Egyptian Cotton Cultivation on the Eve of the Cotton Boom

In 1821, a French industrialist discovered the superior quality of long-staple cotton seed in Egypt. Realizing its potential as an export crop, Muhammad Ali Pasha, the autonomous Ottoman viceroy of Egypt in 1805–1848, expanded its cultivation via the state monopoly system that lasted until 1842 and via the expansion of large estates thereafter. Two factors determined the suitability of a given area to cotton cultivation: mild temperature and the availability of perennial irrigation that provided the Nile water during the spring, the cotton planting season (Owen Reference Owen1969, pp. 28–57). Consequently, Muhammad Ali invested in perennial irrigation. New deep summer (sayfi) canals were constructed, traditional nili canals deepened, and water-lifting tools increased (Rivlin 1961, pp. 213–49).

Land and Labor on the Eve of the Cotton Boom

As Muhammad Ali granted land to his family members and top state officials—the Ottoman-Egyptian elite—large estates gradually expanded to occupy 53 percent of land in 1844. This elite were mostly absentee owners who lived in Cairo. Having a monopoly over state violence, they were able to confiscate both barren and peasants’ land. Large estates were formed on barren, deserted, or tax-arrears land, and only exceptionally on tax-paying land. The 1844 cadaster enumerates three legal forms of large estates. First, ib‘adiyas (17 percent of land) were formed on barren land for reclamation purposes. Second, ‘uhdas (28 percent) were formed on deserted and tax-arrears land. Third, jifliks (8 percent) were formed on tax-paying land and granted exclusively to the viceroy (Barakat Reference Barakat1977).

The remaining 47 percent of land in 1844 was usufruct land that belonged to village headmen (medium landholders) and the peasantry (small landholders).Footnote ³ Since village headmen were the largest landholders outside large estates, they constituted a rural middle class that first emerged in 1813 after the abolition of tax farming, as they acted as intermediaries between the peasantry and the state.

There were two labor-coercive institutions: imported slavery and state coercion of local workers. Slavery was a long-standing medieval institution since enslavement of foreign non-Muslims in ghazwas (holy raids) was permitted by Islamic law. Slavery was self-perpetuating by law; a slave’s conversion to Islam did not result in emancipation, and the offspring of a male slave were automatically slaves. In practice, though, the slave population was not sustainable by natural growth due to low fertility and low life expectancy among slaves, and annual slave imports were necessary to meet the demand for slaves.

Slaves constituted 1 percent of the population in 1848.Footnote ⁴ About 94 percent of slaves were blacks (aswad, sudani) from the Nilotic Sudan (Darfur, Kurdufan, and Sennar), while the remaining 6 percent were Abyssinians (habashi) from Ethiopia and whites (abyad) from Circassia and Georgia. Black slaves were transported to Egypt in caravans via trans-Saharan land routes (Fredriksen Reference Fredriksen1977, pp. 29–42). This eastern trans-Saharan slave trade between Egypt (and the Ottoman Empire) and the Nilotic Sudan and Ethiopia was largely segregated from the western trans-Saharan slave trade between North Africa, west of Egypt, and sub-Saharan Africa, west of present-day Sudan.

Employing slaves in agriculture was rare before the cotton boom. After the Abbasids’ attempt to introduce agricultural slavery in ninth-century Iraq ended with a slave rebellion, agricultural slavery mostly disappeared from the region.Footnote ⁵ In 1848, slaves were overrepresented in cities as domestic servants, where they constituted 3 percent of the population, 75 percent of whom were females.

Online Appendix Figure A.1 provides rough estimates of slave prices and imports in Egypt, based on remarks by contemporaneous European consuls and travelers. Panel (A) shows estimates of slave prices in 1800–1877. Whites (not shown) were the most expensive, followed by Abyssinians and blacks. Within each color, females were more expensive. Panel (B) shows estimates of the annual slave imports. Imports increased to 10,000 slaves annually between 1820, when Egypt invaded Sudan, and 1845, when the state stopped its slave raids in Sudan. However, the 1848 census reveals that these numbers are exaggerated. There were around 55,072 slaves in 1848, which is lower than what one would expect under an annual inflow of 10,000 slaves in 1820–1845. After 1845, imports dropped to about 5,000 slaves annually. The cotton boom period witnessed an unprecedented influx of slaves, about 27,500 per year. This is supported by the 1868 census, which shows that the slave population tripled between 1848 and 1868, going up from 55,072 to 173,654 (3 percent of the population).

The second coercive system was state coercion of local workers. Large estates constituted 7 percent of the rural population in 1848.Footnote ⁶ Labor organization varied by the legal form of the large estate. In ib‘adiyas, labor was supplied by agricultural laborers from neighboring villages (Cuno Reference Cuno1992, pp. 162–3). In ‘uhdas, peasants had to work for the landlord without pay until they paid back their tax arrears. In jifliks, peasants remained as tenants, cash-wage workers, or sharecroppers (Cuno Reference Cuno1992, pp. 161–2). Unlike slaves, coerced workers on large estates were not traded.

