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Children's arithmetic skills do not transfer between applied and
academic mathematics
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  * Open access
  * Published: 05 February 2025

Children's arithmetic skills do not transfer between applied and
academic mathematics

  * Abhijit V. Banerjee  ORCID: orcid.org/0000-0001-9923-6088^1,
  * Swati Bhattacharjee^2,
  * Raghabendra Chattopadhyay^3,
  * Esther Duflo  ORCID: orcid.org/0000-0001-6105-617X^1,
  * Alejandro J. Ganimian^4,
  * Kailash Rajah^1 &
  * ...
  * Elizabeth S. Spelke  ORCID: orcid.org/0000-0002-6925-3618^5 

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Nature (2025)Cite this article

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Subjects

  * Economics
  * Education
  * Human behaviour

Abstract

Many children from low-income backgrounds worldwide fail to master
school mathematics^1; however, some children extensively use mental
arithmetic outside school^2,3. Here we surveyed children in Kolkata
and Delhi, India, who work in markets (n = 1,436), to investigate
whether maths skills acquired in real-world settings transfer to the
classroom and vice versa. Nearly all these children used complex
arithmetic calculations effectively at work. They were also
proficient in solving hypothetical market maths problems and verbal
maths problems that were anchored to concrete contexts. However, they
were unable to solve arithmetic problems of equal or lesser
complexity when presented in the abstract format typically used in
school. The children's performance in market maths problems was not
explained by memorization, access to help, reduced stress with more
familiar formats or high incentives for correct performance. By
contrast, children with no market-selling experience (n = 471),
enrolled in nearby schools, showed the opposite pattern. These
children performed more accurately on simple abstract problems, but
only 1% could correctly answer an applied market maths problem that
more than one third of working children solved (b = 0.35, s.e.m. =
 0.03; 95% confidence interval = 0.30-0.40, P < 0.001). School
children used highly inefficient written calculations, could not
combine different operations and arrived at answers too slowly to be
useful in real-life or in higher maths. These findings highlight the
importance of educational curricula that bridge the gap between
intuitive and formal maths.

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Main

Maths curricula taught in primary school ought to provide children
with the concepts and skills that they need both for their daily
lives and as a foundation for learning the higher maths required to
succeed in school at more advanced levels. Too often, however, formal
schooling fails to achieve either of these goals. In India, in 2023,
only half of the children enrolled in grades 11 and 12 (16-18 years
of age) could divide a three-digit number by a single-digit number^4.
Globally, learning outcomes remain poor despite large increases in
school enrolment in many low-to-middle-income countries^1,5.

Moreover, children seem even less likely to be able to use basic
arithmetic skills in everyday life. A recent study in India^4, for
example, found that only half of the children enrolled in grades 11
and 12 could calculate how many purifying tablets to use in a large
pot after they were given the number they needed for a smaller pot.
Notably, 35% of the children who were able to solve an abstract
division problem failed this verbal exercise^4.

However, many children in low-to-middle-income countries, for
instance, those who work in markets, seem to routinely perform more
involved calculations as part of their daily jobs. For example, a
study in the 1980s of five children who worked as street vendors
(mean age of 11 years) in Brazil found that these children ably and
flexibly used maths in their work^2. These findings are in line with
ethnographic studies of adults with minimal formal education who also
exhibit these abilities^6,7,8. Moreover, decades of research^9,10,11,
12, mostly in Western countries, have shown that children can adeptly
combine small sets to create exact larger numbers well before
schooling begins^13 and that their facility of learning maths in
primary school is associated with their sensitivity to approximate
number in later years of schooling^14. A prominent theory in
cognitive psychology suggests that learning maths in meaningful
real-world contexts can complement maths learnt in the classroom and
provide children with more generalizable and flexible arithmetic
skills^15,16. By learning and practising maths through relevant
contexts, children may be better equipped to acquire the flexible
cognitive skills they need to transfer maths knowledge across
domains.

Under this hypothesis, children who work in markets might be expected
to more easily learn the abstract maths taught in school. However,
just as children who master abstract maths skills in school may fail
to apply them to concrete problems, schools may fail to help children
who adeptly use maths concepts in concrete situations in their daily
lives to develop more abstract, generalizable skills. In the absence
of such help, such skills may not automatically transfer across
domains in either direction.

Here we ask whether, in the urban Indian context, the arithmetic
skills that are used in market transactions transfer to the more
abstract maths skills taught in school. Markets provide a
particularly appropriate setting to ask this question because
children who work in markets regularly perform maths in real-world
activities that are culturally relevant and important to their lives.
Moreover, these children are sufficiently engaged in these activities
to be able to acquire meaningful maths competencies while often
regularly attending school. We also ask whether children who attend
school but without real-world experience of using arithmetic skills
can translate the maths taught in schools to perform arithmetic
operations in more concrete situations such as market transactions.

We surveyed a large number of children in urban India who were either
attending or have attended school for years while also selling goods
in markets. These children spent part of the day at school and part
of the day at the market and therefore received exposure to
arithmetic operations in both settings. In these studies, we analysed
working children's ability to use maths to compute payments as part
of their daily job and their ability to generalize their knowledge,
gained either in school or in the market, to new problems. We also
surveyed large numbers of school children with no market-selling
experience, which enabled us to benchmark working children's
performance and to test whether abstract maths knowledge by itself
transfers across domains.

Working children effectively perform arithmetic operations

In this study (study 1), we tested whether children working in
markets are able to perform complex arithmetic calculations as part
of their daily jobs. We surveyed 201 children in Kolkata, West
Bengal, working in markets (see the section 'Study 1' of the Methods
). Undercover enumerators purchased unusual quantities of two goods
from each child working at the store and paid with a bill that was
worth more than the required amount. For example, the enumerators
might ask how much 800 g of potatoes that the child sells at
20 rupees per kilogram costs and then how much 1.4 kg of onions that
the child sells at 15 rupees per kilogram costs. They would then ask
for the total cost (37 rupees in this case), before handing the child
a 200 rupee note and collecting the change. Each of these steps was
designed to measure the children's applied arithmetic skills.
Afterwards, the enumerators revealed their identity and asked the
participants to complete a set of abstract maths exercises.

Most of these children effectively used arithmetic calculations in
their jobs. Figure 1a presents the proportion of children who
correctly reported the amount due and change in the three enumerator
transactions on both their first and second try (if incorrect on the
first try). Overall, 95%, 97% and 98% of children were correct by
their second try for the first, second and third transactions,
respectively (Fig. 1a and Extended Data Table 1). Most children
mentally performed these calculations with no paper aids.

