Conversational agents in online organization–stakeholder interactions: a state-of-the-art analysis and implications for further research

Maintaining online mediated stakeholder interactions

The body of knowledge in online public relations has primarily focused on human-to-human interactions via social or digital media for different purposes and situations and in different contexts—private, public and non-profit organizations (cf. Duhé, 2015). In this area, some studies examined the agency role of digital channels to identify new ways to build and maintain organization–stakeholder relationships, for instance, those on microblogging networks (Chen and Fu, 2016; Wang et al., 2018). Especially informative posts were found to be most shareable and to increase engagement (Chen and Fu, 2016; Gao et al., 2014). Being active in online and social media communities can improve company brand differentiation and strengthen relationships with customers, but it also positively impact customer engagement through social relatedness and trust (Ji et al., 2017; Kim and Drumwright, 2016; Liu et al., 2018; Martìnez-Lòpez et al., 2017; Rybalko and Seltzer, 2010).

Overall, social media has become an essential part of organization communication strategies but dialogic capabilities of social media are limitedly utilized. Stakeholder participative expectations are often not met because organizations tend to hesitate in deploying dialogic communications (Huang and Yang, 2015; Navarro et al., 2017; Watkins, 2017) and instead, prefer to use them for pushing contents that support their corporate reputation (Wang et al., 2016). While research focusing on social media is contradictory regarding its actual value for stakeholder engagement (Simon and Tossan, 2018), specific studies, for instance, on social messengers (Tsai and Men, 2018), found that they offer opportunities for organizations to achieve a strong one-on-one connection with individual stakeholders. Social messengers can be efficient tools for maintaining human-to-human interactions, but AI has brought new venues for interacting with humans. AI conversational bots have been tested and used in instant messenger platforms, and results of diverse experiments and usage are promising (e.g. Goh et al., 2008). However, researchers are cautious as there are still differences in the quality and content of these conversations when compared to human-to-human interactions (Hill et al., 2015).

This study focused on a specific type of AI, chatbots, in the context of online interactions between stakeholders and organizations. The history of the chatbot begins in 1966 when Joseph Weizenbaum developed ELIZA, “a computer program for the study of natural communication between man and machine” (Weizenbaum, 1966). Today, chatbots have become an important tool for customer services (Bingjie and Sundar, 2018), but other usages are possible since chatbots can process a large amount of data independently and can learn to perform new tasks.

Organizational capabilities of chatbots

To better understand the possible usage of chatbots, it is necessary to reflect upon the function of chatbots in an organizational context. Assuming that chatbots provide new organizational capabilities, this section presents and discusses the most important ideas in the literature of organizational capabilities. Management research offers an incredible number of studies on organizational capabilities as intangible organizational resources offering competitive advantage. Organizational capabilities are generally understood as a sum of organizational competencies and individual abilities that turn know-how into results (Ullrich and Smallwood, 2004). Capabilities thus emerge from the advancement of organizational competences and routines and entail an integration of specialist knowledge across units, departments and individual members (Teece and Pisano, 1994). Particularly, the routinization of organizational activities facilitates the retention of capabilities into organizational memory, which, in turn, provokes a distinctive configuration of organizational resources (Knight and Cavusgil, 2004). Organizational capabilities have been found, for example, to predict the ability of an organization to internationalise (McDougall et al., 1994), to innovate (Knight and Cavusgil, 2004) and to retain its best employees (Gilani and Cunningham, 2017).

Organizational capabilities can have many sub-forms. In relation to chatbots, it is relevant to discuss technological capabilities, which refers to the broader context of technologies in organizations (Bharadwaj, 2000) and often describes those specific capabilities related to the effective use of technological knowledge “to assimilate, use, adapt and change existing technologies” (Dutrénit, 2004, p. 210), but also includes the capacity to develop new technologies or new products and processes (Kim, 1997). Technological capabilities have been considered central to the process of increasing productivity leading to greater organizational competitiveness (Bell and Pavitt, 1995). It has been noted that computers are more and more resembling humans in their abilities in performing tasks and in their capacity to learn while operating, such as dealing with matters from the office and home environment to routine purchases to strategic organizational decisions (Carley, 2002). It is exactly the capacity to analyse, perform, deliver and routinize that make them an important organizational capability.

