IFPRI Discussion Paper 01576 

November 2016 

Does a “Blue Revolution” Help the Poor?  

Evidence from Bangladesh 

Shahidur Rashid 

Nicholas Minot 

Solomon Lemma 

Markets, Trade and Institutions Division 



 
 

 

INTERNATIONAL FOOD POLICY RESEARCH INSTITUTE 

The International Food Policy Research Institute (IFPRI), established in 1975, provides evidence-based 
policy solutions to sustainably end hunger and malnutrition, and reduce poverty. The institute conducts 
research, communicates results, optimizes partnerships, and builds capacity to ensure sustainable food 
production, promote healthy food systems, improve markets and trade, transform agriculture, build 
resilience, and strengthen institutions and governance. Gender is considered in all of the institute’s work. 
IFPRI collaborates with partners around the world, including development implementers, public 
institutions, the private sector, and farmers’ organizations, to ensure that local, national, regional, and 
global food policies are based on evidence. 

AUTHORS 
Shahidur Rashid (S.Rashid@cgiar.org) is a senior research fellow in the Markets, Trade and Institutions 
Division of the International Food Policy Research Institute (IFPRI), New Delhi. 
 
Nicholas Minot (N.minot@cgiar.org) is a senior research fellow in the Markets, Trade and Institutions 
Division of IFPRI, Washington, DC. 
 
Solomon Lemma (S.Lemma@cgiar.org) is a senior research assistant in the Markets, Trade and 
Institutions Division of IFPRI, Washington, DC. 

Notices  
1. IFPRI Discussion Papers contain preliminary material and research results and are circulated in order to stimulate discussion and 
critical comment. They have not been subject to a formal external review via IFPRI’s Publications Review Committee. Any opinions 
stated herein are those of the author(s) and are not necessarily representative of or endorsed by the International Food Policy 
Research Institute. 
2. The boundaries and names shown and the designations used on the map(s) herein do not imply official endorsement or 
acceptance by the International Food Policy Research Institute (IFPRI) or its partners and contributors.  

3. This publication is available under the Creative Commons Attribution 4.0 International License (CC BY 4.0), 
https://creativecommons.org/licenses/by/4.0/. 

Copyright 2016 International Food Policy Research Institute. All rights reserved. Sections of this material may be reproduced for 
personal and not-for-profit use without the express written permission of but with acknowledgment to IFPRI. To reproduce the 
material contained herein for profit or commercial use requires express written permission. To obtain permission, contact  
ifpri-copyright@cgiar.org. 

mailto:S.Rashid@cgiar.org
mailto:N.minot@cgiar.org
mailto:S.Lemma@cgiar.org
https://creativecommons.org/licenses/by/4.0/


 

iii 

Contents 

Abstract v 

Acknowledgments vi 

1.  Introduction 1 

2.  Concepts and Previous Research 3 

3.  Data and Methods 5 

4.  Trends in Aquaculture in Bangladesh 7 

5.  Welfare Implications of Aquaculture Growth 11 

6.  Summary and Implications 16 

References 17 



 

iv 

Tables 

4.1 Trends in fish production in Bangladesh, 1983/1984–2012/2013 7 

4.2 Changes in annual per capita fish consumption (kg/person/yr) in Bangladesh, 2000–2010 9 

5.1 Net positions of households in aquaculture fish in Bangladesh 11 

5.2 Impacts of aquaculture growth on household’s income 13 

5.3 Impacts of aquaculture growth on poverty reduction 15 

Figure 

4.1 Real prices (2010 = 100) of selected fish varieties in Bangladesh, 1986–2014 10 
  



 

v 

ABSTRACT 

The impressive growth in aquaculture is now commonly dubbed a “blue revolution.” In some Asian 
countries, fish availability has increased at a faster rate in recent decades than did cereal availability 
during the Green Revolution. As an example, Bangladesh is one country where aquaculture has increased 
almost eightfold since the early 1990s. This growth has important implications for food and nutrition 
securities. Yet, there is little research on the determinants and impacts of this growth to document the 
lessons, identify evolving issues, and guide policy discussions. This paper attempts to fill that gap. Using 
several rounds of nationally representative household survey data, the authors conducted 
microsimulations to generate disaggregated estimates. The results show that, between 2000 and 2010, 
about 12 percent of Bangladesh’s overall poverty reduction can be attributed to aquaculture growth. In 
other words, of the 18 million Bangladeshis who escaped poverty during this period, more than 2 million 
of them managed to do so because of the growth in aquaculture. However, the results vary widely across 
income groups, with households in the third income quintile (which is not the poorest) benefiting the 
most. The implications of the results, methodological issues, and areas of future research are also 
discussed.  