Fig. 1: Performance of children in Kolkata working in a market (study
1).
figure 1

a, Proportion of children who correctly answered the total amount due
in transactions involving two goods sold in unusual quantities. b,
Proportion of children who correctly answered the total amount due in
hypothetical transactions. c, Proportion of children who were
credited with labelling single-digit numbers, labelling two-digit
numbers, subtracting and dividing on the ASER test, a tool for
assessing numeracy used across India for the ASER. Error bars show
95% CIs around the mean (mean +- 1.96 x s.e.m.). d, An example of this
arithmetic assessment tool. From left to right, each column presents
items that respectively task children with identifying single-digit
numbers, identifying two-digit numbers, subtracting one two-digit
number from another with carrying, and long division of a three-digit
number by a single-digit number with a remainder. For grade 5
children, the ASER test begins with the subtraction task and proceeds
to the right (division) if children succeed and to the left
(identifying two-digit numbers) if they fail. Because success at each
level requires mastery of the operations required by the tasks to its
left, children who succeed at a given level are credited with mastery
of all the levels below it.

Source data

Full size image

To determine whether these children used mental arithmetic to solve
market transactions or had learnt many of the costs for familiar
quantities by rote for the items they sold, the enumerators purchased
unusual quantities and not round amounts. Moreover, in a subsequent
interview, we presented children with a set of two hypothetical
market maths problems of similar complexity to those of the market
transactions but with different items and prices. Paper and pencil
aids were made available to all the children.

Our results suggest that the arithmetic skills acquired in markets
extended beyond rote memorization and were transferable to new
problems within the realm of market transactions, but with some loss.
On average, across both transactions, 52% of the children correctly
solved the hypothetical transaction either on the first try or after
self-correction despite the challenges of retaining new information
about unfamiliar goods, prices and units (Fig. 1b and Supplementary
Table 1). They did so without help, without the use of calculators
and without using pen and paper.

However, despite their arithmetic competencies, these children
struggled with school maths presented in abstract form. We presented
the children with problems from India's Annual Status of Education
Report (ASER), which classifies children according to their oral
answers to written problems of single-digit division with a remainder
(taught in grade 4), double-digit subtraction with a remainder
(taught in grade 2), recognition of two-digit numbers (taught in
grade 1) and recognition of single-digit numbers (taught in
kindergarten), administered with paper aids (Fig. 1d). As shown in
Fig. 1c, when these children were given the ASER test, only 32% of
children could solve a division of a three-digit number by a
single-digit number, and 54% of children could solve two subtractions
of a single two-digit number from another (Fig. 1c and Supplementary
Table 2). This was despite the fact that only 13% of children
reported that they had left school before the end of grade 4, when
division is taught (Supplementary Table 3), and almost all of them
attended grade 2, when subtraction is taught. The performance of
these children was similar to the ASER test performance of a
representative sample of children who live in rural areas of West
Bengal, where 29% of children in grade 5 could solve similar division
problems^17. This result suggests that children who work in markets
are not differentially selected on school arithmetic skills.

The marked gap between the strong performance of the working children
on real and hypothetical market transactions and their weak
performance on the written exercises presented in school is unlikely
to be explained by the difficulty of the underlying arithmetic
calculations. If anything, the operations required by the market
transactions were more difficult than those of the written arithmetic
problems on the ASER, as the market transactions involved several
operations.

Performance on abstract arithmetic problems remained poor when
arithmetic problems with the same structure were orally presented.
Only 3% of children could solve a new division problem like those on
the ASER test when orally presented, and 43% could solve orally
presented subtraction problems after two attempts (Supplementary
Table 4). Thus, participants performed worse in school maths problems
not just because problems were presented in written form^3 but
because of the abstract presentation in itself.

This analysis suggests that children who have flexible arithmetic
skills fail to apply them when the problems are presented in an
abstract form similar to what is presented in school. Framing
arithmetic problems as they are presented in school led them astray,
just as an inappropriate or new framing sometimes confounds adults
with knowledge of sophisticated maths^6,18.

Working children struggle with unfamiliar problems

We next tested a new group of children from a different region
(study 2a), both to examine the generality of the results from
study 1 and to assess further potential confounds. In Delhi, we
surveyed 400 children who worked among 39 markets. As in Kolkata, we
performed three undercover purchases in addition to the survey (see
the section 'Study 2' in the Methods and Extended Data Table 2).

The findings in study 2a were consistent with those of study 1. The
children we questioned in Delhi correctly calculated the amount due
and change on the three successive market maths problems. Overall,
96%, 99% and 97% succeeded in the first, second and third
transactions, respectively, by their second try (Fig. 2a and
Supplementary Table 5). Only one child used a calculator and 2%
received help from others at their store. No child made written
calculations (Fig. 3a and Supplementary Table 6). Because each
calculation involved four operations, these findings imply both high
average accuracy on each operation and excellent working memory.
However, like their counterparts in Kolkata, the children in Delhi
performed poorly on abstract school maths questions. Only 15% could
correctly perform division on the written ASER test (Fig. 2c and
Supplementary Table 7), a result similar to published ASER results
for Delhi^19, where 18% of children correctly performed division.
Similarly, only 11% could do so when the problems were orally
presented (Supplementary Table 8).

Fig. 2: Performance of working and non-working children in Delhi
(study 2).
figure 2

a, The proportion of children who correctly answered the total amount
due in three transactions involving two goods sold in unusual
quantities. b, The proportion of children who correctly answered the
total amount due in five hypothetical transactions. c, The proportion
of children who were credited with labelling single-digit numbers,
labelling two-digit numbers, subtracting and dividing on the ASER
test. Error bars show 95% CIs around the mean (mean +- 1.96 x s.e.m.).

Source data

Full size image
Fig. 3: Calculation methods of working and non-working children in
Delhi (study 2).
figure 3

a, The proportion of children who used pen and paper, classified by
respondent type and type of exercise. b, The number of times that
working and non-working children wrote numbers and operations in the
paper given to them for non-oral exercises. Error bars show 95% CIs
around the mean (mean +- 1.96 x s.e.m.). c, Example of calculations on
paper written by a non-working child.

Source data

Full size image

To test whether children who work performed better on the market
maths problems because they were incentivized by market pressure, we
randomly assigned children to receive either a fixed payment or a
monetary incentive for correctly answering the problems. We did not
find evidence that incentives affected their performance (kh^2(4, n =
 400) = 2.01, P = 0.73; Extended Data Table 3).

To understand more precisely the effect of familiarity on the ability
to conduct arithmetic calculations, we asked children five
hypothetical market maths problems that became progressively more
complex and further removed from their activity in the market that
day. Performance declined for problems that required children to hold
more new information in mind and to perform a sequence of operations.
After one chance to self-correct for initial mistakes, 96% of these
children correctly calculated the amount due in a transaction that
involved the same goods that they sold at the same price that they
sold it, and 88% did so when the price was different (b = 0.09,
s.e.m. = 0.02, 95% confidence interval (CI) = 0.05-0.12, P < 0.001;
Supplementary Table 9). Children's performance declined when a second
item was added at a different price (69% correct, b = 0.19, s.e.m. =
 0.03, 95% CI = 0.14-0.25, P < 0.001; Supplementary Table 9), which
required multiple operations and provided more opportunities for
errors. Performance declined even further when the problems involved
two goods sold using an unfamiliar pricing scheme, for example, by
units rather than kilograms or vice versa (61% correct, b = 0.08,
s.e.m. = 0.03, 95% CI = 0.01-0.14, P = 0.02; Fig. 2b and
Supplementary Table 9).