The Cotton Boom in 1861–1865

After the end of the state monopoly system in 1842, peasants were allowed to sell their output directly to exporters and, hence, became exposed to international price shocks. The U.S. Civil War cotton boom was unexpected, and cotton expansion was not state-planned, but rather due to individual decisions.Footnote ⁷ India and Brazil increased their cotton production too, with India replacing the United States as the world’s top cotton producer. But Egyptian cotton was of higher quality than Indian cotton and thus had a secure market share.

Abolition of Slavery in 1877

European abolitionists prioritized the transatlantic slave trade. Only later they turned their efforts toward abolishing the older, yet smaller and less known, trans-Saharan slave trade. Starting in 1837, British abolitionists pressured Egypt to abolish slavery. The Egyptian state was reluctant to comply because it profited from the slave trade. Furthermore, slavery was endorsed by Muslim jurists, and the abolition was thus against Islamic law (Baer Reference Baer1967).

The real push for abolition occurred in 1869–1876, when Khedive Ismail (1863–1879) ordered several British-led campaigns against Sudanese slave raiders, aiming to restore Egypt’s control over the Nilotic Sudan. The abolition was eventually achieved by the signing of the Anglo-Egyptian Slave Trade Convention in 1877 (Fredriksen Reference Fredriksen1977, pp. 157–80). This was probably facilitated by Ismail’s waning power vis-à-vis Britain, due to Egypt’s default on its international debt in 1876.

Impact of the Cotton Boom

In all three environments, the cotton boom induces landholders in cotton districts to cultivate cotton. Because cotton is labor-intensive, the demand for labor rises. Under environment A, the cotton boom increases slavery in cotton districts as the demand for imported slaves shifts outward. The positive effect on slaveholdings is largest among the elite—the richest landholders—followed by the rural middle class. The demand for local wage labor shifts outward too, although wage employment remains constant, as the local labor supply is fixed by assumption.Footnote ¹¹ Both slave prices and wages go up.

Under environment B, the cotton boom increases state coercion of local workers by the elite. This implies an inward shift in wage labor supply, a fall in wage employment, and a rise in wages as coerced workers are taken out of the wage labor market. The demand for wage labor also shifts outward due to the rising demand among the rural middle class, causing wages to rise.

Under environment C, the cotton boom increases both slavery and state coercion. Slave employment and prices both go up as the demand for slaves shifts outward, where the positive effect on slaveholdings is largest among the rural middle class, not the elite (unlike in environment A). State coercion rises too, as the elite coerce more local workers. The rise in state coercion causes an inward shift in the supply of wage labor, leading wage employment to decline and wages to rise. The demand for wage labor also shifts outward, and wages rise. State coercion reinforces slavery: The cotton boom-induced rise in state coercion may induce the rural middle class to purchase more slaves than under environment A because it reduces the local labor supply facing the rural middle class.

Impact of the Abolition

In all three environments, landholders in cotton districts continue to grow cotton because it remains more profitable than wheat. Under environment A, the abolition induces a further outward shift in the demand for wage labor to substitute for the emancipated slaves. Because all freed slaves emigrate, wage employment remains constant, whereas wages rise.Footnote ¹²

Under environment C, the abolition of slavery causes state coercion to rise, as the elite substitute for their emancipated slaves by coercing more local workers. This leads to a further inward shift in the supply of wage labor and, hence, a further decline in wage employment and a rise in wages. The demand for wage labor also shifts outward to substitute for the freed slaves who were held by the rural middle class, leading wages to rise.

Testable Implications

To summarize, this framework produces the following testable implications (hypotheses) under the dual-coercive environment:Footnote ¹³

H1: Effects of the Cotton Boom:

1. (a) The cotton boom causes an increase in slavery.

2. (b) The effect of the cotton boom on slavery is largest among the rural middle class.

3. (c) The cotton boom increases state coercion of local workers by the elite.

4. (d) The cotton boom reduces wage employment by the rural middle class.

5. (e) The cotton boom-induced rise in state coercion induces the rural middle class to purchase more slaves than in the absence of state coercion.

H2: Effects of the Abolition of Slavery:

1. (a) The abolition of slavery further increases state coercion of local workers by the elite.

2. (b) The abolition of slavery reduces wage employment by the rural middle class.

3. (c) The abolition of slavery causes wages to rise.

Three notes are in order. First, the implications H1(a), H1(c), and H1(d), regarding the effects of the cotton boom on slavery, state coercion, and wage employment, and the implication H2(c), regarding the effect of the abolition of slavery on wages, are shared with single-coercion environments.Footnote ¹⁴ Second, the implications H1(b), H1(e), H2(a), and H2(b) are unique to the dual-coercive environment. The implication H1(b) demonstrates the heterogeneous slave demand response to the cotton boom across landholder classes, due to differences in political power, rather than income, whereas H1(e), H2(a), and H2(b) reflect the interdependence of slavery and state coercion. Second, this conceptual framework focuses on the economic response to the cotton boom and the abolition, not the political response. This is because it treats the (co)existence and abolition of the coercive institutions—the political environment—as exogenous. However, the elite or the rural middle class can (attempt to) alter the coercive institution(s) themselves, a political response that is not captured by the current framework. I come back to this point in the Discussion section.