Keywords:  aquaculture, Bangladesh, poverty, prices and welfare analysis, microsimulations  



 

vi 

ACKNOWLEDGMENTS 

The fieldwork and conceptualization of this research was funded by the US Agency for International 
Development through the International Food Policy Research Institute’s (IFPRI’s) Policy Research and 
Strategy Support Program in Bangladesh. The subsequent works have been supported by IFPRI and 
CGIAR’s Consortium Research Program. The authors have benefited from discussions with Nurul Islam, 
Xiaobo Zhang, Paul Dorosh, Akhter Ahmed, and Shahidur R. Khandker. The usual disclaimer applies. 
 



 

1 

1.  INTRODUCTION  

Aquaculture is one of the world’s fastest growing food sectors, and its share in global fish consumption 
by humans is projected to grow to more than 60 percent by 2030 (FAO 2014). This growth is remarkable 
given that the sector was almost nonexistent in the 1950s and its share in total fish production remained 
below 20 percent until the early 1990s. The underlying implications of this trend are considered to be so 
significant that they are now commonly termed a “blue revolution,” and there are good reasons for using 
such terms. Aquaculture holds the promise of meeting most of the world’s fish demand without ruining 
the environment (Economist 2003; Sachs 2007); it also will be able to help reduce poverty while 
improving food security and nutritional well-being.1 If aquaculture had stopped growing in 1980—that is, 
if growth in the world’s fish supply depended only on marine and inland capture fisheries—per capita 
annual fish availability in 2013 would have been only 14.0 kg, which is 17 percent lower than the 
availability in 1980 and about half of the actual availability of 26.8 kg in 2013. The consequences of such 
a scenario are easy to imagine: higher prices, lower consumption, and far greater pressure on marine and 
inland capture fisheries. The adverse consequences would have been particularly severe for the 
developing countries of Asia, where fish is an important part of the diet, providing more than 60 percent 
of animal source protein (FAO 2005), and where fish production and marketing provide the livelihoods 
for millions of poor households.  

Thanks to technological innovation and some deliberate policy actions, the world did not have to 
live through such a reality. Calculations from the Food and Agriculture Organization’s (FAO’s) Aquastat 
database indicate that Asian countries increased their aquaculture production from 10.8 million tons in 
1990 to 58.9 million tons in 2012, with developing countries accounting for about 86 percent of the total 
production. While China has led the way in this growth, some other countries in Asia have also 
experienced impressive growth in aquaculture since the 1990s. For example, farmed fish production in 
Bangladesh increased from about 240,000 tons in 1992/1993 to 1.86 million tons in 2012/2013, with 
growth in fish availability far exceeding growth in cereal availability during the Green Revolution.2 Until 
the mid-1990s, aquaculture had been the smallest of the three main types of fisheries—marine, inland 
capture, and aquaculture—in the country, representing only 16 percent of total fish production; but it has 
grown to become the largest type, accounting for 55 percent of total fish production in 2013.3 This growth 
and structural change have contributed to increasing fish availability, reducing the real price of fish, and 
generating employment, with important implications for poverty reduction and nutritional well-being.4  

Thus, there has been increasing interest in the poverty and income distribution implications of 
aquaculture growth in Bangladesh.5 However, empirical studies have only recently begun to emerge. 
Even though the literature provides important insights, there remain significant gaps in terms of both 
conceptual understanding and empirical methodologies.6 Conceptually, the aquaculture-poverty linkage 
literature closely resembles the agricultural growth linkage literature in that almost all available studies 
hypothesize aquaculture to have both direct and indirect benefits on poverty. However, there are 
ambiguities regarding the definition and quantification of these direct and indirect benefits. Existing 
                                                      

1 There is a body of literature on the relationship between aquaculture and food security, poverty, and environment. For 
further reference, see Ahmed and Lorica (2002) on food security; Toufique and Belton (2014) and Belton et al. (2012) on poverty 
impacts, and Naylor et al. (2000) and Pingali (2001) on environmental impacts. 

