In the technology base of a firm intangible assets often refer to patents, technical skills, experience, knowledge and knowhow, involvement and attitude of employees, reputation, etc. that go well beyond formal intellectual property.

Knowledge can be defined as a fluid mix of framed experiences, values, contextual information and expert insight (Davenport and Prusak, 1998). In a knowledge-based view, competitiveness and performance of the firm depend on knowledge (Easterby-Smith et al., 2008). Knowledge assets increasingly constitute the basis of competitive advantages and creation of value for firms (Mentzas et al., 2003). Although, the literature underlines difficulties in precisely identifying knowledge in firms and measuring it, one can classify knowledge assets into four categories (cf. Table 1).

Polanyi (1967) made the distinction between “explicit” and “tacit” knowledge. Explicit knowledge can be codified and is most often legally protected and transmitted in a formal language. Information technologies enhance this feature of transmission. On the contrary, tacit knowledge is either difficult to codify or non-codifiable (Nonaka and Takeuchi 1995). At the individual level, tacit knowledge is rooted in action or a specific context of a person’s experience and its transmission requires intensive and repeated human contacts and interactions – often requiring learning-by-doing and learning-by-learning. Given its main features, tacit knowledge is then assumed to be an important component in a firm’s technology base.

In a knowledge-based view of the firm, a leakage or loss of knowledge is associated with a decrease in performance. Research dedicated to knowledge protection remains quite scant (Desouza, 2006) notably from an empirical perspective (Durst and Ferenhof, 2014). Some specific knowledge management issues (such as transfer or acquisition) have been intensively studied contrary to knowledge leakage (Parker, 2012). More particularly, few pieces of research have examined the causes or drivers of harmful knowledge transfers, such as knowledge leakage through partnerships (Jiang et al. 2013). Literature calls for more research into the potentially harmful effects of sharing and leakage in knowledge management (Foss et al., 2010).

Knowledge leakage has become a key concern in organizations as well as an important area of research, with two major main sources (Durst and Ferenhof, 2014).

The first source consists of a shortage of knowledge and capability, that is, employees who retire, leave an organization or move from one organization to another. In such situations, when people leave an organization, they take knowledge with them, especially tacit knowledge linked to their own experience, without any obvious or immediate substitute.

The second source consists of knowledge exposure, which occurs when organizations enter into strategic alliances (e.g. joint venture, outsourcing, consulting) or whenever parts of their core knowledge are transferred to others. This is the case when a firm voluntarily transfers knowledge in accordance with formal agreements (e.g. sales contracts with offset).

The literature on knowledge leakage has mainly focused on the use of boundary-spanning information and communication technologies (Ahmad et al., 2015) through social media (Colwill, 2009), publications (Jansen, 2010), emails (Caravalho et al., 2009) and portable data devices (Agudelo et al., 2016). Sensitive data, information, and knowledge can be disclosed to unauthorized parties by mistake (Norman 2001). Leakage most likely occurs in codified knowledge, because it can be more easily formalized and copied than tacit knowledge (Hurmelinna et al., 2007).

This paper enriches this literature by examining trainers’ behaviors in offset-related technology transfers, which constitute a specific form of cooperation between firms since they are contractually required. We address the question of both forms of knowledge (codified and tacit) with, however, a greater attention paid to the tacit dimension of knowledge.

Technology transfers are a category of offsets (Ianakiev, 2014, p. 252). A direct offset can be defined as an offset transaction directly related to the exported product (or service). An indirect offset is an unrelated transaction. Figure 1 shows that technology transfers are a hybrid category.

In this article, we define technology transfers as the process through which a technology developed by a firm in country A is transferred to another firm in country B. Thus, technology transfers can be seen as “goods” – or intangible assets – sold along with complex systems such as transportation (trains, aircraft, etc.), energy (power plants, etc.) or defense systems (fighter aircraft, frigates, submarines, etc. (cf. Table 2)).

The study deals with sovereign technology transfers from French firms, with a focus on emerging countries. For the sake of a simple illustration, here are a few examples of such technology transfers:

Technology transfers are now well-established practices in international trade. Historically, such transfers took the form of “turnkey’ equipment solutions”. Practices in technology transfers have progressively been evolving to deliver a system with the embedded technology.

Today, importing countries increasingly look for autonomy regarding technology and systems engineering. Consequently, technology transfers imply a more qualitative content. Furthermore, in sovereign technologies, such transfers often take place in a politically sensitive context since products usually contribute to national security. In the international defense market, successful sales are increasingly linked to fulfilling offset requirements that have steadily increased since the 1970s (Brauer and Dunne, 2004).

