GenAI-Infused Service Delivery: Micro-Level Augmentation Patterns at the Service Frontline

Hybrid Human–AI Service Delivery

AI infusion has traditionally been seen as a means to automate service delivery by replacing FSE tasks and directly influencing customer perceptions (Huang and Rust 2018; McLeay et al. 2021). However, in light of AI’s limitations and the demands of personal, emotional, and knowledge-intensive service contexts, the focus shifted from merely designing AI technologies for customers to examining how FSEs and AI together form hybrid human–AI service delivery (Table 1).

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Table 1.

Streams of Literature on Hybrid Human–AI Service Delivery.

Field	Focus	Key Contributions	References
Configurations, Archetypes, and Typologies	Categorizes hybrid service encounters and human–AI relationships, focusing on task and role distribution.	• Introduces high-level structured typologies of service encounters and relational modes • Highlights implications for human work given a continuum of substitution and complementation.	e.g., De Keyser et al. 2019; Huang and Rust 2018; Koponen et al. 2023; Marinova et al. 2017
Frontstage and Backstage AI Infusion	Focuses on how AI enhances or substitutes human roles visibly (frontstage) or invisibly (backstage) in service processes.	• Offers a more granular view of where and how AI supports human work. • Emphasizes the connection between backstage and frontstage.	e.g., Bock, Wolter, and Ferrell 2020; Hogreve, Iseke, and Derfuss 2022; Mortati and Viana Mundstock Freitas 2025; van Doorn et al. 2023
GenAI-Infused Service Routines	Investigates how GenAI reshapes service routines and links frontstage and backstage activities.	• Extracts MAPs along service routines and refines the substitution-complementation continuum. • Identifies mechanisms of service permeation that show how GenAI blurs the boundaries between front- and backstage.	This paper

Note. GenAI = generative AI; MAPs = micro-level augmentation patterns.

Recent research has advanced our understanding of the hybrid nature of AI-infused service delivery by conceptualizing how responsibilities are distributed between human and AI actors through the analysis of configurations, archetypes, and typologies (e.g., De Keyser et al. 2019; Koponen et al. 2023; Larivière et al. 2024). Advances in AI increasingly enable it to take over diverse service roles, with distinctions such as mechanical, thinking, and emotional intelligences informing predictions about when AI may substitute FSEs (Huang and Rust 2018). Building on these capability-based distinctions, scholars have moved beyond the traditional human-to-human encounter, uncovering a spectrum of configurations, from AI-to-AI to blended human–AI interactions (De Keyser et al. 2019). These evolving hybrid human–AI service encounters underscore that AI is not a one-size-fits-all solution but varies in its capacity to substitute or complement human work (Marinova et al. 2017). The augmentation of service work can thus be understood as a continuum of substitution and complementation, in which FSEs and AI perform service routines either sequentially or simultaneously (Le et al. 2025). Augmentation enables humans and AI to perform complementary or joint tasks and to co-produce the service (Blaurock, Büttgen, and Schepers 2024), while implicitly reconfiguring professional roles, positioning humans not just as service providers, but as collaborators, coordinators, or differentiators (Koponen et al. 2023; Larivière et al. 2017). For example, AI systems engage FSEs by proactively asking for input and feedback (Blaurock, Büttgen, and Schepers 2024). Despite these contributions, the literature on hybrid human–AI service delivery remains predominantly conceptual, leaving key questions unanswered about micro-level implications and the dynamics along the substitution-complementation continuum in AI-driven augmentation.

Ongoing research has also aimed to unpack human–AI hybrids by examining how AI systems enhance or substitute human roles, both visibly on the frontstage and invisibly in the backstage of service processes (e.g., Bock, Wolter, and Ferrell 2020; Mortati and Viana Mundstock Freitas 2025; van Doorn et al. 2023). Building on a service design perspective, Mortati and Viana Mundstock Freitas (2025) conceptualize AI as a technology that co-creates value and copilots service delivery with both users and machines across frontstage and backstage environments. This stream offers a more granular view of how AI supports human work (Liu et al. 2024), showing that the infusion of AI reshapes traditional boundaries between the frontstage and backstage (e.g., Mortati and Viana Mundstock Freitas 2025; Robinson et al. 2020). For example, customers may misattribute AI-generated responses to humans, resulting in counterfeit encounters and ambiguous role expectations (Robinson et al. 2020). In light of this, adequate AI support at the backstage (e.g., decision-support tools) critically impacts the quality of frontstage interactions, reinforcing their interdependence as articulated in the AI-mediated service-profit chain (Chen, Hsieh, and Chan 2024; Hogreve, Iseke, and Derfuss 2022). While the link between service frontstage and backstage is acknowledged, the influence of emerging AI technologies, such as GenAI, on this connection remains underexplored.