These declines in performance were accompanied by changes in the
approach used by the children to solve the problem, with more
reliance on pen and paper and techniques taught in school. When they
worked with an item sold at their store, only 4% of children used pen
and paper. As the transactions became less familiar and involved more
operations, children increasingly relied on pen and paper: 29% with
two goods sold in familiar units (b = -0.25, s.e.m. = 0.02, 95% CI =
 -0.30 to -0.20, P < 0.001; Extended Data Table 4), and 41% when it
involved two goods sold in unfamiliar units (b = -0.12, s.e.m. =
 0.03, 95% CI = -0.18 to -0.05, P < 0.001; Extended Data Table 4 and
Supplementary Table 10). Finally, when the problems were presented
with no concrete context, as are oral arithmetic operations in
school, 58% of them used pen and paper (Fig. 3a).

School children perform poorly on concrete problems

Good arithmetic performance in market maths problems did not
translate to good performance in school-like problems. Therefore, we
asked whether proficiency in maths taught in schools transfer to
real-world situations (study 2b). To that end, we surveyed 200
children attending 20 government schools in Delhi, located in the
same zones as the markets from study 2a. These children, matched in
age to the children working in markets in Delhi, were given the same
written and verbal arithmetic problems as the working children,
including the same school maths tests. We also created a play-based
pretend market, in which the school children sold items to the
enumerator, who presented them with the same hypothetical market
maths problems given to the working children in Delhi.

The children in Delhi who were surveyed in schools and in markets
differed in many respects, including their schooling history and
their experience with markets (Extended Data Table 5). Twenty-two
per cent of the non-working school children in study 2 had worked at
a market, but only 1% of them had handled transactions. However,
non-working children had attained, on average, a full grade level in
school above that of the working children. Thus, differences in the
arithmetic skills attained by these two groups captured not only the
causal effect of attending school or working regularly but also the
potential effect of selection for working in markets at a young age
and the effect of an additional grade of school instruction, among
other factors.

Non-working children solved simple abstract arithmetic problems with
high accuracy when they were given unlimited time and pen and paper.
Fifty-six per cent of children correctly answered the division
portion of the written exercises presented abstractly, as in school
(ASER test) (Fig. 2c and Supplementary Table 7). These proficiency
rates were below grade-based expectations for grades 8 and 9, but
they were above the performance of working children, of whom 15%
correctly answered the division portion of the tests (b = 0.41,
s.e.m. = 0.04, 95% CI = 0.34-0.47, P < 0.001; Supplementary Table 7).
Most of the non-working school children also correctly solved
hypothetical transaction maths problems, regardless of whether the
problem involved one or two goods. On average, they performed with
96% accuracy with one chance at self-correction (Fig. 2b and
Supplementary Table 11).

Thus, non-working school children seemed to master basic arithmetic
skills well. However, they performed poorly in the more concrete
problems asked in the pretend market. About 60% of them could
correctly calculate the amount due in market transactions (63%, 51%
and 69% of the non-working school children correctly performed the
first, second and third transactions, respectively, on the first or
second try; Fig. 2a and Supplementary Table 5). Furthermore, a
comparison with working children is somewhat unfair, as the
non-working children were able to use pen and paper and had no time
limit.

Indeed, non-working school children relied heavily on pen and paper
whenever given a chance: 96% of them used pen and paper on the ASER
test and 74% of them used pen and paper for the hypothetical market
transactions (Fig. 3a and Supplementary Table 12). An examination of
the written work of the school children on all these untimed
exercises suggested that most school children had not fully mastered
the algorithms of elementary arithmetic (Fig. 3c and Extended Data
Fig. 1). On average, a non-working child wrote 102 numbers and 22
operations on their sheets of paper (Fig. 3b and Supplementary Table
13). Nearly half (46%) of these children repeated the same operation
and 6% wrote the same operation in two different ways. Close to
one-fifth (17%) of these children made extensive use of tally marks
and serial numbers, converting addition problems to a process of
counting by ones and/or converting multiplication problems to a
process of counting by twos or fours (a strategy taught in grade 1).
Even with the use of these strategies, non-working school children
often had to rewrite or reframe the same problem several times before
reaching a solution.

When faced with maths transactions in the simulated market,
non-working school children did not change strategy (Fig. 3a). Around
two thirds of non-working children used pen and paper (whereas none
of the working children did), and across the three transactions, 23%
used repeated additions instead of multiplying, which was a
significant difference from the working children for matched
transactions (b = 0.18, s.e.m. = 0.02, 95% CI = 0.14-0.23, P < 0.001;
Supplementary Tables 6 and 14). For the pretend market maths
problems, it seemed that these strategies were inadequate, perhaps
because they involved several separate steps and the strategies
adopted for each step took a long time to perform and combining
different steps is yet another skill. However, in this study, we
cannot rule out that the school children performed poorly because of
the unfamiliar setting of the pretend market (for example, because
they were excited by the game aspect).

Limited skill transfer is not explained by confounds

In this study (study 3), we asked why working children and school
children performed so differently depending on the context in which a
maths problem was presented. We conducted 835 surveys with working
children in Delhi over two waves of data collection: March-April 2023
(wave 1) and February 2024 (wave 2). We also surveyed 271 children
with no market-selling experience from nearby schools in
November-December 2022 (along with wave 1 of the market survey).

Working children again performed well in their jobs. Overall, 85%
calculated the correct amount due and change in the market
transactions (Supplementary Table 15), whereas non-working children
struggled in a pretend market situation. The pretend market was set
up in a similar manner as for study 2 but with a time limit, no use
of pen and paper and problems matched in difficulty to what children
who work in markets do. This set up enabled us to test children's
performance in a setting that most closely paralleled that in a
market. Only 10% of non-working children could provide the correct
change (Supplementary Table 16). Finally, working and non-working
children were provided with the same oral abstract subtraction and
division problems (with pen and paper allowed). Overall, 59% of
non-working children correctly solved these problems compared with
45% of working children (b = -0.14, s.e.m. = 0.03, 95% CI = -0.20 to
-0.08, P < 0.001; Fig. 4, left). Thus, the results of study 3
replicated the principal findings of studies 1 and 2 and highlight
the contrasts between working and non-working children both in
real-life and school-like situations.