If technology transfers are likely to bring some advantages to firms such as improving innovation capabilities, increasing the pace of innovation, strengthening their competitive advantages, leveraging the local defense technological and industrial base, they also have a “dark side”: knowledge leakage (Frishammar et al., 2015). Such a leakage may be responsible for an increasing proliferation of technology and a loss of competitive and strategic edge for the exporting country and firms involved.

This questioning is of particular importance in relation to critical technologies which have an impact on strategic industries or the military superiority of the exporting country. Therefore, technology transfers in sovereign technologies are at the core of a complex nexus between industrial and national issues (cf. Table 3).

From the firm’s perspective, accepting such transfers can open the way to new industrial development, larger economies of scale and improved learning effects, and creates opportunities to find new suppliers and industrial partners. For example, through the sale of F15 fighter aircraft to Switzerland, Northrop and General Electric built industrial partnerships with Swiss firms. If involved in the industrial and technological experiments of the importing country, the selling firm is able to observe new methods, skills and even knowledge developed by the purchasing firm. This practical field experience, gained without having to bear the expense, is all the more interesting in the case of high sunk costs (e.g. submarines, nuclear power plants, etc.).

However, since technology transfers are not the core business of firms, organizing such activities brings additional direct costs (e.g. translation of technical documents, training employees as trainers, building dedicated facilities). Through technology transfers, the selling firm is likely to lose control over critical intangible assets. They open the door to knowledge leakages, i.e. “the extent to which the focal firm’s private knowledge is intentionally appropriated by or unintentionally transferred to partners” (Jiang et al., 2013, p. 984). As the firm’s proprietary technology could be disseminated (Lau et al., 2010, p. 966), its non-price competitiveness and innovation capacities can be affected. Even worse, because of their “absorption capabilities” (Cohen and Levinthal, 1990) newcomers can eventually become true competitors for the selling firm. As a result, knowledge transfers must remain under control to avoid involuntary knowledge leakages and limit the loss of intangible assets. Knowledge leakage is difficult to assess – and even harder to control – because it can be unconscious, uncontrolled, and beneficial to only one party (Frishammar et al., 2015).

In technology transfers, three types of “vehicles” can be identified: technical assistance, documentation, and training. Technical assistance, covering several kinds of services, often includes maintenance, repair and overhaul operations. Technical documentation refers to blueprints, user guides and their translation. Training includes different forms from basic training of end-users and maintenance operators up to scientific and technological training for engineers to give them the ability to design the whole system. The issue is no longer to train workers to assemble a product with detailed handbooks, but to train engineers in R&D to enable them to modify, retrofit, improve or even design the whole system.

This brings new issues for firms that need to modify and sometimes redefine the knowledge they could sell. New organizational issues arise such as defining the contents of training programs or setting up pedagogic means and training tools. In technology transfers today, a large part of the process consists in organizing training programs that guarantee the effectiveness of technology transfers.

First, these programs involve many different kinds of expertise from specialized workers to engineers highly-qualified in the design of systems and management because customers want to understand and appropriate the whole industrial process. In such complex systems, the global management of design often matters for customers. For example, boats or submarines can be built using two methods: a systemic vision (e.g. hull, engine, weapon system, etc.) or a section-based design where the product is simply “sliced” into sections. Both methods have advantages and disadvantages, and customers often try to obtain access to the information about this choice.

Second, training programs involve specific time and spatial constraints. Technology transfers require long-term organization and often involve geographical constraints related to the distance between the selling firm (or country) and the receiving firm. For example, France sells submarines with a 30-year contract, to Brazil and Australia, that involves many exchanges between countries and firms separated by thousands of kilometers.

Third, training programs imply a wide range of training and educational tools with a mix of theoretical and empirical knowledge and in-situ learning-by-doing. Basically, three main training channels exist (Table 4): lectures, practical work and learning-by-doing. One can also add a very different channel called here “interstitial periods”, which refers to the time that trainers spend with customers outside working hours.

Training involves the transmission of both the explicit and implicit knowledge that is necessary to master technology. Explicit knowledge can be transmitted by an ad hoc medium such as technical documentation. On the contrary, tacit knowledge requires intensive and repeated contacts between trainers and trainees. Depending on the knowledge transmitted, a “degree of tacitness” can be associated. It also brings new problems because it is hard or even impossible to measure to what extent the technology has been both transferred and absorbed. Since they want to access tacit knowledge, customers tend to increasingly ask for learning-by-doing training, often as a contractual requirement. In addition, firms easily use learning-by-doing training because it is easy and cheaper to organize: it requires no specific infrastructure, no specific course and content, and no specific skills.