At the same time, growing interest in the technological capabilities of GenAI models (Ferraro et al. 2024; Liu et al. 2024) has highlighted their potential to alter how humans and AI interact in service delivery (Brynjolfsson, Li, and Raymond 2025). Given the ability to understand natural language and generate text, GenAI systems (e.g., Microsoft Copilot, SAP Joule) exhibit a higher level of agency (Chen, Hsieh, and Chan 2024; Le et al. 2025), challenging the prior insights on how FSE and AI work together along service processes and the way these systems are embedded into the service routines. Against this backdrop, the rise of GenAI introduces a new layer of complexity. Technologies such as LLMs not only extend the functional boundaries of AI in service contexts but also generate paradoxical dynamics, being perceived as both highly capable and vulnerable (e.g., prone to hallucinations and biases) and as offering personalization while raising concerns about intrusiveness (Ferraro et al. 2024; Liu et al. 2024). Recent advancements in agentic AI further accelerate these developments, as AI systems increasingly exhibit autonomy and enhanced capabilities in reasoning and learning, enabling them to leverage a wide array of enterprise tools (Acharya, Kuppan, and Divya 2025).

Despite growing interest in hybrid human–AI service delivery, our understanding of how GenAI influences FSEs’ tasks and their relationships with AI, beyond a dyadic view of substitution or complementation toward joint enactment, remains limited. Similarly, while distinctions between frontstage and backstage domains exist, the interplay introduced by AI across these layers is only beginning to be understood. As GenAI technologies are being infused in service delivery, this study examines their influence on service delivery by analyzing how they reconfigure routines across the frontstage, backstage, and their intersections.

Organizational Routines in Service Delivery

Organizational routines in service delivery provide a theoretical foundation for analyzing the augmentation of service work. Routines are behavioral patterns of actions performed repeatedly to achieve a specific goal (Pentland and Hærem 2015). Research on organizational routines examines how they are constituted and reinforced over time (Feldman and Pentland 2003). In general, the routinization of service tasks is crucial for increasing efficiency and reducing cognitive effort (Lemken and Rowe 2020). For example, frontline work in call center environments is frequently described as highly routinized, designed to efficiently manage the high volume of incoming calls (Malhotra et al. 2013). Within the realm of customer support services, two overarching organizational routines predominate: problem identification and problem solving. Pentland (1992) was among the first to examine call center agents’ work through the lens of organizational routines, focusing on problem identification and allocation activities such as assigning, referring, transferring, and escalating. Das (2003) extended this view by investigating problem-solving routines. Accordingly, solving problems can be summarized as multiple steps of locating, adapting, and generating solutions.

While early research on organizational routines emphasized their stability, later work on routine dynamics focused on how routines evolve and adapt to changing environments (Feldman and Pentland 2003). Deeply intertwined with their context, routines both shape and are shaped by it, while technologies like GenAI act as powerful exogenous forces influencing their enactment (Murray, Rhymer, and Sirmon 2021). Efforts to provide a more detailed understanding of AI technology use in routines often focus on augmentation as a feature of the infused technology itself, rather than as a function of the service routines where this augmentation occurs (e.g., Blaurock, Büttgen, and Schepers 2024; Murray, Rhymer, and Sirmon 2021). However, human actors and material aspects of technology become interconnected within the service routines (Gaskin et al. 2014), calling for an investigation of FSEs’ GenAI-infused patterns of actions and the dynamics of these socio-material ensembles in performing service routines and the resulting blurred boundaries of backstage and frontstage activities.

The organizational routines lens helps reveal how FSEs and GenAI interact at the micro level, co-performing tasks and shifting responsibilities between frontstage and backstage work. It allows us to move beyond high-level categories and to develop a more refined understanding of hybrid service delivery. This grounding motivates our study of how GenAI infusion constitutes augmentation patterns (RQ1) and their impact on frontstage and backstage service routines (RQ2). We address the gap in understanding how GenAI affects service delivery by uncovering augmentation patterns along the substitution-complementation continuum.