Data

The empirical investigation of the effects of the cotton boom is based on the 1848 and 1868 population censuses. These censuses include a wide range of variables, such as sex, age, relationship to household head, slave/free status, nationality, religion, ethnicity (e.g., black), occupation, place of residence, and place of origin. Households are clearly delineated. A household record starts with a list of its free members, followed by its (free) servants and slaves. Within each category, males are always recorded before females.Footnote ¹⁵

The census samples are two cross-sections of around 80,000 individuals in each of 1848 and 1868. For the purpose of this article, I aggregated the samples to the household (head) level, which is a suitable level to measure slaveholdings, state coercion, and wage employment. I restrict the analysis to households residing in rural Egypt.Footnote ¹⁶ Out of the universe of 14 rural provinces (70 districts) in 1848, 8 provinces (45 districts) are missing in 1868. We do not know the reason behind this. It could be because the 1868 census was not conducted in these provinces or because their registers did not survive. I use stratified sampling by province each year, where I apply systematic sampling by page on the entire registers of each (surviving) province.Footnote ¹⁷ Because of the random sampling procedure, I observe neither the same households nor the same set of villages in 1848 and 1868.

I restrict the sample to households residing in the (panel of) 25 rural districts that are observed in both 1848 and 1868 in order to control for district fixed effects. This restriction results in two final cross-sectional samples of 2,469 households in 1848 and 3,321 households in 1868, residing in 504 villages in 25 “matched” districts, located within 6 provinces. Two remarks bolster my confidence in the representativeness of this restricted sample for the whole of rural Egypt. First, Online Appendix Table A.1 shows that households in matched districts are not statistically different from those in non-matched districts with respect to most characteristics in 1848. The exceptions are that matched districts have a higher proportion of households whose head is a slave (where all household members, including the head, are slaves), lower cotton and cereals productivity in 1877, a higher proportion of non-Muslim households, a lower proportion of Bedouin households, and a lower number of male free members per household who are 50+ years of age. I control for these characteristics (except the proportion of slave-headed households, which is an outcome) in the empirical analysis. Second, throughout the analysis, I weight the observations so that the restricted sample is representative of rural Egypt.Footnote ¹⁸

There are three outcomes of the cotton boom: slavery, wage employment, and state coercion (see H1 in the Conceptual Framework). I measure slavery at the household level by the number of slaves residing in the household, which captures the overall size of slavery, and by a dummy variable—defined among free household heads only—that equals one if the household head owns at least one slave, which captures the proportion of slave owners.Footnote ¹⁹ An individual’s slave/free status is recorded in both 1848 and 1868, although census takers in 1868 often omitted the “slave” label (‘abd), using other labels instead, such as “black” (aswad), “Sudanese” (sudani), and “follower” (tabi‘). Yet, since individuals with these alternative labels are listed at the end of the household return and do not have any blood or marriage relationships to the head, they are almost certainly slaves (Cuno Reference Cuno2009).

The censuses further enable me to measure the heterogeneity in slaveholdings across landholders by identifying four major social classes: the elite, the rural middle class, the peasantry, and non-landholders. First, I observe the legal form of each household’s area of residence within a village. I use this information to identify areas designated as large estates that belonged to the elite and areas outside large estates—mostly, village subsections (hissa)—that belonged to village headmen and the peasantry.Footnote ²⁰ Second, for households in areas outside large estates, I use occupational titles to determine whether the household head is a village headman (i.e., rural middle class), peasant, or non-landholder. Non-landholders include landless agricultural laborers, white-collar workers, artisans, and unskilled non-agricultural workers.

I then examine the heterogeneity in slaveholdings across landholders using two datasets. Both datasets treat large estates as single area-level observations, but they differ on the level of measurement of households outside large estates: village headmen, peasants, and non-landholders. The first, landholder-level, dataset computes their slaveholdings at the household level, whereas the second, area-level, dataset aggregates their slaveholdings to the area level, and compares slavery in large estate areas to that in non-large estate areas. In both datasets, I measure slavery in large estates by the total number of slaves who resided in the estate.Footnote ²¹

The second outcome is the wage employment of local labor, which I measure at the household level by a dummy variable that equals one if the household head is a landless agricultural laborer. This includes both cash-wage agricultural workers (shaghal, tammali) and sharecroppers (muzari‘).

