LANGUAGE LEARNING AND LANGUAGE PROCESSING UNDER CONDITIONS OF IMMERSION

Early research on study abroad suggested that there were clear benefits for language learners when they were immersed in the L2 (e.g., Freed, Reference Freed1995). More recently, the American Academy of Arts and Sciences published a report in 2017 on the state of language learning in the United States in which they noted that an intensive and integrated study abroad experience at the university level is sufficient to create high proficiency speakers of a foreign language, even for those who may have entered the university with little preparation and whose proficiency prior to the study abroad experience was quite low (for the statistical report from the Commission on Language Learning, see Commission on Language Learning, 2017). What happens when young adults are immersed in an L2 context? The assumption has generally been that language immersion is effective by virtue of increasing the frequency and intensity of exposure to the L2.

Although the frequency of L2 input and exposure is an important factor, there are many other factors that are likely to influence language learning under conditions of immersion, including social and cultural aspects of immersion and motivation to learn the language. The factor that has been the focus of much of the recent psycholinguistic research is the role of the L1. In some immersion contexts, it is difficult or impossible for learners to use their native language. But even in those contexts in which they can continue using the L1, it is reduced relative to the home environment. Here we consider the consequences of losing access to the native language when immersed in the L2.

IMMERSION EFFECTS DURING THE PROCESSING OF CODE-SWITCHED LANGUAGE

Since the first psycholinguistic experiments investigating bilingual language switching were conducted by Kolers (Reference Kolers1966) and by Macnamara and colleagues in subsequent years (Macnamara, Reference Macnamara1967; Macnamara & Kushnir, Reference Macnamara and Kushnir1971; Macnamara, Krauthammer, & Bolgar, Reference Macnamara, Krauthammer and Bolgar1968), research on bilingual code-switching has received increased attention, especially in recent years (Balukas & Koops, Reference Balukas and Koops2015; Deuchar, Muysken, & Wang, Reference Deuchar, Muysken and Wang2007; Deuchar & Stammers, Reference Deuchar and Stammers2012; Fricke & Kootstra, Reference Fricke and Kootstra2016; Green & Abutalebi, Reference Green and Abutalebi2013; Gullifer, Kroll, & Dussias, Reference Gullifer, Kroll and Dussias2013; Kootstra & Muysken, Reference Kootstra and Muysken2017; Kootstra, Van Hell, & Dijkstra, Reference Kootstra, Van Hell and Dijkstra2010; Muysken, Reference Muysken2000; Myslín & Levy, Reference Myslín and Levy2015; Torres Cacoullos & Travis, Reference Torres Cacoullos and Travis2018). Code-switching, usually defined as a linguistic behavior in which bilingual speakers alternate between their languages—often several times within a single sentence—is common in many bilingual communities. Bilinguals code-switch when speaking to other bilinguals, but also when they write to one another in informal contexts. The following email illustrates this (Spanish in bold, translation in square brackets; sender's name has been replaced with XXXX to ensure anonymity):

Thursday, February 1, 2018, at 11:00:00 [XXXX]wrote:

The fact that bilinguals code-switch in written discourse, where language planning demands are more easily mitigated relative to spoken language production, does not support the popular view that code-switching is triggered by a break in the fluency of speech (e.g., lexical gaps); rather it suggests that during language planning, bilinguals code-switch to better convey meaning or pragmatic intention (Myers-Scotton, Reference Myers-Scotton1993), and that code-switching, like other forms of speech, reflects “production behavior [that] is shaped by learned implicit strategies that maximize fluency” (for a discussion in monolingual contexts, see MacDonald, Reference MacDonald2013, p. 3).