Sample Description

Our qualitative investigation explored the realm of technical support work and IT Service Management (ITSM) as a subfield of general customer support, a field that has been extensively studied within the longstanding body of research on organizational routines (e.g., Das 2003; Pentland 1992). When issues arise with digital technologies, customers reach out to frontline service providers through various channels to resolve their technical problems. To reflect the field’s heterogeneity, we drew data from four organizations spanning diverse service channels, IT products, customer types, and B2B and B2C contexts. Detailed descriptions of the four organizations are available in Web Appendix 1. Our empirical study is part of an overarching research project that develops advanced analytics and ticketing solutions to store and manage incoming and historical customer requests and interactions. The larger project aimed to design a holistic hybrid intelligence system with distinct modules to support FSEs through AI in a human-centered manner. The iterative development process allowed participants to gain practical experience over time, which informed their responses during the data collection phase.

Data Collection

To collect empirical data, we conducted semi-structured interviews with FSEs, managers, and AI experts, aiming to triangulate views on the underlying routines, the overarching service delivery process, and the associated technical changes. This approach allowed flexible and in-depth discussions with the informants and enabled us to detail their subjective perspectives (Ritchie, Lewis, and Elam 2013). Organizational routines informed the design of the interview guidelines in terms of addressing the problem identification and problem-solving stages (Das 2003; Pentland 1992). To examine differences in infusing predictive vs. generative AI into frontstage and backstage service delivery, we conducted two interview series: pre-GenAI and post-GenAI. Between the two interview series, we held workshops and focus groups with researchers and a development team to co-design and test GenAI solutions for augmenting customer service routines. Conducting interviews with the same individuals at different points in time provided insights into how their perceptions and experiences of AI tools evolved, particularly in response to the emergence of GenAI.

The pre-GenAI series (2020–2021), involving 21 voluntary participants, focused on identifying issues and requirements related to service routines and predictive AI. Furthermore, the first series provided knowledge of the original service routines without any AI. The post-GenAI series (2023–2024) involved 20 voluntary participants and explored GenAI solutions. Following an abductive approach, we refined the second interview series based on insights from the first, adding example prompts and an introduction to GenAI and LLMs. Each interview lasted an average of 45 minutes. We conducted the interviews online, recorded the audio, and transcribed the files accordingly. Data collection ceased upon reaching theoretical saturation, meaning that subsequent interviews confirmed earlier findings and yielded no new insights (Corbin and Strauss 2015). Interview questions, interviewee backgrounds, and an overview of the workshops and focus groups are available in Web Appendix 2.

Data Analysis

We analyzed the collected interviews through an adapted grounded theory approach following Corbin and Strauss (1990). To deepen our understanding of service routines in light of GenAI, we employed an abductive research design to not only inform our interview guidelines but also to reflect the data of both series (Pemer 2021). We iteratively moved between emerging patterns in the data and analytical lenses offered by service routine literature (Das 2003; Pentland 1992). Our approach prioritized intensive group discussions and consensus-building through an iterative process of comparing and integrating codes and categories, rather than relying solely on quantitative measures of intercoder reliability (Berente et al. 2011). The codes and categories were discussed with the entire research team, particularly on three occasions: after the first series, after the second series, and during the analysis of the problem-solution pairs and patterns of augmentation. To address the widely recognized challenge of overcoming preconceptions in qualitative data analysis (Charmaz 2014), we later incorporated an impartial co-author into our research team.

In the first interview series spanning 2020 to 2021, we employed open and axial coding to extract requirements and categorize issues (Corbin and Strauss 1990). First, we used an open coding strategy to understand FSEs’ and managers’ viewpoints and experiences with AI, drawing on the interviewees’ empirical statements (Corbin and Strauss 2015). As we gathered data before GenAI was adopted, the analysis focused on broader AI applications. Afterward, we applied axial coding to categorize the data into recurring issues related to service routines. This step was pivotal in identifying the foundational problems concerning existing service routines and aggregating expectations regarding the use of AI. Subsequently, we further categorized these concepts according to the service routine literature following our abductive approach.