Chatbots are a particular type of technology in that they show characteristics of autonomy and independent learning, which makes them more like “smart agents (Carley, 2002) because they engage in cognitive processing of information to respond to stimuli. Furthermore, research on artificial intelligence shows that smart agents can impact organizations on three levels: organizational boundaries, communication and storage (Carley, 2002). Smart agents can permeate the boundaries between people, tasks and resources, as they break the distinction not just of internal versus external boundaries, but also between different actors and objects in, out and among organizations. Smart agents act as communicators on behalf of organizations. Thus, the accuracy, the truthfulness and frequency of their communication has an impact on organizational reputation and performance. Smart agents can learn and retain a great deal of information and develop new knowledge that is not necessarily shared with humans; thus, they can affect group knowledge and organizational memory (cf. Carley, 2002 for a detailed discussion). Research in human–computer interaction has shown that people interacting with AI technologies perceive them as distinct social actors rather than technologies (Nass et al., 1994), confirming thus that AI is more and more positioned as “increasingly complex and life-like communication partners” (Guzman and Lewis, 2020, p. 4). Research in organization–stakeholder relationships has primarily focused on interpersonal communication dynamics and more recently, in mediated forms of online relationships, which are still forms of human-to-human communication.

Affordances in communication studies

Given the very nature of chatbots and their capabilities, one must reflect upon the nature of its agency and what it entails to do. Chatbots can exercise agency through their “performativity” (Barad, 2003; Pickering, 1995), or “through the things they do that users cannot completely or directly control” (Leonardi, 2011, p. 144). Yet, chatbot agency can be measured in terms of affordances. There is a plethora of definitions of affordances, but for the most part, they are described as possibilities for action. Typically, an affordance refers to a particular kind of functionality of a technology (Faiola and Matei, 2010), but it is not just a material property of a technology, it can also be a relational one. This means that the property is constructed in the interaction between people and technology (Hutchby, 2001). Affordances are dynamic and always emerging from the relationship between people and the environment. They can have both positive and negative, intended and unintended and short- and long-term associations; they may both enable and constrain actions (Conole and Dyke, 2004; Majchrzak et al., 2013).

New affordances may emerge because of the development of new technologies and this development may offer new possibilities for action by individuals (Evans et al., 2017). A recent study by Stoeckly et al. (2018) explored affordances of organizational chatbots in the context of enterprise systems and found 14 functional affordances that were later categorised into four groups. The identified affordances essentially represent properties of chatbots as objects in the studied organizations. These properties relate to the capacity of chatbots: “(1) to facilitate alignment by integrating information (e.g., receiving messages), (2) to provide control mechanisms (e.g., getting and setting triggers), (3) to enable interoperability (e.g., querying and invoking functionality of third-party systems, and (4) to increase efficiency (e.g., enriching messages)” (Stoeckly et al., 2018, p. 2023). Yet, the literature on affordances has shown that there are various understandings and perspectives. Affordances can be properties of the object/environment, a latent capability emerging in a particular context, or specific to the actor/species (Rice et al., 2017, p. 108).

Data collection procedures

Since the topic of interest is interdisciplinary in nature, a diversity of epistemological approaches and disciplinary traditions were included. The analysis was restricted to English language articles published in the established databases, ProQuest, EBSCO and CMMC. The search was open to all peer-reviewed articles, excluding conference proceedings, books, book chapters and editorials (White et al., 2017; Ye and Ki, 2012). Because the chatbot is a new phenomenon, the search criteria had no time constraints. To identify relevant articles, a string of keywords comprising a combination of “chatbot” or “bot” or “artificial intelligence” or “human–robot” or “human–computer” and “dialogue” and/or “conversation” and/or “interaction” and/or “discussion” and/or “discourse” and/or “relationship” was used in the abstract and title. The search was initiated on 31 January 2019 and completed on 11 October 2019.

The search resulted in 112 articles, which were further screened to remove duplicates and irrelevant papers. As the focus of this study was on interactions between humans and chatbots, all articles were removed from the data set that dealt with social bots or social or human robots without a clear chatbot connection. The final sample consisted of 62 discrete articles.