The bulk of research on code-switching has come from sociolinguistic and formal perspectives, and it has investigated the social contexts and structural constraints that guide the production of code-switched speech. More recently, psycholinguists and cognitive psychologists have employed time-sensitive measures of language processing—such as eye-tracking and electrophysiological methods—and brain imaging techniques to study the comprehension of code-switches on the fly (e.g., Beatty-Martínez & Dussias, Reference Beatty-Martínez and Dussias2017; Fricke, Kroll, & Dussias, Reference Fricke, Kroll and Dussias2016; Guzzardo Tamargo, Valdés Kroff, & Dussias, Reference Guzzardo Tamargo, Valdés Kroff and Dussias2016; Johns, Valdés Kroff, & Dussias, in press; Litcofsky & Van Hell, Reference Litcofsky and Van Hell2017; Moreno, Federmeier, & Kutas, Reference Moreno, Federmeier and Kutas2002; Valdés Kroff, Dussias, Gerfen, Perrotti, & Bajo, Reference Valdés Kroff, Dussias, Gerfen, Perrotti and Bajo2017; Wicha, Moreno, & Kutas, Reference Wicha, Moreno and Kutas2004). One goal of this work is to uncover the underlying cognitive and linguistic mechanisms that regulate code-switching. Although originally considered a sign of linguistic incompetence and mental laziness (for a discussion, see Heredia & Altarriba, Reference Heredia and Altarriba2001), linguists have long noted that code-switching is not haphazard and requires a great deal of proficiency and cognitive control in the two languages (e.g., Kroll et al., Reference Kroll, Dussias, Bice and Perrotti2015; Lipski, Reference Lipski and Paradis1978; Pfaff, Reference Pfaff1979; Poplack, Reference Poplack1980, Reference Poplack and Wright2015; Timm, Reference Timm1975; Torres Cacoullos & Travis, Reference Torres Cacoullos and Travis2018).

As we might expect, just as monolingual speakers sometimes exhibit processing costs during online language comprehension (e.g., Frazier, Reference Frazier and Coltheart1987; Gennari & MacDonald, Reference Gennari and MacDonald2009; Reali & Christiansen, Reference Reali and Christiansen2007; Traxler, Morris, & Seely, Reference Traxler, Morris and Seely2002), bilingual speakers have shown costs when processing code-switched sentences (for a review, see Van Hell, Litcofsky, & Ting, Reference Van Hell, Litcofsky, Ting and Schwieter2015). Recent studies have also shown that these costs are reduced when bilinguals are immersed in code-switching environments (e.g., Beatty-Martínez & Dussias, Reference Beatty-Martínez and Dussias2017; Fricke et al., Reference Fricke, Kroll and Dussias2016; Guzzardo Tamargo et al., Reference Guzzardo Tamargo, Valdés Kroff and Dussias2016). For example, Beatty-Martínez and Dussias (Reference Beatty-Martínez and Dussias2017) examined whether bilinguals’ electrophysiological responses to a well-documented grammatical gender asymmetry in Spanish-English mixed-noun phrases (Otheguy & Lapidus, Reference Otheguy, Lapidus, Núñez-Cedeño and Cameron2003; Valdés Kroff, Reference Valdés Kroff, Guzzardo Tamargo, Mazak and Parafita Cuoto2016) differed as a function of code-switching immersion experience.

Briefly, Spanish noun phrases are governed by the requirement that determiners and nouns must match in grammatical gender (Eddington, Reference Eddington2002). A determiner marked with feminine gender must be followed by a noun carrying feminine gender assignment, and a determiner marked with masculine gender must be followed by a similarly marked masculine noun. The asymmetry observed in Spanish-English code-switching corpora is related to a partial “violation” of this requirement. Code-switches headed by the Spanish feminine article la (English “the”) are typically followed by an English noun whose Spanish translation equivalent is also feminine (e.g., la blender/licuadora_FEMm but not *la shoe/zapato_MAS). This is what we might expect if participants were employing a “gender congruency” strategy when producing mixed-noun phrases. The violation comes when the determiner is marked with masculine gender. In these cases, the Spanish masculine determiner el (also “the”) surfaces with English nouns whose Spanish translation equivalents are masculine (el shoe/zapato_MAS) or feminine (el blender/licuadora_FEM). In Beatty-Martínez and Dussias (Reference Beatty-Martínez and Dussias2017), participants who were Spanish-English bilinguals immersed or not in a code-switching environment, read short vignettes containing gender-congruent determiner-noun switches (el shoe/zapato_MAS; la blender/licuadora_FEM) and gender incongruent ones (*la shoe/zapato_MAS; el blender/licuadora_FEM). Code-switchers demonstrated labored processing only with gender incongruent targets such as “la shoe.” Critically, non-code-switchers processed the two types of incongruent code-switches with similar difficulty. This suggests that the bilinguals immersed in a code-switching environment were highly sensitive to the variation in their language experience and demonstrates that switching costs are modulated by the experience with the input in the environment (for results with code-switches involving the verb phrase, see Guzzardo Tamargo et al., Reference Guzzardo Tamargo, Valdés Kroff and Dussias2016).