Analogously, we analyzed the second interview series conducted in 2023 and 2024 by adopting the above-mentioned qualitative approach. However, the analysis of this series focused on coding solutions that emerged with GenAI. This phase was instrumental in delineating solutions from GenAI applications and attaching them to the identified issues. Accordingly, the interview guidelines and the approach to analyzing the data were informed by the results of the first interview series, in line with our abductive design. Again, we coded the interviewees’ statements and mapped the codes to the given routines during an open and axial coding phase. At this stage, we again re-engaged with the literature on service routines to interpret and categorize emerging patterns. Our abductive strategy guided the refinement of our coding scheme throughout both interview series. For example, as we encountered recurring accounts of documentation work and AI input preparation, we conceptualized a new routine category: documentation and AI feeding. The resulting data structures are available in Web Appendix 3. The data analysis was intertwined across the two series. A shared coding scheme was used by two coders and refined by the entire research team iteratively by comparing codes and categories constantly and across both series (Charmaz 2014).

Then, we employed an additional axial coding phase to map the solutions to the corresponding issues. Web Appendix 4 illustrates this mapping along the service routines. Following Berente et al. (2011), we performed selective coding to link and interpret the derived problem-solution pairs and, ultimately, to discern MAPs. To analyze the MAPs within the context of service delivery, we added additional dimensions and organized the evolved patterns according to the service frontstage and backstage (Mortati and Viana Mundstock Freitas 2025). We examined the interplay between the service frontstage and backstage through the identified MAPs to account for GenAI’s impact on service delivery and theorizing mechanisms. In line with Henfridsson and Bygstad (2013), we define mechanisms as the underlying causal structures that explain how and why phenomena unfold. In our context, mechanisms are the generative processes through which GenAI permeates service delivery, and by abstracting from the empirically grounded MAPs, we conceptualize two higher-order service permeation mechanisms that explain how GenAI reshapes the coupling of human and AI activities across frontstage and backstage domains.

Micro-Level Augmentation Patterns

Through the aggregation of multiple micro-level problem-solution pairs that represent various forms of augmentation through GenAI-infusion, seven overarching patterns of augmentation on a continuum of substitution and complementation emerged: triaging and solving simple customer requests (MAP-1), summarizing and handing over requests (MAP-2), copiloting the identification and resolution of requests (MAP-3), matching knowledge and experts (MAP-4), guiding and sustaining service delivery (MAP-5), enhancing service dialogues (MAP-6), and crafting knowledge and training data (MAP-7). Each MAP aggregates reusable approaches to achieve specific augmentation goals. Table 3 presents excerpts of each MAP, including goals and problem-solution pairs. Pairs and patterns that emerged in the GenAI phase are marked with an asterisk. In addition, it offers illustrative future research questions for each MAP. A comprehensive MAP overview in Web Appendix 5 further details the roles of GenAI and FSEs, as well as key technological aspects, including retrieval-augmented generation (RAG) and model fine-tuning for classification tasks.

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Table 3.

Micro-Level Augmentation Patterns.

