Using behavioral measurements and event-related potentials (ERPs), this study investigated the temporal dynamics of Chinese-Japanese bilinguals’ non-target second language (L2) activation and inhibition when they process their first language (L1) embedded with Chinese-Japanese homographs.
Design/methodology/approach:
Both Chinese-Japanese bilinguals and Chinese monolinguals were recruited to perform an orthographic judgment task on Chinese word pairs. In these pairs, priming words were either interlingual homographs or non-homographs. Target words were semantically related or unrelated to the priming words’ Chinese meanings. Crucially, Chinese-unrelated pairs with homographic primes were semantically related in Japanese.
Data and analysis:
Behavioral and ERP data were analyzed using mixed-effects models. The key focus of the analysis was on the fixed effects of semantic relatedness (related/unrelated), priming word type (homograph/non-homograph), group (bilingual/monolingual), and their interactions.
Findings/conclusions:
The results revealed a more positive P200 amplitude for semantically related word pairs relative to unrelated ones in bilinguals, indicating early activation of homographs’ L1 meanings during the early stage of processing. Comparable N400 amplitudes were observed in the bilingual group for pairs containing homographic primes, suggesting co-activation of both L1 and L2 meanings of these homographs. Subsequently, L2 meanings of homographs failed to trigger a significant LPC effect in bilinguals, implying that the L2 meaning may be inhibited at the late processing stage.
Originality:
This study provides ERP evidence that non-target L2 undergoes a dynamic process of mid-stage activation followed by late-stage inhibition during L1 processing, even across typologically distinct languages.
Significance/implications:
These findings support two key bilingual lexical access models: the Inhibitory Control (IC) model and the Bilingual Interactive Activation Plus (BIA+) model, both of which posit that late-stage L2 inhibition optimizes target language processing. By documenting temporal dissociation between L2 activation and inhibition, the study highlights adaptive cognitive control mechanisms in bilinguals, revealing how cross-language activation is managed over time to balance semantic integration and task demands.
AndoE.JaredD.NakayamaM.HinoY. (2014). Cross-script phonological priming with Japanese Kanji primes and English targets. Journal of Cognitive Psychology, 26(8), 853–870.
2.
BarneaA.BreznitzZ. (1998). Phonological and orthographic processing of Hebrew words: Electrophysiological aspects. The Journal of Genetic Psychology, 159(4), 492–504.
3.
BarrD. J.LevyR.ScheepersC.TilyH. J. (2013). Random effects structure for confirmatory hypothesis testing: Keep it maximal. Journal of Memory and Language, 68(3), 255–278.
4.
BatesD.MächlerM.BolkerB.WalkerS. (2015). Fitting Linear Mixed-Effects Models Using lme4. Journal of Statistical Software, 67(1), 1–48.
5.
BrouwerH.CrockerM. W. (2017). On the proper treatment of the N400 and P600 in language comprehension. Frontiers in Psychology, 8, Article e1327.
6.
BrouwerH.FitzH.HoeksJ. (2012). Getting real about semantic illusions: Rethinking the functional role of the P600 in language comprehension. Brain Research, 1446, 127–143.
7.
BruijnE.DijkstraT.ChwillaD. J.SchriefersH. J. (2001). Language context effects on interlingual homograph recognition: Evidence from event-related potentials and response times in semantic priming. Bilingualism: Language and Cognition, 4(2), 155–168.
8.
BybeeJ. (2010). Language, usage and cognition. Cambridge University Press.
9.
CaiQ.BrysbaertM. (2010). SUBTLEX-CH: Chinese word and character frequencies based on film subtitles. PLOS ONE, 5(6), Article e10729.
10.
DeganiT.TokowiczN. (2013). Cross-language influences: Translation status affects intraword sense relatedness. Memory and Cognition, 41(7), 1046–1064.
11.
de la Riva LópezE. M.FrancisW. S.GarcíaJ. (2012). Repetition priming within and between languages in verb generation: Evidence for shared verb concepts. Memory, 20(4), 358–373.
12.
DeloguF.BrouwerH.CrockerM. W. (2019). Event-related potentials index lexical retrieval (N400) and integration (P600) during language comprehension. Brain and Cognition, 135, e103569.
13.
DijkstraT.van HeuvenW. J. B. (2002). The architecture of the bilingual word recognition system: From identification to decision. Bilingualism: Language and Cognition, 5(3), 175–197.
14.
DijkstraT.WahlA.BuytenhuijsF.Van HalemN.Al-JibouriZ.De KorteM.RekkÉS. (2018). Multilink: A computational model for bilingual word recognition and word translation. Bilingualism: Language and Cognition, 22(04), 657–679.
15.
Elston-GuttlerK. E.GunterT. C.KotzS. A. (2005). Zooming into L2: Global language context and adjustment affect processing of interlingual homographs in sentences. Cognitive Brain Research, 25(1), 57–70.
16.