Similar findings are reported in a recent study by Adamou and Shen (in press), who used a picture-sentence matching task to test whether switching costs were modulated by frequent exposure to specific code-switched constructions. Stimuli included ecologically valid code-switches constructed to mirror the types of switches found in natural conversations in the participants’ speech community. Processing of these switches was compared to that of switches with lesser degrees of ecological validity. The central finding was that switched trials that were based on the participants’ code-switching experience (in the form of the more ecological valid ones) were just as fast to process as unilingual trials.

A more striking effect of immersion in the context of code-switching was reported in Valdés Kroff et al. (Reference Valdés Kroff, Dussias, Gerfen, Perrotti and Bajo2017). They asked whether L1 Spanish–L2 English bilinguals used grammatical gender information encoded in Spanish articles to anticipate the gender of upcoming nouns, while processing speech entirely in Spanish—the bilinguals’ dominant language. Past work has demonstrated that monolingual speakers of Spanish exploit gender information present in determiners such as el and la to anticipate the gender of an ensuing noun (e.g., Lew-Williams & Fernald, Reference Lew-Williams and Fernald2007). Given the gender asymmetry effect in mixed-noun phrases, one question is whether being immersed in a code-switching environment will impact the bilinguals’ ability to use grammatical gender anticipatorily. To investigate this, Valdés Kroff et al. recorded the eye movements of Spanish-English bilinguals who lived in a community where code-switching was part of the linguistic repertoire, while participants listened to code-switched sentences (e.g., Hay un niño que está mirando el candy/There is a boy looking at the candy_MASC) in the presence of a two-pictured object scene. In the critical condition, the lexical gender of the two objects was different—a picture of a blender (licuadora_FEM) and a picture of a shoe (zapato_MAS). The interesting result was that code-switchers showed an anticipatory effect, but only in trials with a feminine determiner. When the determiner was masculine, participants did not launch anticipatory looks, but rather waited to hear the target noun. This suggests that the bilinguals did not use masculine articles as cues for anticipatory processing—a result congenial with an immersion-based view in which the extensive use of el as a “default” article in code-switching led the bilinguals to a “wait-and-see” strategy.

One important question concerns the mechanisms that may be responsible for the key role that immersion experience plays in the processing of code-switches. Psycholinguistic studies examining monolingual linguistic behavior have shown that comprehension and production involve many of the same representations and processes (Treiman, Clifton, Meyer, & Wurm Reference Treiman, Clifton, Meyer, Wurm, Healy and Proctor2003). In comprehension, listeners map the signal onto lexical entries whose semantic and syntactic information becomes available for constructing the syntactic structure and meaning of utterances. Similarly, in production, speakers select lexical items, each carrying syntactic and morphological features affecting the selection of additional words (Treiman et al., Reference Treiman, Clifton, Meyer, Wurm, Healy and Proctor2003). Given this, studies have investigated how comprehension and linguistic experience interact. One model that argues for the existence of a close correspondence between comprehension and production patterns in the environment is the production-distribution-comprehension (PDC) framework (MacDonald, Reference MacDonald2013; MacDonald & Thornton, Reference MacDonald and Thornton2009). The premise of the model is that effects observed during comprehension derive from particular distributional patterns in production, which in turn create distributional regularities that shape comprehenders’ expectations. For instance, it has been well documented in the psycholinguistic literature that when English speakers read the sentence “Mary said that John left yesterday,” they typically interpret it to mean that the leaving event took place yesterday, even though the adverb could plausibly refer to the saying event. According to the PDC, this is not because of hardwired constraints on the comprehension system (e.g., expressions like “yesterday” initially modify the verb that is nearest). Instead, the preferences observed during comprehension are learned from patterns in the input that arise from constraints on production. The PDC framework grants a major role to frequency: Frequent constructions are more readily activated by appropriate information sources than less common constructions. For example, studies show that comprehension difficulty is influenced by the match between syntactic structure and the frequency with which verbs appear in that structure. Thus, transitive verbs (e.g., believe) most often used by speakers with sentential complements cause less comprehension difficulty when followed by a sentential complement than by a noun phrase complement (Garnsey, Pearlmutter, Myers, & Lotocky Reference Garnsey, Pearlmutter, Myers and Lotocky1997; Spivey-Knowlton & Sedivy Reference Spivey-Knowlton and Sedivy1995; Trueswell & Kim Reference Trueswell and Kim1998). Based on this evidence, we would expect exposure to code-switched constructions to modulate comprehension, and this is precisely what the evidence discussed here shows.