The complex systems we study are often based on industrial capabilities in which critical knowledge is tacit due to limited production and advanced technologies. Indeed, it is assumed that the performance of these systems is often related to precise actions and specific technical elements of industrial process (e.g. a specific way to weld two elements), a knowledge accumulated during years and even decades. Tacit knowledge is embodied in the habits and routines of employees. Sometimes people are not aware of the importance of such tacit knowledge and can transmit it without being aware of the related risks or even that they are passing it on. Tacit knowledge is thus difficult to control and manage (Cowan et al., 2000).

In technology transfers, training is also a source of knowledge leakages. Our contribution to the study of the micro-sources of leakage is through focusing on trainers’ behavior. Tacit knowledge is at the core of relations between the transferring firm and the receiving firm. One can thus identify a dilemma: the transferring firm aims to protect and control what is transferred whereas the receiving firm’s goal is to capture as much knowledge as possible to enhance its competencies. The identification of the underlying risks of leakage associated with this dilemma is likely to have an effect on the behavior of the people in charge of training during technology transfers.

Trainers can be responsible for leakages through their spontaneous behavior and personal interpretation of context and situations. For example, such an interpretation matters when trainers arbitrarily consider whether or not to provide knowhow. In spite of the firm’s guidelines on what to transmit, they could take the initiative to protect that knowledge if they consider it to be a national and strategic heritage that must be protected. As such it is important to investigate how trainers actually deal with this dilemma and to what extent the firm is aware, and thus able to control what is really provided through the training process and thereby pinpoint knowledge leakages.

Empirical material comes from a selected panel of 6 strategic French firms operating in different sovereign industries: shipbuilding, electronics, energy, transport and aeronautics. Due to the sensitiveness of related information, it is not possible to disclose individual data but they share distinctive features. They are all considered as “great national champions”, created and managed by the French state before being privatized. Focusing for ages essentially on the state’s needs, they are not really accustomed to dealing with foreign customers, which have become more important as they can no longer rely on the domestic market.

Semi-structured interviews were conducted over two years (2013 and 2014). They lasted between 60 and 90 minutes, and they were structured around five major questions: Can you describe and explain your activities within the firm? Can you describe your initial training and professional career? How would you define a technology transfer? What is your experience in technology transfer programs? And, according to you, what are the main difficulties, risks and challenges in technology transfers? Interviews are considered as a means to link the professional practice of interviewees to their representations of the profession, values, interests and any symbolic dimensions. So, it is interesting to ask interviewees with various profiles (e.g. workers, heads, engineers…) to see whether differences of opinion and interpretation emerge.

We used interviews to assess the referential framework of each actor: main purposes, intentions and knowledge involved in training activities. 24 representative interviews presented in Table 5 were completely transcribed in a verbatim (from a total panel of 60 initial interviews).

We conducted a lexicometric analysis using the Alceste method[1] (Reinert, 1990). Our data were implemented in IramuteQ with the free R software[2] The data were coded with two variables for each interview, one as a proxy of the age of the interviewees (three different “ages” have been coded: beginner, expert, senior) and another for six socio-professional level. The exploratory analysis consisted in cross-checking the content of actors’ observations and their positions on topics according to their profiles to define different classes of discourses. Some qualitative information collected during interviews completed the lexicometric approach, especially when it came to defining and naming the different classes.

Class 1 includes terms referring to business environment and the strategic management of the firm. For example, it is mostly based on terms such as technology, manufacture, produce, develop or transfer. Practical and local problems that trainers could experience are not considered.

In addition, Class 1 discourse is composed of terms referring to a global and competitive business environment. This vocabulary can be associated with the global strategy developed by CEOs, program directors and executive committee members, main top-level managers of technology transfers in a contractual perspective. No reference to training as a professional practice is mentioned even if these people are sometimes part of training plans, especially initial presentations to customers.

Class 1 discourses mostly belong to senior executive officers (1) and top managers (2) who give main industrial and strategic orientations. These interviewees are sensitive to the political dimension of sovereign technology exports because they are in strong interaction with political decision-makers. Very few of them question technology transfers that are simply part of the evolution of industrial practices. “Our industries will die if they do not export. We prefer to transfer knowledge rather than having a million unemployed people in our country.” (a member of an executive committee).

