion of the forest moves beyond its typical understanding as digital technologies interacting with a tree-dominated landscape. Devices such as remote sensing technologies and camera traps monitor proxy conditions and organisms, which stand in for and mobilize forest environments. Proxies are both within and transformative of forest conditions, signaling speculative and lived forest conditions. “Actually existing” smart forests become evident and relevant within vastly different conditions, political contexts, and contestations over forest speculations and lived conditions. The “actually existing” smart forest becomes present as a much different conceptual distinction in each of these sites, leading to a more pluralistic understanding of how digital technologies materialize in forest environments. Here, the reconstitution of speculative and lived forest conditions also suggests different ways to protect, restore, expand, and regenerate forest worlds.