Unraveling the small tie problem mystery: Size effects from finger counting to mental strategies in addition

•We discovered a particular developmental pattern for tie compared to non-tie problem solving.•It corresponds to a direct shift from finger modeling to retrieval.•This might be made possible by easily memorizable symmetrical patterns created on fingers.•In contrast, for non-tie problems, a transitio...

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Bibliographic Details
Published in:Journal of experimental child psychology 2025-04, Vol.252, p.106154, Article 106154
Main Authors: Bagnoud, Jeanne, Poletti, Céline, Krenger, Marie, Mahendrathas, Mathusanaa, Dewi, Jasinta, Thevenot, Catherine
Format: Article
Language:English
Subjects:
Addition
Finger counting
Mental arithmetic
Numerical cognition
Symmetrical patterns
Tie problems
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Summary:•We discovered a particular developmental pattern for tie compared to non-tie problem solving.•It corresponds to a direct shift from finger modeling to retrieval.•This might be made possible by easily memorizable symmetrical patterns created on fingers.•In contrast, for non-tie problems, a transitional stage between finger modeling and internalization is necessary.•This explains the difference in cognitive status between tie and non-tie problems in adulthood. Determining how children solve arithmetic problems when they stop using their fingers is a real challenge. To take it up, the evolution of problem-size effects for tie and non-tie problems was observed when 6-year-olds (N = 65) shift from finger counting to mental strategies. These observations revealed that the problem-size effect remained the same for non-tie problems, whereas it drastically decreased for tie problems. Moreover, the solving strategy for tie problems switched directly from the representation of both operands on fingers to retrieval without transition through the representation of only one operand on fingers. This direct switch could be made possible by the relative ease to commit symmetrical representations to memory (in the case of tie problems) rather than non-symmetrical ones (in the case of non-tie problems). This would explain why, early during development, small tie problems are solved quickly and present null or negligible size effects. All in all, our results and interpretations provide an answer to the long-standing question as to why tie problems have a special cognitive status. Our results also nuance the classical description of the developmental pattern reported in all textbook chapters devoted to numerical cognition according to which a finger strategy where only one operand is represented on fingers constitutes a developmental stage between the representation of two operands on fingers and retrieval. We demonstrate here that it is true only for non-tie problems.
ISSN:0022-0965
1096-0457
1096-0457
DOI:10.1016/j.jecp.2024.106154