MAPs and Goals	Problem	Solution	Exemplary Research Questions
Triaging and solving customer requests (MAP-1) FSEs should be relieved of repetitive requests and standard information gathering, allowing efficient routing or direct escalation based on priority.	Large numbers of simple and recurring customer requests that should be subject to automation	Chatbot system to handle routine inquiries and provide immediate responses	• How does GenAI reshape the division of labor between agents and FSEs in triaging customer requests? • What enables seamless handovers between GenAI and FSEs in partially automated service routines?
	Repetitive requests for personal information, system details, and basic incident information	Identification of provided and missing information
	Incorrect classification of requests leads to unbalanced workload, faulty prioritization, and additional reassignments	Ticket classification, prioritization, and routing
Summarizing and handing over requests (MAP-2) FSEs should receive consistent, complete descriptions and summaries to efficiently handle requests and reference past solutions.	Poor documentation of escalated requests causes additional work steps and extends the processing time	Problem documentation and summarization	• How do GenAI-enabled summaries facilitate coordination across frontstage and backstage service routines? • In what ways does summarization contribute to service permeation and the continuous improvement of GenAI systems?
	Cumbersome and time-consuming manual documentation of tickets	Ticket documentation and summarization
	Inconsistent and low-quality ticket documentation	Bulk improvement of existing documentation
Copiloting the identification and resolution of requests (MAP-3*) FSEs should be provided with real-time support to solve complex requests.	Time-consuming solution search in knowledge base articles, online forums, or ticket documentation	Recommending appropriate follow-up actions (*)	• How do GenAI systems alter knowledge discovery and utilization in unstructured data environments? • What mechanisms calibrate GenAI systems’ involvement to ensure human oversight in high-impact service moments?
	New, unfamiliar, and incomplete requests require a higher level of attention from employees	Identifying critical questions to enrich problem statements (*)
	Lack of decision support for escalation of requests implies avoidable effort	Aiding FSEs in deciding when to escalate (*)
Matching knowledge and experts (MAP-4) FSEs should receive contextualized knowledge from multiple data sources or be referred to topic experts.	Difficulty in identifying knowledgeable colleagues	Extraction of skill profiles based on history (*)	• How can service organizations balance automation and human control in GenAI-supported expert allocation to maintain accountability? • How do GenAI systems differ from traditional AI in handling unstructured, context-rich service knowledge for expert and knowledge matching?
	Lack of knowledge transfer between FSEs and forwarding to experts	Matching of knowledgeable colleagues
	Effortful extraction of solutions from past requests	Summarization of problem solutions
	Multiple systems and media disruptions complicate the solution search	Matching solved tickets and other knowledge bases
Guiding and sustaining service delivery (MAP-5) FSEs should be guided to follow defined processes and standards for high-quality service.	Lack of emotional support during customer interactions	Sentiment analysis and emotion regulation guidance	• What distinguishes GenAI’s ability to dynamically generate service protocols from traditional AI’s static workflow optimization? • How do FSEs perceive and integrate GenAI’s emotionally adaptive suggestions into customer-facing communications?
	Lack of real-time feedback, only manager reviews	Feedback from assessing interaction quality (*)
	No automatic tracking of pending tickets and progress updates, users are uninformed about ticket status	Automated reminder and update messages
	Time-consuming quality assessment	Ticket quality control (*)
Enhancing service dialogues (MAP-6) FSEs should be provided with writing support tools to improve and speed up their communication.	Users face impersonal service due to local nuances and inadequate support in their official language	Customization of solutions and conversation styles	• How does GenAI infusion shift the skill requirements for FSEs from communication proficiency to cognitive and problem-solving abilities? • In what ways does GenAI-generated language permeate service interactions, and how does it influence customers’ perceptions of service authenticity and professionalism?
	Language barriers and inconsistencies in support communication	Machine translation
	Inefficient communication	Smart replies
	Manual effort of communication and input of user data	Email writing support
Crafting knowledge and training data (MAP-7*) FSEs should be involved in delegating training data and should be relieved from the operational effort required to structure it.	Inadequate and outdated knowledge base articles and solution material	Creation of knowledge base articles (*)	• What are the emerging roles of FSEs in co-creating, refining, and validating training data for GenAI systems in service organizations? • What routines and mechanisms support iterative learning between FSEs and GenAI systems in updating service knowledge and AI capabilities?
	Lack of training data and quality as well as predefined responses for known issues	Generation of training examples (*)

Note. *Indicates emerging pairs and patterns compared to pre-GenAI. GenAI = generative AI; FSE = frontline service employee.

Service Permeation Mechanisms

The MAPs show that augmentation unfolds throughout the service delivery process (i.e., influencing multiple service routines) and across service frontstage and backstage (i.e., various interaction points involving FSEs and customers). While some of the patterns indicate the remaining distinction and transitions between frontstage and backstage via the line of visibility (e.g., MAP-1, MAP-2), the majority of patterns highlight the increasingly permeable boundaries between frontstage and backstage service routines due to the infusion of GenAI (post-GenAI), which distinguishes it from predictive AI (pre-GenAI). They illustrate how GenAI’s influence unfolds in frontstage service delivery by augmenting FSEs via the service backend, shaping how employees engage with and act on GenAI advice. At the same time, its capabilities are simultaneously reinforced through backstage data flows and continuous feedback. We account for these impacts by identifying and conceptualizing the underlying mechanisms of service permeation.