Fig. 4: Comparison of working and non-working children in oral
abstract and market maths word problems (study 3).
figure 4

Left, comparison of the performance of working and non-working
children on the same abstract subtraction and division problems.
Middle, comparison of the performance of working and non-working
children on the market maths word problem after a single attempt.
Right, comparison of the performance of working and non-working
children on the market maths word problem after receiving a hint to
break down the problem and to make use of rounding strategies
(process + rounding hint). The oral abstract problems and market
maths word problems were not matched in difficulty with one another.
A child was coded as correct if they initially correctly answered the
question or after receiving the hint. Error bars show 95% CIs around
the mean (mean +- 1.96 x s.e.m.). P values are calculated using
two-tailed t-tests without adjustments for multiple comparisons.

Source data

Full size image

To examine the reasons for these differences in performance, new data
collection and several experiments were embedded in the data
collection effort for both groups of children.

Robustness to alternative explanations

Our leading explanation for these results is that working children do
less well on abstract maths questions because they resort to poorly
mastered algorithms taught in school. Conversely, school children do
poorly in applied problems because they do not know any strategies
other than those taught in school and they have not mastered those
strategies sufficiently well to solve these more involved problems.
It is possible, however, that the children's performance was impaired
by stress, stereotype threat or weak incentives to perform
accurately, so we tested the effects of these factors.

Familiarity

We asked whether the differences in performance reflect the impact of
the presentation by itself or by anxiety induced by the lack of
familiarity. It is conceivable that working children were anxious
when confronted with a standard abstract problem that they would
otherwise be able to solve. Alternatively, school children may have
been anxious, or too excited to focus, when performing in the pretend
market situation because they had never worked in a market.

To address this issue, we created a question that would feel familiar
to both working and non-working children. We devised a concrete maths
word problem presented in a format that is familiar to school
children but mimicked the activity that working children perform. It
is a story of a boy, Vishal, who goes to the market with 200 rupees
and buys different quantities of two vegetables. The question is how
much money Vishal is left with. Rounding could be used to simplify
problems of the cost of both goods. We did not allow pen and paper
for this question. This task has a familiar context for school
children (who routinely solve word problems in school) and is a
familiar task for the working children (who routinely perform this
task in their work).

Working children outperformed school children on this market maths
word problem. At the first attempt, 36% of working children correctly
answered the question compared with 1% of non-working children (b =
 0.35, s.e.m. = 0.03, 95% CI = 0.30-0.40, P < 0.001; Fig. 4, centre).
When the first answer was incorrect, at the second attempt, a random
subset of children were given a hint to break down the problem and to
apply a rounding strategy. In such cases, 50% of the working children
correctly answered the problem by their second attempt, compared with
5% of the non-working children (b = 0.45, s.e.m. = 0.05, 95% CI =
 0.35-0.55, P < 0.001; Fig. 4, right). The working children
calculated more fluently than the non-working children despite the
attempt to render the problem equally familiar to both groups. We
also did not find evidence that working children who also attended
school performed better than those out of school on the market maths
word problem (b = -0.02, s.e.m. = 0.05, 95% CI = -0.12 to 0.08, P =
 0.730; Extended Data Table 6), although the working children who
were still in school performed almost twice as well on abstract maths
problems (b = 0.29, s.e.m. = 0.03, 95% CI = 0.22-0.36, P < 0.001;
Extended Data Table 6). These results provide further evidence of the
minimal skill transfer from school to real-world situations.

Stress and stereotype threat

When working children were taken aside to answer questions in a
school format, they may have felt threatened by it. It is possible
that the situation induced stress or self-stereotyping (for example,
'I am not good at school'). In study 3a, wave 1, we included a
randomized experiment with four conditions to test for the impact of
stress and stereotype threat on the performance of working children.
In the first treatment ('market maths problem first'), to put
children at ease, we presented the hypothetical market maths problems
before the oral abstract subtraction problems. The second treatment
('encouragement') aimed to vary the level of self-confidence of the
children by having the surveyor use encouraging language during the
survey versus without. We cross-randomized these treatments to
produce four conditions.

At the end of the survey, we measured children's stress levels using
a series of Likert-scale questions. Both confidence-related
treatments reduced the stress levels of working children but did not
improve performance. Relative to the control group who received
neither treatment, the market maths problem first group, the
encouragement group and the group who received both treatments
reported 0.17, 0.32 and 0.23 standard deviations less stress,
respectively. However, we did not observe significant improvements in
performance of solving abstract subtraction questions across any of
the treatments: market maths problem first group (b = -0.20, s.e.m. =
 0.15, 95% CI = -0.49 to 0.08, P = 0.163); encouragement group (b =
 -0.06, s.e.m. = 0.14, 95% CI = -0.34 to 0.22, P = 0.689); or market
maths problem first with encouragement group (b = -0.16, s.e.m. =
 0.15, 95% CI = -0.46 to 0.13, P = 0.272). Therefore we can reject
small effects (Table 1).

Table 1 Impact of confidence treatments on stress and maths
performance of working children in Delhi
Full size table

Incentives

School children may face weaker incentives to correctly answer
problems. So, we tested whether providing school children with
material incentives improved their performance, by giving a random
sample of children tokens to exchange for gifts. We did not find
significant differences in performance across groups (b = 0.10,
s.e.m. = 0.12, 95% CI = -0.14 to 0.34, P = 0.406; Extended Data Table
7).

Meaningfulness

We randomized children to receive different versions of the survey so
that we could test them on oral abstract and oral anchored problems
that involved the same numbers. Working children performed
significantly better on anchored problems, correctly answering 72% of
anchored problems compared with 64% of abstract problems (b = 0.08,
s.e.m. = 0.02, 95% CI = 0.03-0.12, P  = 0.001; Fig. 5a and
Supplementary Tables 17 and 18). By contrast, non-working children
performed significantly worse on oral anchored addition and
multiplication problems, correctly answering 73% of anchored problems
and 78% of abstract problems (b = -0.06, s.e.m. = 0.03, 95% CI =
 -0.11 to -0.01, P = 0.028; Fig. 5a and Supplementary Table 18).
Thus, meaningfulness had differing effects on the performance of the
two groups of children, a result consistent with the different
contexts in which they learnt arithmetic skills.

Fig. 5: Comparison of working and non-working children on abstract
versus anchored and roundable versus non-roundable problems (study
3).
figure 5

a, The proportion of children who correctly answered abstract versus
anchored problems. We tested children on oral problems involving
addition and multiplication. b, The proportion of children who
correctly answered roundable versus non-roundable problems. We tested
children on oral problems involving abstract addition, abstract
subtraction, abstract multiplication, anchored addition and anchored
multiplication. Error bars show 95% CIs around the mean
(mean +- 1.96 x s.e.m.). P values were calculated using two-tailed t
-tests without adjustments for multiple comparisons.

Source data

Full size image

Understanding the different processes working children use

Given the large gap between applied and theoretical skills, with no
transfer in either direction, we collected additional data on how
working children reason and encouraged them to use more efficient
algorithms.