Together, the results in this section suggest that the comprehension system becomes optimally attuned to variation in the input and provide evidence that bilinguals are highly sensitive to the constraints of their linguistic experience. Particularly regarding code-switching, the findings demonstrate how the processing of code-switched language largely depends on the type of code-switches available in the participants’ discourse environment.

TRANSLATION AND INTERPRETATION

Translation and language interpretation is an extremely demanding instance of the multilingual context.Footnote ³ The role of expertise in translation has been explored in relation to the linguistic and cognitive processes involved in translation and interpreting tasks (Christoffels & De Groot, Reference Christoffels, De Groot, Kroll and Groot2005; Christoffels, De Groot, & Kroll, Reference Christoffels, De Groot and Kroll2006; Ibáñez, Macizo, & Bajo, Reference Ibáñez, Macizo and Bajo2010; Macizo & Bajo, Reference Macizo and Bajo2006). Translators are a special type of multilingual individual not only because they usually master three or more languages at a very proficient level but also because language use of each of these languages differ from that of other type of bilinguals. When translators perform translation tasks, they have to comprehend and reformulate a given message expressed in one language into another language. Despite differences among the existing varieties of translation tasks, the main characteristic of the translation performance is that while translators have to understand and reformulate a message from one language to another, they must also maintain the two relevant languages actively and switch continually between them, while avoiding interference. The evidence suggests that translators activate the two relevant languages during online comprehension for later translation. Even when they are consecutively comprehending in one language and translating into another (Christoffels, Ganushchak, & Koester, Reference Christoffels, Ganushchak and Koester2013; Macizo & Bajo, Reference Macizo and Bajo2006, Ruiz, Paredes, Macizo, & Bajo, Reference Ruiz, Paredes, Macizo and Bajo2008), they access lexical and syntactic translation equivalents from the start of the translation process when they are still comprehending the presented sentences. For example, Macizo and Bajo (Reference Macizo and Bajo2006, Experiment 2) asked professional translators to perform interpretation of the utterances presented visually (they had to read sentences in Spanish and translate them into English). The cognate status of keywords was manipulated to assess if the participants had access lexical/semantic forms to the target language (TL) before they completed comprehension of the source language (SL). Reading times for cognate words in Spanish were faster than reading times for control words. Moreover, this cognate facilitation effect solely occurred when professionals read for translation; no effect was found when they were asked to perform the reading for repetition task, suggesting that lexical processing varies as a function of the linguistic task. Similarly, Ruiz et al. (Reference Ruiz, Paredes, Macizo and Bajo2008, Experiment 1) provided further evidence for this flexible use of language by manipulating the frequency of the translation equivalents or the SL/TL congruency of the preferred word orders for sentences that had to be translated. This pattern suggests that translation involves simultaneous processing at many levels, given that not only comprehension and production are performed simultaneously in two different parallel languages, but also TL language activation and search for translation equivalents occur while comprehension is taking place. Despite simultaneity, translators need to be able to keep their two languages separated and monitor their input and output mechanisms in a way that allows them to input the SL and to output the TL without interference (Grosjean, Reference Grosjean1997).