They do not seem to identify any risk of knowledge leakage since technology transfers are codified and bounded in the contract. They tend to consider that, at their respective level, each dimension of the contract has been supervised and validated. They trust the effectiveness of the firm’s organization to protect its own interests. “There are no big risks in technology transfers. Everything is very well legally regulated. I always have in mind the example of Coca Cola with their over-protected recipe although everybody drinks Coca Cola all over the world” (a project manager). According to them, the main source of risk arises when engineers – or sometimes technicians – passionately teach about their domain of expertise, with too many details and explanations. “The only danger is that our technical experts leak a little too much information when they give a course. They have very high technical skills and are deeply involved in their technical field” (a member of an executive committee).

According to them, the only dilemma is related to the level of knowledge to be transferred as defined during the negotiation of contract. Such a level must be the lowest possible, but high enough to help win the contract and satisfy customer’s requirements. Their purpose is to implement contractual commitments and to satisfy customers, because fulfillment results in payment. Otherwise, customers may complain to the authorities of the importing country, which may eventually impact firm’s executives. In extreme cases, a loss of confidence can result in suspending or even canceling the contract.

Class 2 comprises words belonging to the lexicon of education and training (e.g. question, answer, classroom, module, lecture, presentation, etc.). These terms refer to “classroom environment” and come from engineers focusing on a training situation with students, often top experts in their domain. Our results show a great heterogeneity in terms of age (from 30 to 50) and professional experience (not only in technical fields).

Class 2 people are not involved in managing technology transfer projects. They have in-house trainer profiles or deliver courses outside the firm thanks to regular links with local universities or schools. They usually become involved in technology transfer projects only to provide few hours of training: from two days to several dozen days, depending on topics and the number of available engineers. Some of them do not willfully implement training but are required to do so because of their expertise.

Engineers express the greater diversity in terms of attitude and representation regarding technology transfers. They have several questions regarding their training activity: about the firm’s responsibility and reputation, the high or low price paid by the customer, their personal involvement, the risk that the customer becomes a competitor, and the lack of recognition for their commitment to training activities. “We have the duty to be honest because the customer spends a lot of money on training and it is then necessary to provide a good quality service [...] It’s a state-to-state agreement, we knew we were a little freer in this case.” (an engineer, head of a technical domain).

In fact, many Class 2 interviewees consider that training activity goes too far regarding the transmission of technical contents and assume a risk of knowledge leakages. Contrary to other trainers, they are totally aware of the motives and consequences of their actions. “If the system fails with human losses, I will feel responsible. I won’t be able to live with that in mind. So when it comes to technical stuff, I don’t fool around when it deals with security issues. I do everything I need to make it work. If it is necessary, I transmit more information than what was initially requested” (an engineer).

They feel a strong ambiguity between giving too much knowledge to the customer and not giving enough knowledge with regard to contractual commitments. Consequently, they tend to modify the content of training towards more (or less) transmitted knowledge.

Class 3 comprises terms referring to both the origin of clients (e.g. India, Brazil, China, Korea, etc.) and technologies or systems that are manufactured by firms (e.g. boat, system, aircraft, etc.). It also comprises other terms referring more to the concrete organization of training activities in the industrial field (e.g. program, work, manager, architect).

Class 3 discourse refers to a kind of middle manager position between the trainers in the field and top executives of the firm.

Engineers belonging to Class 3 have to organize training. According to them, training is a kind of product that needs to be managed and delivered following an industrial mode of production to meet customers’ requirements, i.e. training schedules and control of trainees’ knowledge, in due time. They simply adapt industrial organization to a new product: training.

In a middle manager’s tasks, training is intimately associated with the manufacturing agenda, thus requiring some fine-tuning: training must be delivered but it cannot slow down ongoing production. For example, if a middle manager needs an engine to train customers, any delay in the engine delivery will upset the production agenda. As a result, middle managers often have to quickly set up practical exercises because trainees are paying for training and cannot wait. “It should be noted that if one of the 3 items (training, construction, documentation) does not pass the milestone, it will block the payment key of the complete training package with some additional financial penalties. We are in a state of emergency and permanent reorganization in order to satisfy the customer.” (a middle manager). Middle managers thus face a stressful and permanent tension between the industrial schedule and training contents interfering with such a timetable. Transferring knowledge is their main objective and there is no personal questioning regarding risk of leakage when knowledge is transferred.