We propose service permeation as the mechanisms of GenAI infusion across FSEs’ service routines through the identified MAPs, enabling contextualized and adaptive services. It posits that GenAI’s impact, whether through next-best actions, contextualized information, or summaries, is primarily generated in the service backstage but extends into the service frontstage through the line of visibility. Once permeated, GenAI-generated knowledge remains accessible and adaptable through LLMs and real-time interactions, ensuring its continuous generative potential for delivering contextualized service. These service permeation mechanisms are self-reinforcing (Henfridsson and Bygstad 2013), meaning they recursively feed themselves through feedback and learning loops involving FSEs and GenAI. Although the initial impact arises directly from the infusion of GenAI, the loops and self-reinforcing effects lead to continuous intensification and permeation. As a result, the mechanisms are cyclical, as the effect also operates in the opposite direction from the frontstage to the backstage. For example, generated resolutions might feed back into the underlying training data or define GenAI’s contextual memory. In addition, service permeation mechanisms are composites. We follow the analogy of permeation in the physical sciences (Barrer 1941), which spans three interconnected mechanisms (Figure 1). (1) Sorption involves aggregating and contextualizing structured, unstructured, and multimodal data from both backstage (e.g., knowledge bases, transcripts) and frontstage (e.g., customer inputs, emotional cues) sources to enable GenAI augmentation. (2) Diffusion captures the internal integration and transformation of this knowledge, where GenAI and FSEs co-create value. It unfolds simultaneously (real-time GenAI support during customer interactions) and sequentially (FSE-guided refinement of GenAI capabilities over time) through the patterns of augmentation. (3) Desorption reflects the outward delivery of service, where GenAI-infused knowledge reaches the customer through either FSE-facilitated interactions or AI systems.

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Figure 1.

The mechanisms of GenAI service permeation.

Figure 2 depicts the MAPs across service routines and their positioning in the frontstage and backstage, separated by the line of visibility. The logic of this framework begins with understanding the underlying service routines, proceeds to identifying and implementing problem–solution pairs that constitute the MAPs, and ultimately translates the impact of GenAI on the service delivery journey at the frontstage through the mechanisms of service permeation. The arrows indicate how the patterns and resulting services permeate service delivery. According to our systematization of the MAPs and our concept of service permeation, we found two recurring instances of service permeation mechanisms: simultaneous service permeation , where GenAI systems operate in real-time to deliver actionable insights to FSEs, which permeate to the frontstage interactions with customers offered by the FSEs; and sequential service permeation , where FSEs, in collaboration with GenAI, curate and refine AI training data to improve its autonomous problem-solving capabilities and GenAI’s flexibility. The latter also illustrates how prior frontstage activities, such as handling recurring customer issues, are increasingly absorbed into backstage functions through emerging routines of documentation and AI feeding. At the same time, information from the service frontstage is fed back into the GenAI systems, as indicated by the bidirectional arrow (see MAP2 and MAP7).

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Figure 2.

MAP-enabled service permeation in GenAI-infused service delivery.

Theoretical Implications

Our study makes two main theoretical contributions to the literature on hybrid human–AI service delivery (e.g., De Keyser et al. 2019; Marinova et al. 2017; Mortati and Viana Mundstock Freitas 2025). First, the seven empirically grounded MAPs refine the view of augmentation as a continuum of substitution and complementation by providing an integrative lens on the processual changes shaping service delivery across frontstage, backstage, and their intersections (Baer, Waardenburg, and Huysman 2025; Marinova et al. 2017). As a complement to high-level typologies and archetypes of service delivery (De Keyser et al. 2019; Huang and Rust 2018; Koponen et al. 2023), we provide a routine-level and process-centric perspective on augmentation and the configurations of human–AI hybrids. As such, our study is an important account for organizational routines theory (Feldman and Pentland 2003) as we demonstrate how this theory facilitates the exploration of augmentation and its implications for FSEs’ routines. The MAPs make explicit how routines shift from being performed primarily by FSEs to being part of a GenAI-infused service delivery process. Notably, GenAI augmentation does not follow a singular or uniform pattern (Henkel et al. 2020; Jia et al. 2024). Instead, it gives rise to multiple, evolving augmentation configurations throughout the service delivery process. Some MAPs predominantly reflect task substitution (e.g., MAP-1, MAP-2), whereas others capture complementary forms of augmentation that enhance rather than replace human work (e.g., MAP-3, MAP-5, MAP-6). Consequently, FSEs must continuously adapt to these shifting configurations of human-GenAI collaboration, challenging assumptions of predictable or standardized support (Liu et al. 2024).