Results obtained by Ibáñez et al. (Reference Ibáñez, Macizo and Bajo2010) suggest that bilinguals may differ in the way they negotiate their two (or more) languages. In their study, Ibáñez et al. asked professional translators and untrained bilinguals to read and understand sentences presented word by word, and then repeat them in the language of presentation (Spanish: L1 or English: L2) once they had finished reading them. To explore the nonselective activation of both languages, they introduced cognate words (e.g., zebra/cebra, in English/Spanish) in the sentences and compared their reading times to control noncognate words. The presence of cognate effects (faster reading to cognates relative to control words) was taken as an index of between-language activation (Dijkstra, Grainger, & Van Heuven, Reference Dijkstra, Grainger and Van Heuven1999; Kroll & Stewart, Reference Kroll and Stewart1994; Macizo & Bajo, Reference Macizo and Bajo2006). In addition, to explore the nature of the lexical selection mechanism, Ibáñez et al. adapted the language-switching paradigm (e.g., Costa & Santesteban, Reference Costa and Santesteban2004; Kroll & Stewart, Reference Kroll and Stewart1994; Meuter & Allport, Reference Meuter and Allport1999; Thomas & Allport, Reference Thomas and Allport2000) to a sentence-reading task. Thus, the sentences were presented in Spanish (L1) or English (L2) in an unpredictable manner. The presence of asymmetrical switching costs (switching into the dominant L1 produced larger switching costs than switching into the less dominant L2) was taken as an index of inhibitory control. This procedure also had the advantage of mimicking comprehension in bilateral translation, where translators listen and comprehend sentences uttered from two or more speakers of different languages. The results showed that translators were different from the control bilinguals in that the translated continued to be faster to process cognate words as compared to control words. Furthermore, they did not show asymmetrical language-switching costs (index of inhibition), whereas the bilingual group showed slower responses when switching for their L2 to their L1 (asymmetrical switching cost). These results suggest that translators differ from bilinguals in the way they control their languages during comprehension so that they kept them both active (cognate effects) and showed no evidence of inhibition. The results of the present study suggest that translators do not use inhibitory processes to control for the concurrent activation of their two languages. The fact that the translator presented cognate effects during reading suggests that inhibition was not used to control their languages. To further provide support for this observation, Martín (Reference Martín2010) used the negative priming with interlingual homographs procedure with professional translators. In this task, pairs of English words were presented to bilinguals immersed in their L1 or L2, and they had to decide whether or not they were semantically related. The word pairs were presented in English (the participants’ L2). The task was carried out in blocks of two trials. In the first trial, pairs of unrelated English words were presented, so the participants’ correct response was “no.” In the critical condition, an interlingual homograph (e.g., pie, meaning “foot” in Spanish) was presented along with another word that was unrelated to the English meaning of the homograph but related to the Spanish meaning (e.g., pie-toe). When a pair like pie-toe was presented, participants had to respond “no,” because both words are unrelated in English. This condition was compared to a control condition in which a matched nonhomograph word along with an unrelated English word was presented (e.g., log-toe). This first trial aimed to capture L1 activation during L2 processing, given that activation of the irrelevant homograph meaning would make participants to take longer to respond in the homograph-unrelated condition than in the control-unrelated condition. The second trial aimed to capture the inhibition needed to overcome interference. Thus, in this trial, pairs of English-related words were presented, so that the participants’ correct response was “yes.” In the critical condition, the English translation of the non-target homograph meaning (e.g., foot) was presented along with a related word (e.g., hand). This condition was compared to a control-related condition in which a matched related word was presented along with an English word (e.g., finger-hand). Longer response times in the translation-related condition as compared to the control-related condition when preceded by the homograph-unrelated condition (e.g., foot-hand preceded by pie-toe) indicated that the L1 irrelevant homograph meaning was inhibited in the first trial. The Spanish-English bilinguals were slower in responding to homograph trials than to control trials, indicating that they experienced interference because of the activation of the non-target L1 homograph meaning. Furthermore, after responding to homographs, these bilinguals slowed their responses when the irrelevant homograph meaning became relevant in the second trial (see also Macizo, Bajo, & Martín, Reference Macizo, Bajo and Martín2010). Consistent with data presented by Ibáñez et al. (Reference Ibáñez, Macizo and Bajo2010), the translators showed evidence of language co-activation, because they were slower when interlingual homographs were presented during the first trial; however, and differently from bilingual controls, they did not show slower responses when the translation of the irrelevant meaning was presented in the second trial after presentation of the homograph in the first trial, suggesting that translators do not rely on inhibition, but rather use other mechanisms that allow them to maintain two active languages (for a similar pattern with an n − 2 repetition switching task, see Babcock & Vallesi, Reference Babcock and Vallesi2015).