FitzpatrickI.IndefreyP. (2014). Head start for target language in bilingual listening. Brain Research, 1542, 111–130.
17.
GreenD. W. (1998). Mental control of the bilingual lexico-semantic system. Bilingualism: Language and Cognition, 1(2), 67–81.
18.
GreenD. W.AbutalebiJ. (2013). Language control in bilinguals: The adaptive control hypothesis. Journal of Cognitive Psychology, 25(5), 515–530.
19.
HoshinoN.ThierryG. (2012). Do Spanish—English bilinguals have their fingers in two pies—or is it their toes? An electrophysiological investigation of semantic access in bilinguals. Frontiers in Psychology, 3, Article 9.
20.
JacquetM.FrenchR. M. (2002). The BIA++: Extending the BIA+ to a dynamical distributed connectionist framework. Bilingualism: Language and Cognition, 5(3), 202–205.
21.
JiangS.MaL.ChenB. (2023). The role of cognitive control in bilingual language comprehension: An event-related potential study of dense code-switching sentences. Bilingualism: Language and Cognition, 1–17.
22.
KerkhofsR.DijkstraT.ChwillaD. J.de BruijnE. R. (2006). Testing a model for bilingual semantic priming with interlingual homographs: RT and N400 effects. Brain Research, 1068(1), 170–183.
23.
KhachatryanE.CamarroneF.FiasW.Van HulleM. M. (2016). ERP response unveils effect of second language manipulation on first language processing. PLOS ONE, 11(11), Article e0167194.
24.
KongL.ZhangJ. X.KangC.DuY.ZhangB.WangS. (2010). P200 and phonological processing in Chinese word recognition. Neuroscience Letters, 473(1), 37–41.
25.
KroghS. M. (2022). Danish-English bilinguals’ cognate processing in L1 and L2 visual lexical decision tasks. Languages, 7.
26.
KuznetsovaA.BrockhoffP. B.ChristensenR. H. B. (2017). lmerTest Package: Tests in Linear Mixed Effects Models. Journal of Statistical Software, 82(13), 1–26.
27.
LandiN.PerfettiC. A. (2007). An electrophysiological investigation of semantic and phonological processing in skilled and less-skilled comprehenders. Brain and Language, 102(1), 30–45.
28.
Language and Text Information Management Department of the Ministry of Education, Li, X., & Su, X. (2021). List of common words in modern Chinese. Commercial Press (in Chinese).
29.
LauE. F.GramfortA.HamalainenM. S.KuperbergG. R. (2013). Automatic semantic facilitation in anterior temporal cortex revealed through multimodal neuroimaging. Journal of Neuroscience, 33(43), 17174–17181.
30.
LeeC. Y.TsaiJ. L.ChanW. H.HsuC. H.HungD. L.TzengO. J. L. (2007). Temporal dynamics of the consistency effect in reading Chinese: An event-related potentials study. NeuroReport, 18(2), 147–151.
LiL.MoL.WangR.LuoX. (2009). Evidence for long-term cross-language repetition priming in low fluency Chinese–English bilinguals. Bilingualism: Language and Cognition, 12(1), 13–21.
33.
MartinC. D.DeringB.ThomasE. M.ThierryG. (2009). Brain potentials reveal semantic priming in both the “active” and the “non-attended” language of early bilinguals. NeuroImage, 47(1), 326–333.
34.
MehravariA. S.TannerD.WamplerE. K.ValentineG. D.OsterhoutL. (2015). Effects of grammaticality and morphological complexity on the P600 event-related potential component. PLOS ONE, 10(10), Article e0140850.
35.
MishraR. K.SinghN. (2016). The influence of second language proficiency on bilingual parallel language activation in Hindi-English bilinguals. Journal of Cognitive Psychology, 28(4), 396–411.
36.
MoonJ.JiangN. (2011). Non-selective lexical access in different-script bilinguals. Bilingualism: Language and Cognition, 15(1), 173–180.
37.
NakayamaM.SearsC. R.HinoY.LupkerS. J. (2012). Cross-script phonological priming for Japanese-English bilinguals: Evidence for integrated phonological representations. Language and Cognitive Processes, 27, 1563–1583.
38.
OppenheimG.WuY.ThierryG. (2018). Found in translation: Late bilinguals do automatically activate their native language when they are not using It. Cognitive Science, 42(5), 1700–1713.
39.
PictonT. W.BentinS.BergP.DonchinE.HillyardS. A.JohnsonR.Jr.MillerG. A.RitterW.RuchkinD. S.RuggM. D.TaylorM. J. (2000). Guidelines for using human event-related potentials to study cognition: Recording standards and publication criteria. Psychophysiology, 37, 127–152.
40.
SerenoS. C.RaynerK.PosnerM. I. (1998). Establishing a time-line of word recognition: Evidence from eye movements and event-related potentials. NeuroReport, 9(10), 2195–2200.
41.