Second, we empirically demonstrate that GenAI fosters a closer coupling between service backstage and frontstage, driven by two self-reinforcing service permeation mechanisms that enable the delivery of contextualized and highly adaptive services. Thereby, we not only complement prior studies in identifying AI’s impact in specific frontstage and backstage routines (Bock, Wolter, and Ferrell 2020; Mortati and Viana Mundstock Freitas 2025; Robinson et al. 2020), but also explain the mechanisms through which GenAI permeates services. Service permeation is reflected in mechanisms for simultaneous service permeation (e.g., copilots or GenAI-based coaches) and sequential service permeation (e.g., supervising AI systems or curation of training data). These propositions help explain the interplay between the service backstage and frontstage (i.e., service-profit chain) by highlighting that service experience is increasingly shaped not only by FSEs, but also by GenAI models, their underlying training data, and the contextual information they utilize (Chen, Hsieh, and Chan 2024; Hogreve, Iseke, and Derfuss 2022; Knote et al. 2020). We show that through GenAI infusion, the service delivery lifecycle and prior model of organizational routines in customer support services (Das 2003; Pentland 1992) is being expanded by a new type of service routine, termed documentation and AI feeding. New routines evolve for supervising, prompting, and feeding GenAI systems, through which FSEs indirectly influence service delivery. This introduces new FSE responsibilities and adds backstage tasks to core FSE delivery duties (Huang and Rust 2018; Wirtz et al. 2018). Despite limited attention to managing GenAI systems and data in service contexts, our study provides a foundation for examining sequential service permeation and its manifestations in routines and augmentation patterns.

Managerial Implications

Our research has important implications for service organizations, managers, and designers aiming to harness the potential of GenAI in customer support and beyond. By introducing MAPs and the mechanisms of service permeation, we provide actionable guidance for integrating GenAI into both frontstage and backstage service routines and managing the continuum of substitution and complementation. Service leaders should design GenAI deployment strategies that emphasize backstage utility while preserving the human touch and controlling quality in customer-facing interactions. Our findings indicate that GenAI delivers contextual value when applied to backstage functions such as summarizing tickets (MAP-2), copiloting decision support (MAP-3), or coaching FSEs during service delivery (MAP-5). Managers should move beyond viewing GenAI as just an automation tool and recognize it as an active service actor, one that collaborates with FSEs in real time, supports decision-making, and continuously enhances service routines through knowledge sharing. With greater autonomy, agentic AI is likely to combine and amplify these patterns, enabling more sophisticated orchestration of GenAI-augmented service routines. Thus, MAPs not only offer a lens for understanding current GenAI-infused services but also serve as a foundation for designing and improving future autonomous agents and multi-agent systems, ensuring their continued relevance in increasingly agentic service contexts.

With its generative and agentic traits, GenAI blurs the boundaries between the service frontstage and backstage, a phenomenon we conceptualize as service permeation. Managing this permeation requires balancing augmentation benefits with human oversight and acknowledging the duality of GenAI’s impact (Ferraro et al. 2024). On the one hand, GenAI systems can produce highly persuasive yet hallucinated outputs, heightening the risk of overreliance during simultaneous service permeation. To mitigate such risks, firms should establish guardrails, including escalation thresholds, transparency protocols, and explanation cues, across autonomous chatbots (MAP-1) and collaborative copilots (MAP-3). Practitioners must also ensure that FSEs critically engage with GenAI recommendations and continuously refine models and data (MAP-7). Conversely, GenAI can itself function as a guardrail by identifying inconsistencies (MAP-5) or inappropriate communication (MAP-6) that might otherwise escape human attention (Henkel et al. 2020; Luo et al. 2021). For example, MAP-7 enhances documentation and data quality, fostering knowledge transfer and model improvement. Managers should therefore regularly assess the extent and quality of service permeation across the delivery process to detect infusion gaps and guide strategic adjustments that sustain human accountability and service excellence.

As service permeation becomes a critical driver of service performance, organizations should invest in workforce development initiatives that equip FSEs to collaborate effectively with GenAI systems. Decision-making by GenAI systems, and their reliance on curated frontline data, leads FSEs to take on expanded roles as co-creators and knowledge curators (Li et al. 2024). This includes developing judgment on when to act on or override AI recommendations and establishing routines for documenting, annotating, and refining service knowledge, practices that drive sequential service permeation and support continuous system learning. While our findings suggest that GenAI increasingly augments interpersonal communication and emotional expression (e.g., Brynjolfsson, Li, and Raymond 2025; Henkel et al. 2020), the skill demands for FSEs are evolving. Greater emphasis is now placed on domain knowledge and technical proficiency to ensure accurate service delivery. In addition, competencies such as AI literacy, context engineering, and prompt engineering are becoming essential for effectively managing and leveraging GenAI-infused services (Knoth et al. 2024). In conclusion, service organizations must equip FSEs with the skills to manage, guide, and improve GenAI interactions.