Data extraction and analysis

Based on early literature reviews (Lock, 2019; White et al., 2017; Ye and Ki, 2012), a coding protocol was created and shared between the two independent coders (see Appendix 1). Articles were reviewed by extracting the following information: journal name, year of publication, discipline, authorship (continent of university affiliation), type of paper (empirical or theoretical/conceptual), topic, the presence of an implicit or explicit chatbot definition, the original definition proposed by the authors, the terminology used to describe chatbots, the terminology used to describe the process of human–machine exchanges (e.g. dialogue, conversation, interaction), the conceptual foundations and theories, the perspectives addressed in the paper and the implications of the findings. For empirical papers, the methodology (quantitative, qualitative or mixed methods) and the dialogue metrics were also coded. Papers dealing with the development of instruments were also coded as empirical. Additionally, the presence of any ethical discussion was recorded. All this information was identified and then organized on a spreadsheet to enable comparison across studies and the translation of findings into higher-order interpretations. The disciplinary field was determined by the journal name and followed classification used by Statistics Finland (2018). An inductive approach was used since there is no list of predefined codes for the terminology used for chatbots, the terminology used to describe human–machine exchanges, the overall topic of the paper, the definitions of chats, theories and conceptual frameworks, metrics to measure chatbot functionality and the overall perspective discussed in the paper and its implications (Strauss and Corbin, 1990); codes were created while reading the articles. First, all terminologies, topics, theories, metrics, perspectives and implications as discussed by the original authors were recorded. Next, patterns of similarities across the codes were examined and grouped into macro-categories. Initial codes were revised on the spreadsheet to reflect the new categorization.

Perspectives were addressed based on the point of view underlined by scholars in the discussion and conclusion sections of the article; for example, if articles were about a chatbot's implication for marketing, the article was coded as “marketing perspective”. Similarly, for the implications, all mentioned implications were recorded first and later grouped into macro-categories based on similarities of the conclusions and the reflections offered. The data on implications were divided into six macro-categories (see Appendix 1). For the definition of chatbots, all explicit and implicit definitions were copied and pasted and later thematically analysed to identify the main characteristics, descriptors and underlined capabilities. Constant consensus meetings of all researchers established the data extraction stage and the codes used in the analysis of publications.

An intercoder reliability test was performed on a random sample of seven articles on the latent variables. The first intercoder reliability test was low, and it was discovered that the descriptions of the codes, especially those regarding topics and implications, were too extensive and partly overlapping. The protocol was revised and further limited. After this, the articles were coded again and a new intercoder reliability test on another seven articles was performed. Results of this second check showed a good level of reliability. The level of intercoder agreement was 94.8% in every category.

Terminology

The analysis indicated that articles used a variety of terms to define chatbots, often even interchangeably. For most, chatbot or chat bot or chatter bot were the preferred terms (N = 61), followed by agent (N = 21), robot (N = 21), (conversational) bot (N = 10) and virtual assistant (N = 2) [2]. Just 29 papers out of 62 offered an explicit definition of chatbot. The definitions of chatbot varied but not significantly (Figure 2). Some definitions compared these technologies to IM Bots or content-driven bots. Others described them as forms of robots particularly in those articles where the preferred terminology was either chat robots, conversational service robots or a specific type of social robot. When scholars used the term agent, the definitions tended to focus on specific characteristics, such as being conversational, a machine, an artificial intelligence or a virtual process. Finally, some definitions of chatbots emphasised dialogue or machine conversation systems, chat services and communication programmes as main features.

We next analysed the terminology used in the literature to describe the context of usage, basically the material agency of chatbots in the context of organization–stakeholder interactions, that is, “the capacity for nonhuman entities to act on their own, apart from human intervention” (Leonardi, 2011, p. 148). Similarly, as for the actual naming of this technology, scholars have used a variety of different terms even in the same paper, thus we recorded all first-time appearances in the paper. Interaction (N = 53) was the most-used term to describe organization–stakeholder interactions via chatbots, followed by conversation (N = 38) and dialogue (N = 18). Discussion (N = 3), discourse (N = 2) and relationship (N = 1) were used marginally. It should be noted that in most of this literature, the concept of dialogue refers to the sequence of conversational turns that a machine, in this case chatbot, takes to reply to an inquiry (Jurafsky and Martin, 2019). Scholars using the term “dialogue” were thus particularly keen in studying the sequence of conversational turns in specific stakeholder interactions, rather than the orientation of communication towards dialogue. Overall, the top three terms for describing organization–stakeholder interactions via chatbots were expected since a large number of the articles were about developing and/or testing the humanness of this technology through measures of conversation skills and abilities that showcase particular types of material agency.

Descriptors

Looking closely at the main features that characterize these technologies, chatbots were primarily described as service-oriented, performing logical and cognitive operations, interdependent systems, machine automation and independent actors (see Table 1). Service-oriented chatbots were described as service providers trying to solve users' problems and respond to users' service needs. Chatbots that were described as performing logical and cognitive operations were based on coded or machine learning algorithms. These algorithms support logical and cognitive operations, for example, by selecting suitable answers and expressions to users' questions and comments. Chatbots with interdependent systems were described as relying on customer interaction history and able to process such information in their answering by using natural language. Machine automation was used to emphasise the mechanical performativity of chatbots and the technical features that allow chatbots to answer user questions without human help. Finally, several features pointed to independent action of chatbots, essentially underlining more social skills than technological ones, like reasoning and making decisions when the chatbot interacts or communicates with a user.