Class 4 and Class 5 both comprise the discourse of people who consider that training is not one of their professional tasks. In their discourses, there is no clear border as to what is and what is not training. They mainly speak about their job and imposed constraints when customers are in the workshop. They do not seem to be aware of strategic issues associated with knowledge and techniques they master and teach.

Class 4 and 5 discourses are found in workers and technicians with a lexicon belonging to their daily working life with a higher representation of words such as technical, difficulty, milestone, planning, supplier deliveries, etc. In terms of social representation of technology transfers, workers and technicians are a homogeneous category. Some technicians give back-to-basics lectures, which is not the case for workers who mainly implement learning-by-doing training.

Two subcategories can be defined. For some people, training is perceived as an imposed activity, which is clearly not rewarded (with advancement or bonuses, for example). As a result, training is often considered as a waste of time. “As a worker, I was impressed at first. When they were introduced at the beginning of the session, I saw a dozen specialized engineers [...] I told myself that I was not sure to have something to teach them. But fortunately, they did not want a complete course in my technical field, they only wanted to see how I concretely did my job and to understand my own way of operating.” (a skilled worker).

For others, training is desired. Workers and technicians voluntarily commit and are really interested in teaching. In addition, they like to speak English – commonly used in training related to technology transfers – and, if they have to visit receiving firms, the expatriate status is perceived as rewarding.

However, workers and technicians never questioned the strategic dimension of transferred knowledge. In their discourse, no reference to potential knowledge leakages is found. More particularly, workers do not seem to perceive such a risk or to be aware that their skills can be highly strategic. Their attitude regarding technology transfers can be qualified as “passive attitude” or “unintentional attitude”.

The management of training for technology transfers poses different problems for complex systems. Firms tend to favor “learning-by-doing” for several reasons. First, learning-by-doing is easy to set up from an organizational point of view when it is compared to other training situations (e.g. lectures). Second, it is less expensive with no opportunity costs. Third, one cannot master complex systems without learning-by-doing. Firms do not question themselves enough about the strategic importance of knowledge embodied in the people who are chosen to teach. We propose ways to help firms to better understand and mitigate the risks associated with training in technology transfers.

For complex systems, technology transfers are of utmost importance to save time and avoid failure. This is why requirements increasingly focus on in-situ training, since this represents the best solution to grab tacit knowledge that “floats in the air”. Being as close as possible to industrial ecosystems constitutes the best means to acquire effectively related skills. As a consequence, receiving firms expect to interact not only with integrators but also their industrial partners throughout the value chain to be able to replicate all industrial skills.

Complex systems involve several interlocutors mastering several subsystems and components with a key role for integrators throughout the value chain. Thus, the effectiveness of the industrial process relies on many pieces of collective knowledge. Complex systems thus lead to complex networks of knowledge, with many layers of tacit knowledge, understandable if and only if there are insertions and interactions within the related ecosystem. In such a context, the knowledge of each employee can be strategic because it helps to better understand how to design and produce a complex system. This embedded collective knowledge, found in routines and embedded knowledge, results from the process of acquiring a shared understanding (Cohendet and Llerena, 1999, p. 219). In addition to the number of participants, the transformation of tacit knowledge into codified knowledge is very difficult and also increases the risk of knowledge leakages.

Such a dimension must be integrated in the design of training programs. Knowledge is also acquired in-situ through a better understanding of observed industrial networks and informal exchanges with trainers throughout training periods. As previously underlined, barriers between trainees and trainers are likely to blur over time, favoring open discussions that can reveal a lot of knowhow and know-who. This represents a true challenge to keep technology transfers under control, even beyond the firm’s sites.

All people involved in offset-related training activities must become aware that unprepared actions or inappropriate behaviors can result in the leaking of knowledge. This is especially true in sovereign industries where secrecy has been the traditional means to control knowledge leakages. When opening up to third-party players for contractual requirements, in-house actors have not been prepared to make the right choices. Thus, our empirical research validates Ahmad et al.’s (2014, p. 29) statement: “Formal controls include risk assessments, audits, and policies and procedures that provide advice to personnel on the one hand and outline punitive measures for non-compliance on the other.”

There is no doubt that the mitigation of knowledge leakages must constitute a keystone for the selling firm’s own organization. Leakage mitigation needs to be considered as a strategic capability at top management level. Legal protection can be useful (Liebeskind, 1996), but this is neither enough nor appropriate when dealing with tacit knowledge (Jiang et al., 2013). The risks of knowledge leakages increase if the selling firm fails to define and implement measures to protect its intangible assets when cooperating with another firm. In terms of strategic management, it seems crucial to better inform CEOs and top managers that formal and administrative procedures are not sufficient to completely prevent knowledge leakages.