The third outcome is the state coercion of local labor, which I measure at the area level by the total local population—or, alternatively, the number of agricultural laborers—in large estates. Specifically, I examine the heterogeneity in employment of local workers across large estates (i.e., state coercion) and non-large estate areas (i.e., wage employment).Footnote ²²

The main explanatory variable is the suitability of cotton cultivation, which I measure at the district level by the cotton yield per unit of land in 1877, based on the 1877 Statistical Yearbook (Ministère de l’Intérieur 1877)—the earliest official statistics on crop productivity at the district level.Footnote ²³ Although cotton suitability may have evolved in response to the expansion of perennial irrigation through 1877, it was constrained by temperature and the technological feasibility of construction of summer canals. As a robustness check, I employ alternative measures of cotton suitability, including the Global Agro-Ecological Zones produced by the Food and Agriculture Organization of the United Nations (FAO-GAEZ) (see Online Appendix D). Figure 2 maps the cotton and cereals productivity in 1877 for the matched districts.Footnote ²⁴

Figure 2 COTTON AND CEREALS PRODUCTIVITY IN 1877 IN MATCHED DISTRICTS

Notes: Cotton productivity is the cotton yield in qintars per feddan, and cereals productivity is the yield of wheat, barley, and beans in ardabbs per feddan, where 1 feddan = 6,368 square meters, 1 qintar = 44.5 kilograms, and 1 ardabb = 135 kilograms. The maps show the spatial distribution at the district level for the 25 matched districts.

Sources: The 1877 Statistical Yearbook (Ministère de l’Intérieur 1877).

Table 1 shows the baseline differences in 1848 across high-cotton districts, those above the median cotton productivity, and low-cotton districts. The table reveals that slavery was much larger in low-cotton districts, which is consistent with the historical evidence on employing slaves in state-owned plantations and public works in the non-cotton-growing Nile Valley, before the cotton boom (Helal Reference Helal1999, pp. 110–22). High-cotton districts had a higher proportion of landless agricultural laborers, a lower proportion of self-employed peasants, a lower proportion of non-Muslims, and more free female members per household aged 41–50 years, than low-cotton districts.

Table 1 BASELINE DIFFERENCES IN 1848 BY COTTON PRODUCTIVITY IN 1877

Notes: The sample is restricted to households residing in matched rural districts in 1848. The “Diff” column reports the coefficient of the following household-level regression in 1848: y_hd + α₁ + α₂HighCotton_d + ε_hd, where y _hd is the outcome of household h residing in district d, and HighCotton _d = 1 if the household’s district of residence is above the median cotton productivity in 1877. Regressions are weighted by household weights. Standard errors are clustered at the district level. * p < 0.10, ** p < 0.05, *** p < 0.01.

Sources: The 1848 census sample. Data on crop productivity in 1877 are from the 1877 Statistical Yearbook (Ministère de l’Intérieur 1877).

Empirical Specification

To test the implications of the cotton boom for slavery and wage employment (H1(a) and H1(d)), I employ a difference-in-differences strategy, where I exploit the time variation of the cotton boom and the cross-district variation in cotton productivity:

(1) $${y_{hvdt}} = \delta ({cotton_d} \times {1868_t}) + {X_{hvdt}}{\gamma _1} + {M_{vdt}}{\gamma _2} + {\alpha _d} + {\beta _t} + {\varepsilon _{hvdt}}$$

where y _hvdt is the outcome of household h residing in village v located within district d in census year t, cotton _d is the cotton productivity in district d, 1868_t is a dummy variable that equals one for the 1868 census (i.e., post the cotton boom), α _d is district fixed effects to control for district time-invariant heterogeneity, β _t is census year fixed effects to control for aggregate employment shocks in 1868, and ε _hvdt is an error term. Standard errors are clustered at the district level, the level of aggregation of cotton suitability. To account for the small number of clusters (25 districts), I also report randomization inference (RI) p-values, which do not rely on the asymptotic properties of estimators (Heß Reference Heß2017). This procedure replicates the assignment process of households to districts with different levels of cotton suitability. It then re-estimates the regression under this new assignment and repeats this process 1,000 times. Finally, it constructs empirical p-values that represent the proportion of simulated t-statistics that are larger than the observed t-statistic in the data.Footnote ²⁵

The vector X _hvdt includes a host of household characteristics. I included two dummy variables indicating non-Muslim and Bedouin households, respectively. Non-Muslims were richer than Muslims on average, and Bedouins were granted land to settle in rural Egypt. Therefore, each group probably had more slaves and held a different occupational distribution. I also controlled for the number of non-slave household members broken down by sex and age, which captures a household’s capacity to employ unpaid household labor in agriculture—an alternative option to purchasing slaves and recruiting non-household wage labor on the market. The vector M _vdt includes the district-level cereals productivity in 1877 interacted with the 1868 indicator, which controls for the confounding effect of the Crimean War cereals boom in 1853–1856 (Online Appendix Figures A.2 and A.6), and the village-level distance to Suez and its interaction with 1868, which capture the exposure to drafting local labor by coercion to work in the construction of the Suez Canal in 1859–1864.

The coefficient δ captures the differential growth of slavery and wage employment in 1848–1868 across districts with different levels of cotton productivity. According to H1(a) in the Conceptual Framework, δ > 0 for slavery, and according to H1(d), δ < 0 for wage employment.