Compositional structure

We asked working children how they solved the hypothetical market
maths problems involving goods from their store. Many children
simplified calculations by using rounding and decomposition
techniques that leverage the base-ten structure of the number system
(44% when problems involved standard market prices and 36% when they
involved new prices) (Supplementary Table 19). They did so by
converting complex operations (for example, 11 x 43) into a series of
simpler ones (for example, solving 11 x 43 by converting the problem
to (10 x 43) + 43). A large proportion (26% at market prices and 16%
at new prices; Supplementary Table 19) also used approximations to
simplify calculations by rounding subtotals up or down by 1 or 5 (for
example, approximating 0.7 kg of cauliflower at 20 rupees per
kilogram to be 15 rupees). These methods may explain how working
children solve complex problems so quickly and accurately without the
need for pen and paper.

We then tested whether children leveraged these strategies on
school-like abstract and anchored problems. We compared their
performance on problems with an operand ending in 1 or 9 (roundable
problems) with their performance on problems presenting numbers of
similar sizes lacking those endings (non-roundable problems such as
12 x 42). Working children performed slightly better on roundable
problems (67% correct) than on non-roundable problems, although the
difference was not significant at the 5% level (64% correct, b =
 0.03, s.e.m. = 0.02, 95% CI = 0.00-0.07, P = 0.083; Fig. 5b and
Supplementary Table 20). For non-working children, we did not see
evidence of a difference: 75% answered roundable arithmetic questions
correctly compared with 74% of non-roundable ones (b = 0.00, s.e.m. =
 0.02, 95% CI = -0.04 to 0.05, P =  0.868; Fig. 5b and Supplementary
Table 20). It was notable that non-working school children did not
use this structure, particularly as it forms the foundations of the
arithmetic algorithms taught in school. Moreover, working children,
who apparently discovered this structure over the course of their
work in markets, had not mastered the school-taught algorithms that
were based on it.

Hints

In further experiments, we asked whether the differences between
working and non-working school children are easily overridden or
difficult to overturn. Because working children performed better on
problems that were anchored to a familiar and concrete context, we
asked whether they could improve their performance in abstract
arithmetic problems by reframing them in such a context. Because
school children did not seem to effectively use the base-ten system
to simplify problems, and market children did so only to a limited
extent, we asked whether children in both groups could be induced to
use rounding to improve their calculations. We addressed these
questions by including an experiment in which children were provided
various hints.

For working children, we tested rounding and anchoring hints in two
separate scenarios. Neither anchoring nor rounding hints had a
significant impact on how accurately the children answered these
problems, with treatment effects of -2 percentage points (b = -0.02,
s.e.m. = 0.04, 95% CI = -0.09 to 0.05, P = 0.583; Extended Data Fig.
2a and Supplementary Table 21) and 1 percentage point, respectively (
b =  0.01, s.e.m. = 0.03, 95% CI = -0.06 to 0.07, P = 0.866; Extended
Data Fig. 2b and Supplementary Table 22). For non-working children,
the hints were given in the context of the market maths word problem.
They received hints to break down the problem and to use rounding
strategies. Again, we did not find evidence that hints improved
performance relative to those who only received a second chance (b =
 0.00, s.e.m. = 0.03, 95% CI = -0.06 to 0.06, P = 0.881; Extended
Data Table 8 and Extended Data Fig. 2c). We conclude that by the time
they reach adolescence, the cognitive differences between working and
non-working children are not easily overturned.

Schools must bridge the gap between formal and intuitive maths

These studies provide evidence from three large groups of children
from India that the majority of children working in markets are
skilled in the arithmetic calculations used in their daily work.
Moreover, they flexibly perform market transactions such that they
rapidly adjust to correctly deal with transactions involving unusual
quantities of the goods they sell. When tasked with a hypothetical
transaction involving a change in price or items, most children
performed correctly on the first try, and many of those who did not
were correct on the second try. Even when presented with a complex
market-inspired word problem involving four different operations, 35%
correctly answered on the first try (and 50% succeeded after a chance
at self-correction and a hint), which implied high levels of success
at performing, sequencing and remembering each of the four arithmetic
operations. By contrast, only 1% (b = 0.35, s.e.m. = 0.03, 95% CI =
 0.30-0.40, P < 0.001; Fig. 4, centre) of the non-working children
could solve the word problem in one try (5% with hints; b = 0.45,
s.e.m. = 0.05, 95% CI = 0.35-0.55, P < 0.001; Fig. 4, right). We rule
out confounding factors such as the possibility that the working
children were chosen for their maths skills, that they received help
from others, used calculation aids or had stronger incentives. It
seems plausible that experience in markets, where goods change with
seasonal factors, where prices change regularly across or within days
and where there is always time pressure, leads children to discover
flexible arithmetic strategies.

By contrast, we found little evidence that these real-world
competencies helped children to perform school-based maths. Working
children, most of whom were still in school (and the rest had
attended school in the past) were not able to solve elementary
written or oral abstract problems of subtraction and division as
presented in school. This result is notable, particularly given that
the algorithms taught in school are also based on the same base-ten
compositional structure that working children use in solving the
market maths problems that can be simplified by rounding to the
nearest ten.

Conversely, non-working school children performed more accurately
than working children in solving simple abstract problems taught in
schools but poorly on concrete problems involving several simple
operations, such as the ones routinely solved by working children.
Moreover, their accuracy came at an extreme cost in speed. That is,
many school children solved simple multiplication problems, such as
24 x 8, by rewriting them as longer addition problems (here, a
problem with eight two-digit addends) or still longer counting
problems (here, by tallying and counting the numbers of twos and ones
in the written addition problem). Thus, neither group of children had
developed the maths skills required for further study in maths,
science and many other disciplines.

These findings point to a broader failure of the pedagogical
practices in India to make usable connections between intuitive and
formal understanding of maths ideas. The pedagogy in place does not
teach school students strategies to do maths in real-world settings.
It also does not take advantage of the fact that working children
have developed such strategies on their own to help them bridge their
specific skill sets, well-tailored to the markets, to the skills
needed to succeed in a school-based setting. This failure echoes the
finding from a randomized control trial (RCT) of low-income preschool
children in Delhi^20, whereby primary schools were not able to build
on intuitive maths skills that children had acquired by playing math
games in preschool. Although children's intuitive sense of maths
durably improved following an intervention in preschool, their
performance in formal maths did not when they encountered the grade 1
maths curriculum over the subsequent year^20.

These findings call for a maths pedagogy that explicitly addresses
these translational challenges through curricula that connect
abstract maths symbols and concepts to intuitively meaningful
contexts and problems. Consistent with that call, a RCT found that
introducing financial education to public high school students in
Brazil was effective not only in improving financial literacy but
also in reducing school failure rates, with qualitative interviews
suggesting that students felt more engaged with maths presented in
familiar contexts^21.