Contrary to a theoretical perspective, the implementation of contractual clauses is not as clear and under control as one may expect with regard to technology transfers. Indeed, stakeholders dedicate a lot of time and energy to designing the perimeter of such transfers ex ante through contractual clauses. These legal tools aim to contain risks through tough negotiations. This is a required but insufficient condition, since the people who draw up the contract are not those who are going to implement it.

Even in sovereign technologies, states and firms do not make sufficient effort in keeping implementation under control, believing too much in the strength of negotiated contracts. Our empirical research reveals the limits of such an approach as well as the excessive focus of today’s literature on contract negotiations through legal dimensions and the insufficient assessment of the ex-post phase, through which risks of knowledge leakages can appear.

This raises the question of how to interpret contractual commitments and the relevance of such commitments with regard to the effectiveness of corresponding technology transfers. It appears empirically that trainers individually redefine the content of contract through training activities in which they are involved. Trainers can provide information that is not included in contractual terms because of their personal interpretation of requirements. Containing transferred knowledge is very difficult for the firm or state because every trainer tends to adjust his mission according to his own representation of the contract as well as the strategic nature of related knowledge. This important result is shown with the different categories of trainers from Class 1 to Class 5. This redefinition process has two main origins.

First, the unintentional behavior of trainers: they are not aware of transmitting too much knowledge to customers. This is notably the case for workers and technicians or engineers involved in “training on the job” tasks. They fulfill this mission with the same professionalism as they do their daily job (Touraine, 1966). Consequently, they tend to disclose more information than expected because of exacerbated professional ethics coupled with a strong recognition of their skills by customers (facilitating reverse engineering). However, top managers tend to neglect this possibility when designing technology transfers.

Second, the voluntary behavior of trainers: some trainers may voluntarily deviate from the firm’s initial intentions and commitments by providing more knowledge than expected or, on the contrary, limiting access to the required knowledge. Some of them think that helping the customer to fully understand technology and underlying industrial process is a priority to ensure customer satisfaction. Others choose to give less knowledge even if they have to lie or to fake answers because they perceive a significant risk for the firm or the country. According to them, too much information has been sold and this can be responsible for losing a technological lead and therefore market leadership. Ultimately, they think this can lead to the firm’s bankruptcy.

These results underline that several risks result from trainers themselves, but most of the time they are truly underestimated or neglected because of the dual treatment of technology transfers between contractual negotiations and the implementation of transfers. Such duality can be considered to be a legacy of a time when technology transfers were limited to delivering patent licenses, industrial blueprints or turnkey factories. Then, leakage risks were limited due to minimal interactions between employees of delivering and receiving firms. This is no longer the case, since transfers cover a broader scope of knowledge so that receiving firms and countries are truly able to absorb and exploit related technologies.

Successful technology transfers are only possible by steadily increasing interactions between stakeholders. However, two weaknesses are apparent with the definition of transferred technologies and the ex-ante preparation of training sessions. First, tacit knowledge is much more difficult to delimit than codified knowledge. This requires that the actors involved “on the ground” understand how to define boundaries to prevent retro-engineering, which is rarely the case. Nevertheless, it is quite difficult for negotiators to truly understand what is at stake. Second, implementing riskless transfers requires real preparatory training for future trainers before implementing contractual commitments, so that they become aware of corresponding risks and possible consequences of their decisions. Therefore, trainers’ training constitutes a real imperative and not an option in the management of the firm’s intangible assets. Trainers must be knowledge gatekeepers. They can also become actors of risk mitigation by helping all in-house stakeholders to fully identify possible ex ante sources of knowledge leakages. Such training goes along with a real investment in the design of training programs and the implementation of incentives to align trainers’ behavior with the firm’s interests.

Headway can be made through developing “protective capacity.” Knowledge-retention strategies can help firms reduce the danger of knowledge leakage or loss (Andersen, 2012). To ensure a better protection of the firm’s knowledge, it is necessary to question the use of learning-by-doing situations, since they create “open access” to tacit knowledge. To mitigate risks, it should be fruitful to implement comprehensive training policies and enforce a clear segregation between internal and training activities. This can rely on off-site facilities to avoid in-situ training (online courses, serious games, etc.) or dedicated “training rooms” with a skills referential and simulated situations, an approach already used by some firms in rail or naval industries.