The validity of Equation (1) rests on the parallel-trends assumption: In the absence of the cotton boom, slavery and wage employment would have evolved equally in 1848–1868 across districts with different cotton suitability levels, conditional on controls. There is no additional pre-cotton boom population census (besides the 1848 census), and hence, I cannot readily test for the existence of pre-boom differential trends in outcomes by cotton suitability. Instead, I provide three pieces of evidence in support of the parallel-trends assumption. First, Table 1 shows that high-cotton districts were not statistically different from low-cotton districts in 1848, with respect to most household characteristics, which I controlled for in Equation (1). Second, there were two other main shocks that occurred between 1848 and 1868 that I controlled for in Equation (1): the Crimean War cereals boom in 1853–1856, that I accounted for by controlling for cereals productivity, and the construction of the Suez Canal in 1859–1864.Footnote ²⁶ Third, Online Appendix C provides suggestive evidence on the parallel trends of slavery by cotton productivity before the cotton boom, where I exploit the age profiles of slaves to trace the growth of household slaveholdings over time, under the assumption that a slave is purchased at age 6 and lives up to age 50.

I then employ an augmented empirical specification that studies the heterogeneous effects of the cotton boom on slavery and local employment by landholder class (H1(b), H1(c), and H1(d)). I first use the landholder-level dataset to estimate the following model for slavery:

(2) $$\begin{array}{*{20}{c}} {slave{s_{lsvdt}} = \sum\limits_{s = 2}^4 {{\delta _s}(landholderclas{s_s} \times {cotton_d} \times {{1868}_t})} } \\ { + \delta ({cotton_d} \times {{1868}_t}) + \sum\limits_{s = 2}^4 {{\alpha _s}(landholderclas{s_s}) \times {cotton_d})} } \\ { + \sum\limits_{s = 2}^4 {{\beta _s}(landholderclas{s_s} \times {{1868}_t}) + {M_{vdt}}\gamma + {\theta _s}} } \\ { + {\alpha _d} + {\beta _t} + {\varepsilon _{lsvdt}}} \\ \end{array}$$

where slaves _lsvdt is the number of slaves owned by landholder l of class s {2,3,4}; the variable landholderclass _s consists of three dummy variables that indicate peasants in areas outside large estates (s = 2), village headmen in areas outside large estates (s = 3), and large estates (s = 4), respectively; the omitted group consists of non-landholders in areas outside large estates, θ _s is landholder class fixed effects.

Next, I use the area-level dataset to estimate the following model for both slavery and the employment of local labor:

(3) $${outcom{e_{avdt}} = {\delta _1}({largeestate_a} \times {cotton_d} \times {{1868}_t}) + \delta ({cotton_d} \times {{1868}_t})} \\ { + {\alpha _1}({largeestate_a} \times {cotton_d}) + {\beta _1}({largeestate_{a \times }}{{1868}_t})} \\ { + {M_{vdt}}\gamma + \theta {largeestatea_a} + {\alpha _d} + {\beta _1} + {\varepsilon _{avdt}}}$$

where outcome _avdt is the outcome of area a in village v in district d in census year t, and largeestate _a equals 1 if area a is a large estate and equals 0 otherwise.

The coefficients δ _s in Equation (2) capture the heterogeneous effect of the cotton boom on slavery by landholder class in comparison to non-landholders. The implication H1(b) predicts that this effect is largest among the rural middle class (δ ₃ > δ ₂; δ ₃ > δ ₄). The coefficients δ and δ ₁ in Equation (3) capture the heterogeneous effect of the cotton boom on the employment of local labor by landholder class. The implication H1(d) predicts that δ < 0 for the number of agricultural laborers in areas outside large estates (i.e., lower wage employment), while H1(c) predicts that δ ₁ > 0 for local employment in large estates (i.e., higher state coercion).

Finally, I empirically investigate the implication H1(e) on the interdependence of slavery and state coercion during the cotton boom. I am not able to test this prediction directly because both slavery and state coercion are outcomes that were affected by the cotton boom, and because I do not observe the counterfactual of the slavery-only environment. Instead, I provide empirical support for this implication by examining, in a triple difference-in-differences strategy, whether rural middle-class landholders (village headmen) in cotton districts with higher state coercion purchased more slaves during the cotton boom than their counterparts in cotton districts with lower state coercion. To mitigate the endogeneity of state coercion, I measure it in 1848, prior to the cotton boom. I now turn to the findings in the next subsection.

Findings

The findings are shown in Tables 2–4 and graphically in Online Appendix Figures A.9–A.13.Footnote ²⁷ The effect of the cotton boom on slavery is shown in Table 2. Slavery was rare in rural Egypt in 1848, with 0.05 slave per household, on average. Almost all slaves resided in households headed by freemen; only 1 percent of these households owned any slaves, and slave owners had 4.5 slaves on average. However, as predicted in H1(a), the cotton boom caused rural slavery to rise. Column (1) indicates that the boom had a positive and statistically significant effect on the number of slaves per household, and the effect is greater when adding the control variables in Column (2). Districts at the third quartile of cotton yield per unit of land in 1877 (Q ₃ = 1.5) (henceforth, high-cotton districts) witnessed a greater rise in the number of slaves per household in 1848–1868 by 0.19 slave, relative to districts at the first quartile (Q ₁ = 0) (henceforth, low-cotton districts), which is about four times the 1848 average. Column (4) further shows that the proportion of slave owners among free-headed households in high-cotton districts increased by 7 percentage points, relative to low-cotton districts, which is seven times the proportion in 1848. Taken together, Columns (2) and (4) imply that slave owners in high-cotton districts increased their slaveholdings by 2.7 slaves, on average.