Capabilities

Based on descriptors, we identified the different capabilities of chatbots. Chatbots were seen to possess content provision, conversational and self-governing capabilities. Content provision means that the chatbot is providing content in the form of textual or verbal information and delivering knowledge, for instance, offering information to customers, answering questions and so on. The conversational capability arises from the chatbot's purpose to interact and engage in conversations. Interaction can happen via text or voice through talking heads or embodied animated avatars. The conversational capability is a particularly relevant feature of chatbots as it differentiates them from other technologies by indicating how close to human-like the communication exchange is between chatbots and humans. Another important capability is the autonomy of the technology, what we called the self-governing capability. The fact that this technology can make choices in what and how to answer and can learn from previous conversational exchanges is seen as a specific element of the chatbot.

Eleven different conceptual foundations were recorded from the analysed articles, and these pertain the disciplinary domains of computer science (N = 16), engineering (N = 15), psychology (N = 15), computer-mediated communication (N = 15), sociology (N = 12), linguistics (N = 11), information technology (N = 7), organizational studies (N = 6), philosophy (N = 3), general communication (N = 3) and mass communication (N = 2). Ten articles did not include any specific conceptual foundation as they did not refer to any model, framework or academic study that was possible to track back to a research field [3].

With respect to the theories, more than half of papers (N = 43) did not mention any theory despite reviewing early studies, existing models and empirical tests. In the remaining papers, 25 different theories were identified but none of them clearly rose above the others. Role theory was the most common (N = 7), followed by media equation theory (N = 5), unified theory of technology acceptance (N = 5), social information processing theory (N = 4), theory of relational coordination (N = 3) and innovation diffusion theory (N = 3).

Most articles were empirical studies (N = 43); among those, quantitative research methods were employed in 36 papers. Only two papers employed a qualitative approach. Five papers used mixed methods. All metrics measuring the quality of chatbot–stakeholder interactions were also systematically recorded to better understand how the academic community assesses the level of technical development of specific chatbot software in addressing diverse interactions. The quality of chatbot–stakeholder interactions was measured in 18 articles. In these articles, 81 discrete metrics were recorded (see Appendix 2) and later grouped into macro-categories on the grounds of their overall measurements. The most-cited metrics across all empirical studies measured perceived human feelings (N = 15) and chatbot interaction skills (N = 13). This is expected as the majority of the papers were technological and were interested in studying and measuring how individuals perceive the communicative interaction experience with the machine.

With respect to the perspectives, eight main points of view were found (see Appendix 1 for an overview of the definitions of these perspectives). The top perspective was machine language (N = 23), followed by marketing (N = 11) and psychology (N = 6). The communication perspective was addressed in eight papers and organizational and stakeholder perspectives, respectively, in six papers. Ethical and managerial perspectives were addressed in only one paper. When cross-tabulating research topics and perspectives, the machine language perspective was used primarily in articles that studied topics such as chatbot development (N = 16) and testing chatbot language and conversational skills (N = 4). A marketing perspective was often taken in research that studied chatbot effects and usage in organizations (N = 6). A communication perspective was present in research that studied the development of chatbots (N = 3), testing chatbots language and conversation skills (N = 3) or chatbot usage in organizations (N = 2). But, the topic of chatbots as learning tools was only studied from a machine language or a psychological perspective, whereas troubleshooting chatbots was studied only from an organizational or an ethical perspective (see Figure 3).

The implications discussed in the reviewed literature primarily dealt with improving [the] chatbot as a tool (N = 24) and chatbot effects on stakeholder interactions, responses and engagement (N = 15) (see Figure 4). When implications were cross-tabulated with disciplines, publications in computer and information science (N = 12) and psychology (N = 7) primarily focused on improving [the] chatbot as a tool. General communication papers addressed implications dealing with chatbot effects on stakeholder interactions, responses and engagement (N = 3), results of the research are improving chatbot as a tool (N = 2), and critical reflections on chatbot development (N = 2). Even though the industry is divided on the potentials and pitfalls of artificial intelligence, ethical discussions on the use of these technologies in organizational contexts are limited. Our analysis indicated that only four articles out of 62 included an ethical discussion regarding chatbots: two were in general communication articles, one in computer science and another in a marketing article. With regards to the topics, ethical issues were discussed when scholars addressed how chatbots affect and are used in organizational settings.