The low performance of working children and school children in
primary school maths problems also calls for changes in how maths is
introduced to children, in particular to better synergize intuitive
knowledge and training in symbolic maths. There is encouraging
evidence that it might be possible: two RCTs of students in
preschool, kindergarten and grade 1 in Delhi showed that a curriculum
that pairs intuitive and abstract maths materials, and leads children
to exercise both in alternation in group games, had durable impacts
on both their school maths and their intuitive maths skills (Dean, J.
T. et al., manuscript in preparation).

Methods

All materials and methods were reviewed and approved by the
Institutional Review Boards at the Massachusetts Institute of
Technology (MIT) (IRB1504007082, IRB1612798217 and IRB2208000727) and
the Institute for Financial Management and Research (IRB00007107). We
obtained informed consent from all study participants. The studies
involved randomization, and we used power calculations to determine
our target sample sizes. We include a more detailed summary of our
methods in the Supplementary Methods.

Statistical analysis and code

In all analyses, we calculated group means and compared them using
two-tailed t-tests. In Extended Data Table 6 and Supplementary Tables
21 and 22, we compared groups using linear regressions. We present
these results with and without controls. To calculate standardized
indices (for example, when measuring stress), we first standardized
the individual outcomes that make up a given index, averaged them and
then standardized the final variable to have a mean of 0 and a
standard deviation of 1. We conducted all of our analyses in Stata
and plotted figures in R.

Study 1

Sample

There is no list of all informal (wholesale and retail) markets that
employ children in India because child labour is illegal. Therefore
we drew a convenience sample of markets in all studies. In study 1,
we identified potential markets and then visited them to verify that
they employed children. This process identified 92 markets. We drew a
convenience sample of working children at each market. An enumerator
walked around each market and noted where children were located. We
only approached children who appeared to be 16 years of age or
younger, were selling goods and sold more than one good. We did,
however, stop the survey if we discovered that the child was 18 years
of age or older. This led us to include some children who were
17 years of age. In study 1, 201 out of 285 working children whom we
approached agreed to participate. Given that the vast majority of
children consented to participate, selection on who consents is
unlikely to be driving our results, although we cannot rule this out
entirely. Of these children, 141 were enrolled in school (average
grade attained at the time of testing, 6.24) and 60 were not (average
grade attained, 3.67) (Supplementary Table 3).

Survey structure

For study 1, our survey consisted of the following sections: (1)
market transactions; (2) consent; (3) ASER written assessment; (4)
oral abstract and anchored assessment; (5) hypothetical transactions;
and (6) demographics.

Market transactions

In the market transactions section, each working child was approached
by two enumerators dressed as regular buyers who purchased two goods
(for example, 300 g of beans and 200 g of peas). When goods were sold
by the unit (for example, bananas), enumerators bought them by the
unit. When they were sold by the kilogram (for example, tomatoes),
enumerators bought them by the kilogram or gram. In both cases,
enumerators avoided purchasing common quantities (for example, 1 kg
or 500 g or 1-2 units) to minimize the probability that children had
memorized the prices of the quantities requested.

When a child told the enumerators the amount due, they were asked how
they had arrived at that total (for example, by an enumerator who
said, 'I expected it to be less'), which prompted the child to
explain their calculation. If the calculation was correct, the
enumerators paid and left. If it was incorrect, the enumerators asked
the child to verify their calculation (for example, saying 'Are you
sure? How did you get that? Do it again and see'). Regardless of
whether the child's calculation of the amount due was correct, the
enumerators offered more money than was due, took the change and
left. The use of calculators, paper aids and help from adults was
permitted but the enumerator kept a record of each.

In studies 1 and 2a, two other pairs of undercover enumerators
repeated the same process, resulting in three transactions per child.
One of the three pairs of enumerators revealed their identity and
invited the child to participate in the study.

ASER

The ASER is a survey of learning outcomes for school-aged children
conducted annually by Pratham, a non-governmental organization in
India. ASER is representative of rural India, although in some years,
it was also conducted in select urban areas.

Study 2a

Sample

We followed a similar process for identifying children and markets as
in study 1. In this study, we conducted the main survey after the
first market transaction. We later returned with undercover
enumerators to complete the second and third transactions. Of the 442
working children approached, 400 agreed to participate and 344
completed all three transactions (Extended Data Table 2)

Survey structure

The survey consisted of the following sections: (1) market
transactions (as in study 1); (2) consent; (3) ASER written
assessment (as in study 1); (4) oral abstract and anchored assessment
(as in study 1); (5) hypothetical transactions; (6) roundable
problems for a subsample of 85 children; and (6) demographics.

Rounding prices in the market

It is common practice for shopkeepers in markets in India to round
prices up or down by one or to the nearest multiple of five. In
studies 2 and 3, for all market transactions (for working children),
pretend market transactions (for school children) and hypothetical
transactions (for working and non-working children), we considered
the price quoted for an individual good to be correct if it was
rounded up or down by one from the exact answer, rounded up or down
by five from the exact answer or the exact answer itself. For
example, if the exact answer was 35.5 rupees, we would treat 30, 35,
35.5, 36 and 40 as correct answers. We did this because such rounding
is common practice and does not reflect the inability of the child to
solve problems.

For the combined price of goods 1 and goods 2, we considered any
answer that adds the correct (rounded or unrounded) prices of
individual goods to be correct. For example, if carrots cost
18 rupees and potatoes cost 32 rupees, we would consider a total
price of 52 rupees to be a correct answer; 18 rupees can be correctly
rounded to 20 rupees, and 20 rupees plus 32 rupees gives a total of
52 rupees.

For the change provided, we calculated the correct answer by
subtracting the true cost of each good from the cash provided (not by
subtracting the amount quoted by the child from the cash provided).
For example, if we purchased 600 g of apples at 30 rupees per kg and
200 g of potatoes at 20 rupees per kg and gave the child 200 rupees,
then we would calculate the exact answer as 200 - (0.6)(30) - (0.2)
(20) = 200 - 18 - 4 = 178, irrespective of what the child quoted for
the total amount due. We also allowed the same rounding as described
for the combined price of goods 1 and goods 2. For example, we would
also treat 200 - 20 - 5 = 175 to be correct.

Hypothetical transactions

In study 2a, there were five hypothetical transactions that varied
one aspect of the transaction at a time. For example, for a child who
sold carrots by the kilogram that day, the first would be a
hypothetical problem focused on selling carrots at the familiar price
by kilogram. The second problem would be selling carrots at a new
price by kilogram, the third, selling carrots at the same new price
by kilogram and a second unfamiliar good sold at a new price by
kilogram. The fourth problem would be selling a new good, for example
bananas, at a new price by units, and finally, selling bananas at the
same new price by units and a second unfamiliar good at a new price
by units (see Supplementary Methods, study 2a, for more details and
examples of the problems). We provided children with pen and paper.

Incentive randomization

Each child was randomly assigned to two versions of the exercises: a
version that offered them 10 rupees for every exercise that they
answered correctly (in addition to the 200 rupees for participating)
and a version that did not offer any incentives.