Table 2 THE COTTON BOOM AND SLAVERY

Notes: The sample is restricted to 25 rural districts that are observed in both 1848 and 1868. The sample in Columns (3)–(4) is further restricted to households with a free head. The omitted group is non-landholders in non-large estate areas in Column (5), and non-large estate areas in Column (6). Household controls are: =1 if household head is non-Muslim, =1 if household head is Bedouin, the number of household free members broken down by sex and age. District controls are the interaction of the district-level cereals productivity in 1877 with the 1868 indicator, the village’s distance to Suez, and its interaction with 1868. Regressions are weighted by household weights in Columns (1)–(5) (in Column (5), the weight of large estates is equal to the sum of household weights in the area), and by the sum of household weights in the area in Column (6). Standard errors clustered at the district level are in parentheses. * p < 0.10, ** p < 0.05, *** p < 0.01. The probabilities (Pr) refer to the randomization inference p-values.

Sources: The 1848 and 1868 population census samples. Data on cotton and cereals suitability are from the 1877 Statistical Yearbook (Ministère de l’Intérieur 1877).

Table 3 THE COTTON BOOM, WAGE EMPLOYMENT, AND STATE COERCION OF LOCAL LABOR

Notes: The sample in Columns (1)–(2) is restricted to households with a free head. Household and district controls are the same as in Table 2. Regressions in Columns (1)–(2) are weighted by household weights. Regressions in Columns (3)–(5) are weighted by the sum of household weights in the area. Standard errors clustered at the district level are in parentheses. * p < 0.10, ** p < 0.05, *** p < 0.01. The probabilities (Pr) refer to the randomization inference p-values.

Sources: See the sources of Table 2.

Table 4 STATE COERCION REINFORCED SLAVERY DURING THE COTTON BOOM

Notes: The dependent variable is the number of slaves in the (rural middle-class) household. The sample is restricted to village headmen. State coercion in district in 1848 is measured by a dummy variable =1 if there was at least one large estate (Column (1)), the population of large estates (Column (2)), and the number of agricultural laborers in large estates (Column (3)). Regressions are weighted by household weights. Controls are the cereals suitability interacted with the 1868 dummy variable. Standard errors clustered at the district level are in parentheses. * p < 0.10, ** p < 0.05, *** p < 0.01. The probabilities (Pr) refer to the randomization inference p-values.

Sources: See the sources of Table 2.

According to the Conceptual Framework, this positive impact on slavery is driven by the rising demand for labor due to the higher labor intensity of cotton.Footnote ²⁸ A first alternative interpretation of this finding is that slavery increased because of the cotton boom-induced positive income effect. The censuses do not report the tasks of slaves, and hence, I do not observe whether slaves were indeed employed as agricultural laborers. However, following Cuno (Reference Cuno2009), Online Appendix Table A.3 shows that the positive effect on slavery is mostly driven by purchasing male, not female, slaves of working age—6–20 and 21–40 years. This suggests that slaves worked in agriculture, because if the rise of slavery in cotton areas were an (pure) income effect, one would expect most slaves to be females, as in cities, where 75 percent were women presumably working as domestic servants. This male bias also comes in contrast to the balanced sex ratio of slaves in rural provinces in 1848.Footnote ²⁹, Footnote ³⁰

A second alternative interpretation of the positive effect of the cotton boom on slavery is that slaves were transferred from low-cotton districts to high-cotton districts, via migration of slave owners or slave sales on secondary markets. However, the cotton boom caused an increase in Egypt’s slave imports as predicted by H1(a), and not (merely) a movement of slaves within Egypt. First, household slaveholdings in low-cotton districts did not decrease in 1848–1868. Second, the black slave population tripled between 1848 and 1868.

Having established that slavery surged in cotton areas during the cotton boom, I then investigate which landholder class(es) purchased slaves. Consistent with H1(b), Column (5) shows that the positive impact of the cotton boom on slaveholdings is largest among the rural middle class—village headmen in areas outside large estates. Village headmen’s slaveholdings in high-cotton districts surged in 1848–1868 by three slaves per household, compared to their counterparts in low-cotton districts. By contrast, the impact on slaveholdings among owners of large estates is negative, suggesting that the rise in slaveholdings is indeed driven by the rural middle class. The negative effect on slaveholdings in large estates can probably be explained by the rise in coercion of local workers, which I discuss next. Furthermore, I obtain similar results when I estimate the regression at the area level in Column (6), where I find that the positive impact on slaveholdings is driven by landholders in non-large estate areas, that is, non-elite landholders who include the rural middle class.