SpiveyM. J.MarianV. (1999). Cross talk between native and second languages: Partial activation of an irrelevant lexicon. Psychological Science, 10(3), 281–284.
42.
StuelleinN.RadachR. R.JacobsA. M.HofmannM. J. (2016). No one way ticket from orthography to semantics in recognition memory: N400 and P200 effects of associations. Brain Research, 1639, 88–98.
43.
TantucciV.Di CristofaroM. (2019). Entrenchment inhibition: Constructional change and repetitive behaviour can be in competition with large-scale “recompositional” creativity. Corpus Linguistics and Linguistic Theory, 16(3), 547–579.
44.
TantucciV.Di CristofaroM. (2021). Pre-emptive interaction in language change and ontogeny: The case of [there is no NP]. Corpus Linguistics and Linguistic Theory, 17(3), 715–742.
45.
TaylorR. S.FrancisW. S. (2017). Between-language repetition priming in antonym generation: Evidence that translation-equivalent adjectives have shared conceptual representations across languages. Memory, 25(3), 344–349.
46.
ThierryG.WuY. (2004). Electrophysiological evidence for language interference in late bilinguals. NeuroReport, 15(10), 1555–1558.
47.
ThierryG.WuY. (2007). Brain potentials reveal unconscious translation during foreign-language comprehension. Proceedings of the National Academy of Sciences of the United States of America, 104(30), 12530–12535.
48.
van HellJ. G.DijkstraT. (2002). Foreign language knowledge can influence native language performance in exclusively native contexts. Psychonomic Bulletin and Review, 9(4), 780–789.
49.
van HeuvenW. J. B.DijkstraT. (2010). Language comprehension in the bilingual brain: fMRI and ERP support for psycholinguistic models. Brain Research Reviews, 64(1), 104–122.
50.
van HeuvenW. J. B.WenY. (2019). The need for a universal computational model of bilingual word recognition and word translation. Bilingualism: Language and Cognition, 22(4), 695–696.
51.
WangR.DengH.LiJ.LiL.FanM. (2011). The activation of non-attended language in language comprehension of Chinese-English bilinguals. Acta Psychologica Sinica, 43(7), 771–783 (in Chinese).
52.
WangX.HuiB.ChenS. (2020). Language selective or non-selective in bilingual lexical access? It depends on lexical tones!PLOS ONE, 15(3), Article e0230412.
53.
WangX.WangJ.MalinsJ. G. (2017). Do you hear “feather” when listening to ‘rain’? Lexical tone activation during unconscious translation: Evidence from Mandarin-English bilinguals. Cognition, 169, 15–24.
54.
WangY.JiangM.HuangY.QiuP. (2021). An ERP study on the role of phonological processing in reading two-character compound Chinese words of high and low frequency. Frontiers in Psychology, 12, Article e637238.
55.
WuY.ThierryG. (2010a). Chinese-English bilinguals reading English hear Chinese. Journal of Neuroscience, 30(22), 7646–7651.
56.
WuY.ThierryG. (2010b). Investigating bilingual processing: The neglected role of language processing contexts. Frontiers in Psychology, 1, Article e178.
57.
XunE.RaoG.XiaoX.ZangJ. (2016). The construction of the BCC Corpus in the age of Big Data. Corpus Linguistics, 3(1), 93–118 (in Chinese).
58.
YacovoneA.MoyaE.SnedekerJ. (2021). Unexpected words or unexpected languages? Two ERP effects of code-switching in naturalistic discourse. Cognition, 215, Article e104814.
59.
YangS.CaiY.XieW.JiangM. (2021). Semantic and syntactic processing during comprehension: ERP evidence from Chinese QING structure. Frontiers in Human Neuroscience, 15, Article e701923.
60.
YangS.JiangM. (2024). Second language activation in native language word recognition among Chinese Japanese learners. Foreign Language Teaching and Research, 56, 594–606 (in Chinese).
61.
YangS.JiangS.JiangM.GuoQ. (2024). Lexical pathway from L2 to L1 activation in intermediate proficient bilinguals: Behavioral and ERP evidence. Frontiers in Human Neuroscience, 18, Article e1270377.
62.
YangS.ZhangX.JiangM. (2021). Bilingual brains learn to use L2 alliterations covertly like poets: Brain ERP evidence. Frontiers in Psychology, 12, Article e691846.
63.
ZeelenbergR.PecherD. (2003). Evidence for long-term cross-language repetition priming in conceptual implicit memory tasks. Journal of Memory and Language, 49(1), 80–94.
64.
ZhangH.SuI.ChenF.NgM. L.WangL.YanN. (2019). The time course of orthographic and semantic activation in Chinese character recognition: Evidence from an ERP study. Language, Cognition and Neuroscience, 35(3), 292–309.
65.
ZhangW.ChenX.FanY.HuangJ.WangS. (2015). Semantic integration in the early time window: An ERPs study. Journal of Psychological Science, 38(2), 303–308 (in Chinese).