Limitations

While our study provides valuable contributions to the literature and practice, certain limitations must be acknowledged. A key limitation of this study is its empirical scope, as it focuses on four organizations within a single industry. While our approach followed qualitative research criteria for reliability and validity, the sampling limits the generalizability of the findings. In particular, we focused on technical customer requests, a sector promising the potential of GenAI infusion. Broadening the scope of this research to include various customer service domains, such as sales, general non-technical customer care, and contact centers, would shed light on the adaptability of GenAI-augmented service practices. Moreover, despite the variety of service organizations, digital services, and service channels, the derived patterns are not exhaustive. Our study’s reliance on qualitative data and subjective perspectives introduces an inherent bias, and the small number of AI experts consulted may not fully represent the field. For example, our interviews did not explicitly address multi-agent systems and agentic AI (Acharya, Kuppan, and Divya 2025), which only began to emerge and gain relevance for scaling GenAI infusion after our second interview series. Nevertheless, we argue that the identified MAPs are not made obsolete by technological progress. Instead, they capture fundamental augmentation logics that remain relevant as agentic AI evolves.

Finally, the timing of our first interview series, conducted during the COVID-19 pandemic, might have influenced the results, as the pandemic temporarily increased demand for support. However, according to a recent survey by McKinsey (2024), it appears that the heightened demand for customer requests has persisted despite the end of the pandemic and the use of chatbots. Although we only took into consideration the current state-of-the-art GenAI models (i.e., GPT-4) (2023–2024) and might be challenged by new technological breakthroughs (e.g., AI agents, agentic AI, and multi-agent systems) (Acharya, Kuppan, and Divya 2025; Pan et al. 2025), our results offer other researchers a basis for managing future emerging technologies.

Avenues for Future Research

Our contributed empirical foundation, comprising the MAPs and the mechanisms of service permeation, provides a basis for guiding future research on hybrid human–AI service delivery. Future research should conduct an in-depth exploration of specific problem-solution pairs and augmentation patterns, especially with a focus on assessing their practical effectiveness across different service settings. Each MAP offers a separate avenue for future research, illustrated by the exemplary research questions in Table 3. A promising area involves the analysis of prompts formulated by FSEs. Such research could comprise collecting, categorizing, and evaluating these prompts and recurring prompt patterns. This approach would deepen understanding of FSE–GenAI collaboration and contextualize the MAPs and emerging routines.

Furthermore, service permeation and the two identified mechanisms open promising avenues for future research and call for deeper empirical and theoretical exploration. First, future work should advance the theoretical understanding of service permeation itself by examining its underlying dynamics, boundary conditions, and long-term implications. This includes exploring how GenAI-driven information diffusion unfolds across the service frontstage and backstage, and how this reshapes routines, roles, and value co-creation. Second, researchers should investigate the distinct mechanisms of simultaneous and sequential service permeation. While simultaneous service permeation emphasizes real-time augmentation of FSEs through GenAI recommendations, sequential service permeation highlights iterative learning and knowledge transfer over time. Understanding when and how these mechanisms emerge and interact can offer deeper insights into human–AI hybrids. Third, we encourage exploring AI delegation systems as a conceptual extension of the sequential service permeation mechanism. This includes examining how responsibilities and tasks are distributed, escalated, or retained between GenAI systems and FSEs, how delegation impacts trust and control in service interactions, and how these arrangements configure agency (Bartelheimer et al. 2025). Fourth, further research is needed on the customer-facing implications of permeation, particularly how GenAI-generated language, decisions, and emotional cues permeate frontstage interactions and influence customer perceptions. Finally, future studies should analyze how service design and governance structures can adapt to facilitate the compliant and valuable permeation of services, ensuring the responsible deployment of GenAI while enabling continuous learning and human oversight throughout the service system.

In sum, our study provides a process-centric foundation for understanding how GenAI augments FSEs’ service routines, offering empirically grounded patterns and mechanisms that future research can build upon.