Table 3 shows the effect of the cotton boom on wage employment and state coercion of local labor. Consistent with H1(d), Columns (1) and (2) demonstrate that the cotton boom had a negative and statistically significant impact on wage employment. High-cotton districts witnessed a 13-percentage point decrease in the proportion of agricultural laborers in 1848–1868, relative to low-cotton districts.Footnote ³¹ Columns (3) and (4) show the heterogeneous effects on the employment of local labor across large estates and non-large estate areas. Consistent with H1(c), Column (3) shows that the cotton boom had a positive and statistically significant effect on the employment of local labor in large estates.Footnote ³² Large estates in high-cotton districts increased their local labor force in 1848–1868 by 61 individuals, on average, relative to large estates in low-cotton districts. As the proportion of the population of large estates declined from 7 percent in 1848 to 3 percent in 1868, this finding implies that large estates became fewer, but larger in size.Footnote ³³ Furthermore, Column (4) shows a negative effect on the number of agricultural laborers in non-large estate areas, as predicted by H1(d), and a positive, yet statistically insignificant, effect on the number of agricultural laborers in large estates.

According to the Conceptual Framework, the increased employment of local labor in large estates during the cotton boom was via state coercion, and not wage recruitment on the market. Two pieces of evidence support this interpretation. First, the legal form distribution of large estates shifted to more coercive forms between 1848 and 1868, from ‘uhdas, where 86 percent of the population of large estates resided in 1848, to jifliks, which had 73 percent of the population of large estates in 1868. Whereas ‘uhdas were temporary confiscations of tax-arrears land that were eventually dissolved and returned to the peasantry in the 1860s as they paid back their taxes (Cuno Reference Cuno1992, pp. 157–60), jifliks were permanent confiscations of tax-paying land. Second, because of their more coercive nature, jifliks probably necessitated a higher use of state violence. Indeed, all jifliks in 1868 belonged to Khedive Ismail himself, which must have made it harder for local workers to flee. Furthermore, jifliks recruited more soldiers and guards, probably to subdue local workers. Column (5) reveals a positive and statistically significant impact of the cotton boom on the number of soldiers and guards on large estates. These soldiers likely implemented the confiscation of the tax-paying land and maintained a continuous presence on the ground to suppress any emerging dissent.

Taken together, the decline in wage employment, despite the rising demand for local labor, can be explained by the decline in labor supply due to state coercion. Consequently, the national-level average daily cash wages of agricultural laborers increased from 0.72 piasters in 1840–1841 (Al-Hitta Reference Al-Hitta1950, pp. 91–5) to 1.85 piasters in 1873, according to the 1873 Statistical Yearbook (Ministère de l’Intérieur 1873, p. 269).

The results on the interdependence of slavery and state coercion (H1(e)) are shown in Table 4. Consistent with H1(e), the findings reveal that rural middle-class landholders (village headmen) in cotton districts that were exposed to higher state coercion in 1848 purchased more slaves during the cotton boom than those in cotton districts with lower state coercion. This indicates that state coercion reinforced slavery during the cotton boom.

I conduct several robustness checks for the effects on slavery and wage employment, which I describe in Online Appendix D. I also demonstrate in Online Appendix E that the effects of the cotton boom on slavery and wage employment are driven by the expansion in cotton cultivation. However, this is not to say that labor coercion was necessary for cotton cultivation (see Online Appendix E).

Having described the effects of the cotton boom on slavery, state coercion, and wage employment, I examine in the next section the effects of the abolition of slavery.

Data

To investigate the impact of the abolition, I complement the 1848 and 1868 censuses with the subsequent published censuses of 1882, 1897, 1907, and 1917 (Ministère de l’Intérieur 1884; Ministère de Finance 1898; Ministry of Finance 1909, 1920). These censuses enable me to measure state coercion and wage employment at the district level. In particular, the proportion of the population in large estates is observed in 1848, 1868, 1882, and 1897.Footnote ³⁴ The proportion of agricultural laborers—including, cash-wage agricultural laborers, tenants, and sharecroppers—is observed in 1848, 1868, 1907, and 1917. The censuses also record the ex-slave population, which enables me to test the assumption that ex-slaves emigrated back to the Nilotic Sudan or gradually disappeared over time as they died without children. The proportion of (ex-)slaves is observed in 1848 and 1868 and is proxied by the proportion of the Sudanese population in 1882, 1907, and 1917.Footnote ³⁵ I also provide suggestive province-level evidence on wages, as laborers’ average nominal daily wages in Egyptian piasters are observed for agricultural laborers in 1873 from the 1873 Statistical Yearbook (Ministère de l’Intérieur 1873), and for unskilled construction laborers in 1903, 1908, and 1913 from the 1914 Statistical Yearbook (Ministère des Finances 1914). However, the evidence on wages must be interpreted with caution due to the small number of provinces.

Empirical Specification

I exploit the variation across districts in the extent of slavery in 1868, on the eve of the abolition, and the time variation of the abolition, where I estimate the following model:

(4) $${y_{dt}} = \delta (slaver{y_{d,1868}} \times Post{1877_t}) + \gamma ({X_d} \times Post{1877_t}) + {\alpha _d} + {\beta _t} + {\varepsilon _{dt}}$$

where y _dt is the outcome of district d in census year t, Slavery _d,1868 is the proportion of slaves in district d in 1868, Post1877_t is a dummy variable that equals one for the post-1877 period, α _d and β _t are district and census year fixed effects, respectively. Standard errors are clustered at the district level. I also report randomization inference p-values.