Roundable problems

In study 2, a subset of 85 working children were given four exercises
explicitly designed to encourage the use of decomposition and
repeated grouping. To give children maximum latitude to reveal their
sensitivity to the base-ten structure, paper and pencil aids were
made available to them. In all other respects, the problems mirrored
those of the abstract and anchored arithmetic problems from the
preceding test. They were not provided any hint that this was a
possible strategy to follow. We present the results in Supplementary
Table 23.

Solution methods

We collected all the sheets of paper that working children used
during the written exercises, hypothetical transactions and roundable
problems. We developed a coding system to characterize the
calculation strategies used by these children (for example, the
number of numbers that children wrote on the page, whether they used
tallies or serial numbers, among others) and asked data-entry
operators to use these codes to enter data on every sheet of paper.
Every sheet was coded twice by two different data-entry operators to
identify and correct any inconsistencies in data entry.

Study 2b

Sample

In study 2b, in July-August of 2017, we surveyed 200 children
attending 20 government schools located in a 2-km radius of the
markets we identified. We selected ten children at random from
grade 8 and ten children from grade 9. All school children agreed to
participate.

Survey structure

Study 2b consisted of the following sections: (1) consent; (2)
pretend market transactions; (3) ASER written assessment (as in
study 2a); (4) oral abstract and anchored assessment (as in
study 2a); (5) hypothetical transactions (as in study 2a) and
roundable problems (as in study 2a); and (6) demographics. We
recorded solution methods as in study 2a.

Pretend market transactions

We set up a pretend market in classrooms with plastic goods and
money. We told children to imagine they were selling items in a shop
and that the surveyor was a customer. We randomized children to sell
by kilograms or units. We asked the child to go to the desk at the
front of the classroom and select any two items that they wanted to
sell. We then checked the goods that they selected had different
prices and explained to the child that the prices written were sold
per kilogram or by unit. Children were then given plastic money of
300 rupees in small change and told that they could use pen and paper
during the transaction if needed. We then followed the same process
we used with working children, performing three separate
transactions.

Study 3a, wave 1

Sample

We followed a similar sampling strategy to study 2a. Of the 489
working children who completed a market transaction with one of our
surveyors, 372 agreed to participate and completed the full survey.
We present the characteristics of our study 3 sample in Supplementary
Table 24.

Survey structure

Study 3a, wave 1 consisted of the following sections: (1) market
transactions (as in studies 1 and 2a); (2) consent; (3) hypothetical
transactions and calculation explanations; (4) oral abstract
subtraction and hints (with the order of (3) and (4) randomized); (5)
market maths word problem; (6) market maths word problem with hints;
(7) oral abstract division; and (8) demographics and stress measures.

Hypothetical transactions and calculation explanations

We asked children two hypothetical transaction questions. They were
allowed to attempt the question twice if they were initially
incorrect. After each question, we asked children how they solved the
problem. We audio-recorded their response, transcribed it and then
categorized the solution method they used.

Market maths word problem

We gave children a problem that was presented in a format that was
familiar to school children but mimics the activity that working
children do. Rounding could be used to simplify the cost of both
goods. We did not allow pen and paper. The problem read: "Vishal went
to the market with 200 rupees. He bought 450 grams of peas at 100
rupees a kilogram, and 200 grams of tomatoes at 90 rupees a kilogram.
How much money does he have left?".

Confidence treatments

In previous work, we found that children who performed well in
arithmetic operations in the course of their job did not do well when
solving standard arithmetic calculations when presented in a
school-maths formulation. Two possible reasons for this are that
children become stressed or lose confidence when they are presented
with problems in a setting they are not familiar with. To test this
hypothesis, we introduced two cross-randomized treatment variations.
The first treatment varied whether oral abstract subtraction problems
were presented before or after the hypothetical market maths
problems. If abstract problems cause stress and stress impairs
performance, then children who completed the abstract problems first
will be more stressed while completing the abstract and hypothetical
market maths problems and perform less well. The second treatment
attempted to vary the level of self-confidence of the children by
having the surveyor use more or less encouraging language during the
survey. Specifically, we began by telling children we were interested
in how children who work in markets 'manage to be so exceptionally
good at doing mental calculations' versus 'manage to do mental
calculations in the course of their work, but often do poorly in
school'.

Stress measures

As a first-stage measure for the confidence treatments, we measured
children's stress, confidence and attitudes to maths at the end of
the survey.

Study 3a, wave 2

Sample

We returned to 34 out of the 38 markets we visited in study 3a,
wave 1. We did not conduct a real market transaction with children in
this study. However, we used a similar strategy to recruit children
to ensure a comparable sample. As in previous studies, surveyors
spent time observing children to determine whether they were handling
transactions at their shop (calculating prices and providing change).
If they appeared to be doing so, surveyors approached the child and
enquired about the price of a good at a specific quantity. For
example, asking 'How much do 300 g of apples cost?'. If the child did
not answer the question and had someone else in the shop answer on
their behalf, we assumed that the child did not handle transactions
and did not begin the survey with them. As a final check, we also
directly asked children at the beginning of the survey whether they
handled transactions and screened them out of the study if they did
not. Of the 566 working children who were approached by one of our
surveyors, 463 passed these screens, agreed to participate and
completed the full survey.

Survey structure

Our survey consisted of the following sections: (1) consent; (2)
simple arithmetic and confidence building; (3) hypothetical
transaction; (4) warm-up abstract and anchored addition and
multiplication arithmetic calculations; (5) oral abstract subtraction
with anchoring hints; (6) oral abstract and anchored multiplication
with rounding hints; (7) process hints; and (8) demographics.

Warm-up abstract and anchored addition and multiplication arithmetic
operations

We asked children a series of oral addition and multiplication
problems. Some of the problems were abstractly framed whereas others
were anchored to a concrete context. This section served several
purposes. First, it put children further at ease before they began
the hint sections of the survey. Second, we randomized children into
five groups who were given differing numbers of problems (ranging
from two problems to six problems). This provided random variation
for the position that questions appeared within the survey, which
controlled for question order effects in our subsequent hint
experiments. Finally, we compared performance on abstract and
anchored problems. We randomized children into two versions of the
test to exactly balance problem difficulty on abstract and anchored
problems. We also provided a mix of roundable and non-roundable
problems of similar difficulty.

Hint experiments

We include a detailed summary of the anchoring, rounding and process
hint experiment methods in the Supplementary Methods (study 3a), with
results in Extended Data Table 8, Extended Data Fig. 2 and
Supplementary Tables 21, 22 and 25.

Study 3b

Identification of schools

We followed a similar sampling strategy to study 2b. We surveyed a
total of 300 children, half in grade 7 and half in grade 8. All
children we approached agreed to participate. Our main analysis
focused on the 271 school children with no market-selling experience.