The question is, then, how do professional translators control their languages? Because interpreters must comprehend the SL while producing and monitoring their output in the TL, they seem not to rely mainly on inhibition as a way of managing their two languages, and therefore another cognitive mechanism might also be involved. Results looking at the cognitive abilities of professional translators seem to suggest that language control in translators, similar to other bilinguals, requires the right balance between proactive and reactive control, but with a clear bias toward proactive processes and mechanisms such as monitoring, updating, dual tasking, or working memory. The idea is that proactive control processes (Braver, Reference Braver2012; Morales et al., Reference Morales, Gómez-Ariza and Bajo2013, Morales, Yudes, Gómez-Ariza, & Bajo, Reference Morales, Yudes, Gómez-Ariza and Bajo2015) may help translators to reduce interference before it occurs. Proactive control means that goal representations are triggered in preparation for the task and maintained during periods in which they are required. From this view, translators may be continuously monitoring intra- and extra-language cues to select the appropriate language for comprehension and production (for discussion of this view for very balanced bilinguals, see Costa, La Heij, & Navarrete, Reference Costa, La Heij and Navarrete2006; Costa, Santesteban, & Ivanova, Reference Costa, Santesteban and Ivanova2006).

Thus recent studies comparing professional translators to other bilinguals and monolingual participants in tasks, such as Stroop or Simon, that index inhibition showed that the interpreters were not better than the students and controls in avoiding interference (Köpke & Nespoulous, Reference Köpke and Nespoulous2006, Yudes, Macizo, & Bajo, Reference Yudes, Macizo and Bajo2012). However, they showed better performance in working memory tasks (Christoffels et al., Reference Christoffels, De Groot and Kroll2006; McNamara & Conway, Reference McNamara and Conway2015; Morales, Padilla, Gómez-Ariza, Bajo, Reference Morales, Padilla, Gómez-Ariza and Bajo2015; Padilla, Bajo, & Macizo, Reference Padilla, Bajo and Macizo2005; Signorelli, Haarmann & Obler, Reference Signorelli, Haarmann and Obler2011; Stavrakaki, Megari, Kosmidis, Apostolidou, & Takou, Reference Stavrakaki, Megari, Kosmidis, Apostolidou and Takou2012), fewer monitoring errors, and more flexible behavior in the Wisconsin Card Sorting Task (Yudes et al., Reference Yudes, Macizo and Bajo2012). Larger working memory and monitoring processes support proactive language control that allows faster language activation and less costly language switching during comprehension and production. Enhanced ability to actively maintaining two sets and efficiently switching between them has been further supported by two recent studies showing smaller mixing costs (mixed-task blocks versus single-task blocks) in task-switching procedures (Babcock & Vallesi, Reference Babcock and Vallesi2015, Reference Babcock and Vallesi2017). Similarly, the interpreters’ skill to perform and coordinate simultaneous tasks has been assessed by using the PRP (psychological refractory period) in single- and dual-task situations (Strobach, Becker, Schubert, & Kühn, Reference Strobach, Becker, Schubert and Kühn2015). In the dual-task condition, participants are asked to perform two different choice reaction time (RT) tasks as fast as possible. The two tasks are separated by a variable interval, and participants are instructed to give priority to the performance of Task 1. This specific PRP situation typically shows dual-task performance costs by RT in Task 2 (RT2-dual-RT) that increase with decreasing stimulus onset asynchrony (SOA; PRP effect). RTs in Task 1 (RT1) usually remains constant. Results comparing participants with and without interpreting experiences showed that RT2 and RT1 in dual tasks were faster in experienced participants, indicating that superior task coordination in the present PRP situation might be associated with the performance and coordination of multiple, simultaneous tasks during interpreting.

In sum, research on translation and language interpretation suggests that language use in this extreme bilingual situation differs from other bilingual contexts because the two languages need to be coordinated and used in a flexible manner. A recent study by Togato, Paredes, Macizo, and Bajo (Reference Togato, Paredes, Macizo and Bajo2017) comparing monolingual reading and reading for translation of syntactically ambiguous sentences (e.g., “Someone shot the servant of the actress who was on the balcony”) illustrates the highly flexible and adaptive use of language by interpreters. Although previous research has shown attachment preferences for the first (Spanish speakers) or second (English speakers) antecedent (“servant” and “actress”) for the subordinate clause (who was on the balcony) depending on the language of the speaker (Carreiras & Clifton, Reference Carreiras and Clifton1999; Gilboy, Sopena, Clifton, & Frazier, Reference Gilboy, Sopena, Clifton and Frazier1995), professional translators flexibly used the attachment strategy preferred in the output language when they performed the interpreting task (read the sentence for later translation). Hence the comprehension and production systems of the translators seem to adapt to the constraints imposed by the linguistic tasks in a goal-oriented manner. Interestingly, their cognitive skills seem to be particularly attuned to the needs of the bilingual task.