The vector X _d consists of time-invariant characteristics of districts: the initial value of the dependent variable in 1848, the proportion of slaves in 1848, the district’s cereals productivity, and the district’s distance to Suez. To account for the potential endogeneity of slavery in 1868, I employ the interaction of the district’s cotton productivity with the post-1877 indicator, as an instrumental variable for Slavery _d,1868 × Post _1877t.

The coefficient δ compares the evolution of outcomes before and after the abolition across districts with different levels of reliance on slavery in 1868. H2(a) predicts that δ > 0 for the proportion of the population in large estates: The abolition of slavery has a positive effect on state coercion of local workers. H2(b) predicts that δ < 0 for the proportion of agricultural laborers because the rise in state coercion will further reduce wage employment. The Conceptual Framework also predicts (by assumption) that δ < 0 for the ex-slave population. Finally, H2(c) predicts that δ > 0 for wages.

Findings

The results are shown in Table 5, and graphically in Online Appendix Figures A.14–A.16. Columns (1) and (2) show the effect of the abolition on state coercion of local workers. While the OLS and IV estimates are both positive, which is consistent with H2(a), they are not statistically significant. Similarly, Columns (3) and (4) reveal that the abolition had a negative effect on wage employment, which is consistent with H2(b), but the effect is not statistically significant. This suggests that while the positive effect of the abolition on state coercion, and its negative effect on wage employment, may have been at play, these effects were muted and not statistically significant. I interpret these findings in the Discussion section.

Table 5 IMPACT OF THE ABOLITION OF SLAVERY ON STATE COERCION, WAGE EMPLOYMENT, AND WAGES

Notes: Regressions are at the district-year level in Columns (1)–(6) and at the province-year level in Columns (7)–(8). Standard errors are in parentheses, clustered at the district level in Columns (1)–(6), and at the province level in Columns (7)–(8). The IV regressions employ the interaction of the post-1877 dummy variable with the district’s (province’s) cotton productivity as an IV. * p < 0.10, ** p < 0.05, *** p < 0.01. The probabilities (Pr) refer to the randomization inference p-values.

Sources: The 1848 and 1868 population census samples, and the 1882, 1897, 1907, and 1917 population censuses (Ministère de l’Intérieur 1884; Ministère de Finance 1898; Ministry of Finance 1909, 1920). Wages are from the 1873 and 1914 Statistical Yearbooks (Ministère de l’Intérieur 1873; Ministère des Finances 1914).

I investigate the effect of the abolition on the proportion of emancipated slaves in Columns (5) and (6), finding a negative and statistically significant impact, which is consistent with the assumption of the Conceptual Framework that emancipated slaves did not become agricultural laborers. At the aggregate level, the Sudanese population in rural Egypt first increased between 1848 and 1868, remained constant through 1882, and then witnessed a secular decline from 149,312 in 1882 to 24,766 in 1917.Footnote ³⁶ The results in Columns (5) and (6) further indicate that this post-1877 decline in the ex-slave population was greater in high-cotton districts. This negative effect can be explained by three mechanisms: (1) emigration: ex-slaves may have returned to the Nilotic Sudan; (2) gradual disappearance: first-generation slaves, who were mostly males, may have died without offspring; and (3) assimilation: descendants of slaves may have increasingly self-identified as Egyptians in the population censuses. Because assimilation of ex-slaves is unlikely to vary across districts by cotton suitability and because the ex-slave population did not decline in 1868–1882 and decreased only gradually thereafter, suggesting that there was no sudden large emigration wave after the abolition, the negative effect on the ex-slave population is probably explained by the gradual disappearance of slaves that was larger in high-cotton districts. Since the sex ratio of slaves in these districts was more male-biased than in low-cotton districts (Online Appendix Table A.3), slaves probably died without children, which was exacerbated by the low life expectancy of slaves (Lovejoy Reference Lovejoy2012, pp. 7–8). This phenomenon—the disappearance of slaves in the long run—has been noted before for the whole Middle East by various scholars including Wright (Reference Wright2007, p. 22) who noted that “most of these people [enslaved blacks] seem to have disappeared without trace,” and attributed the phenomenon to the low marriage rate of slaves and their low life expectancy. That said, I am not able to rule out both emigration to Sudan and assimilation as potential mechanisms at play.

Finally, Columns (7) and (8) show that the abolition had a positive effect on wages, which is consistent with H2(c). The evidence is only suggestive, though, because of the small number of provinces.

To summarize, the abolition of slavery did not have a statistically significant effect on state coercion and wage employment. However, it did have a negative effect on the ex-slave population, which can be due to gradual disappearance, emigration, or assimilation, and a positive effect on wages (subject to the caveat of the small number of provinces). I turn in the next section to a discussion of the empirical findings for both the cotton boom and the abolition.