Survey structure

For study 3b, our survey consisted of the following sections: (1)
consent; (2) ASER (as in studies 1 and 2; Supplementary Table 26);
(3) written abstract, oral abstract and oral anchored assessment; (4)
market maths word problem (as in study 3a, wave 1); (5) pretend
market problem (as in study 3a, wave 1); and (6) market maths
word problem with hints.

Written abstract, oral abstract and oral anchored assessment

We tested how school children's arithmetic performance changed
depending on how questions were delivered by asking questions in
written abstract, oral abstract and oral anchored forms. For each of
these sections, we tested children on one addition, subtraction,
multiplication and division question. Other than the key feature, we
balanced the complexity of the problems across these sections by
randomizing children into one of four versions of the survey. For
example, across the versions, children were tested on oral abstract
and oral anchored problems with the exact same numbers. We also
balanced the difficulty of roundable and non-roundable problems by
ensuring they had similar numerical quantities and the same
requirements to carry over numbers.

Pretend market transactions

We again set up a pretend market in children's classrooms but made
several changes relative to study 2 to test children's performance in
a setting that most closely parallels selling in a market. In
particular, we designed the problem to be of comparable difficulty to
the real-world market transactions, did not allow children to use pen
and paper and required children to respond in 4 min or less.

Market maths word problem with hints

We tested whether providing a hint to use rounding strategies
improves performance for non-working children, who may underutilize
flexible arithmetic algorithms. There were two treatment groups: one
received a hint to break down the problem; the other received
a hint to both break down the problem and to use rounding strategies.
Finally, the control group could re-attempt the problem without a
hint.

Incentives

All children received tokens on the basis of whether they correctly
answered the questions. We randomized whether children could exchange
these tokens for non-financial gifts (incentives treatment) or
whether children received a fixed gift (no incentives treatment).

Reporting summary

Further information on research design is available in the Nature
Portfolio Reporting Summary linked to this article.

Data availability

All data are publicly available without restriction from the J-PAL
Dataverse on the Harvard-MIT data archive (https://doi.org/10.7910/
DVN/VPVH00). Source data are provided with this paper.

Code availability

All code is publicly available without restriction from the J-PAL
Dataverse on the Harvard-MIT data archive (https://doi.org/10.7910/
DVN/VPVH00).

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Acknowledgements

This project was funded by the Post-Primary Education Initiative of
the Abdul Latif Jameel Poverty Action Lab (J-PAL), the Foundation
Blaise Pascal and the Fonds AXA pour la Recherche. The Delhi
Directorate of Education authorized the conduct of two of the studies
in this article. We thank R. Banerji, P. Bergman, N. Buchbinder,
A. de Barros, Y. Dhavala, W. Easterly, A. Eble, H. Hill, H. Kannan,
R. Murnane, J. Rockoff, J. Star, M. Urquiola, A. Venkatachalam,
A. Wuermli, H. Yoshikawa and seminar participants for comments; and
M. Goenka, S. Mallick, R. Menon, R. Pugalia, G. Sharma, A. Srinivasan
and P. Tiwari for their research assistance.

Author information

Authors and Affiliations

 1. Department of Economics, Massachusetts Institute of Technology,
    Cambridge, MA, USA

    Abhijit V. Banerjee, Esther Duflo & Kailash Rajah

 2. Ananda Bazar Patrika, Kolkata, India

    Swati Bhattacharjee

 3. Indian Institute of Management, Kolkata, India

    Raghabendra Chattopadhyay

 4. Steinhardt School of Culture, Education, and Human Development,
    New York University, New York, NY, USA

    Alejandro J. Ganimian

 5. Department of Psychology, Harvard University, Cambridge, MA, USA

    Elizabeth S. Spelke

Authors

 1. Abhijit V. Banerjee
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 2. Swati Bhattacharjee
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 3. Raghabendra Chattopadhyay
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 4. Esther Duflo
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 5. Alejandro J. Ganimian
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 6. Kailash Rajah
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 7. Elizabeth S. Spelke
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Contributions

The following authors contributed to the research design and
management of data collection: A.V.B. and E.D. to studies 1-3; S.B.
and R.C. to study 1; A.J.G. and E.S.S. to studies 2 and 3; and K.R.
to study 3.

Corresponding authors

Correspondence to Abhijit V. Banerjee, Esther Duflo or Elizabeth S.
Spelke.

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Competing interests

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Peer review information

Nature thanks Thomas Breda, Stanislas Dehaene, Zach Parolin and Harry
Patrinos for their contribution to the peer review of this work.

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Extended data figures and tables

Extended Data Fig. 1 An example of non-working children's scrap paper
in study 2, when solving the problem: "You want to buy 8 carrots at
23 rupees each; what do you pay?".

(a) Multiplication converted to repeated numbers by writing down the
memorized series for counting by fours. (b) An unsuccessful attempt
to solve a problem by tallying. (c) Multiplication converted to
repeated addition.

Extended Data Fig. 2 Impact of hints on working children's
performance in study 3 wave 2.

(a) Proportion of children who correctly answered abstract questions
in the anchoring hints section of the survey. (b) Proportion of
children who correctly answered abstract and anchored multiplication
questions in the rounding hints section of the survey. (c) Proportion
of children who correctly answered a complex abstract or anchored
question in the process hints section of the survey. Error bars show
95% confidence intervals around the mean (mean +- 1.96 x s.e.m).
P-values are calculated using two-tailed t-tests without adjustments
for multiple comparisons.

Extended Data Table 1 Proportion of children who calculated the
amount due and change correctly in market transactions in study 1
Full size table
Extended Data Table 2 Number of children working in markets
approached and surveyed
Full size table
Extended Data Table 3 Proportion of children in each category of the
ASER test by incentive group in study 2
Full size table
Extended Data Table 4 Comparison of calculation methods across
hypothetical transactions for working children in study 2
Full size table
Extended Data Table 5 Proportion of study participants with selected
characteristics in study 2
Full size table
Extended Data Table 6 Comparison of performance of working and
non-working children on the exact same problems in study 3
Full size table
Extended Data Table 7 Impact of incentives on non-working children's
performance in study 3b
Full size table
Extended Data Table 8 Impact of process and rounding hints on
non-working children's performance on the market word problem in
study 3b
Full size table

Supplementary information

Supplementary Information

This file contains Supplementary Methods and Supplementary
Tables 1-26.

Reporting Summary

Source data

Source Data Fig. 1

Source Data Fig. 2

Source Data Fig. 3

Source Data Fig. 4

Source Data Fig. 5

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Cite this article

Banerjee, A.V., Bhattacharjee, S., Chattopadhyay, R. et al.
Children's arithmetic skills do not transfer between applied and
academic mathematics. Nature (2025). https://doi.org/10.1038/
s41586-024-08502-w

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  * Received: 08 March 2022

  * Accepted: 05 December 2024

  * Published: 05 February 2025

  * DOI: https://doi.org/10.1038/s41586-024-08502-w

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