2 According to official data, production of aquaculture fish grew by about 15 percent in the 1990s, as compared with a 
growth in rice production of about 3 percent during the Green Revolution. 

3 These estimates are based on the Department of Fisheries (DoF) data, which are further discussed in Section 4. 
4 The nutritional implications are particularly important for Bangladesh because fish accounts for 63 percent of animal 

source protein (FAO 2005) in Bengali diets; it is the most important source of high-quality protein, essential fatty acids, and 
micronutrients (Roos et al. 2007); and it is the most frequently consumed, nutrient-rich, animal-source food among all income 
groups in Bangladesh (Toufique and Belton 2014). 

5 Another reason for increased interests on the aquaculture-poverty linkage is that donors have taken an active interest in 
promoting aquaculture.  

6 Ahmed and Lorica (2002) presented a conceptual framework and Toufique and Belton (2014) presented a good summary 
of available studies of the aquaculture-poverty linkages in Bangladesh.  



 

2 

literature also has important methodological weaknesses, as almost all available studies are based on 
nonrepresentative samples. As a result, although these studies provide important insights into selected 
issues, no generalizable conclusions can be drawn from them. Perhaps the most important gap is that none 
of the available studies answer the basic question: to what extent has aquaculture growth contributed to 
poverty reduction?  

This paper attempts to fill these gaps in the literature. In particular, it uses microsimulations to 
analyze the impacts of aquaculture growth on income distribution and poverty in Bangladesh using an 
expanded version of Deaton’s (1989) model and several rounds of nationally representative household 
survey data. The estimates are disaggregated by sex, rural-urban, administrative divisions, and income 
quintile. The rest of the paper is organized as follows: The next section presents an overview of the 
concepts and previous research. Section 3 describes the data and methods used in the paper. Section 4 
presents the key trends in aquaculture production, consumptions, and prices. The results of the welfare 
impacts of real price decline and productivity growth are presented in Section 5. The paper concludes 
with a summary and implications.  



 

3 

2.  CONCEPTS AND PREVIOUS RESEARCH 

The conceptual framework for analyzing the welfare implications of aquaculture growth is no different 
from that for any other economic sector. Following Hirschman’s (1957) work in Latin America, many 
studies have examined linkages between economic sectors. The agricultural growth linkage literature 
made a distinction between direct and indirect effects in terms of improving rural employment and 
household well-being (Johnston and Mellor 1961; Mellor and Lele 1972; Adelman and Morris 1973). 
This literature was a strong force in changing the then-prevailing views—mainly emerging from Latin 
America—that public investment should be directed toward the industrial sector; this view was based on 
the presumption that public investment had greater linkages to the overall economy. The underlying ideas 
of this strand of literature continue to be relevant, as reflected in the recommendations of the World 
Bank’s (2008) World Development Report and de Janvry and Sadoulet’s (2010) studies of China.  

The central premise of the agricultural growth linkage literature is that the growth in agriculture 
resulting from the alleviation of supply constraints—such as technological innovation or infrastructural 
improvement—generates higher multiplier effects (or growth linkages) through increased demand of 
nontradable goods outside of agriculture.7 The existing aquaculture poverty linkage literature diverges 
significantly from this conceptual framework, as is evident in several studies. This paper considers two 
studies to illustrate the conceptual issues and their implications for empirical methods and interpretation 
of results. Ahmed and Lorica (2002; hereafter, AL) argued that adoption of new aquaculture technology 
could affect food security through three distinct pathways: income linkages, employment linkages, and 
consumption linkages. Although it is not obvious from the conceptual framework figure, they also 
suggested that aquaculture technology adoption could have both direct effects (through consumption from 
own production) and indirect effects (through higher income, leading to increased consumption).  

The major weakness of AL’s conceptual framework is that it does not account for the linkages 
between fish and nonfish sectors. The framework also has other ambiguities. For instance, price effects 
and high consumption from own production are listed as two distinct channels of consumption linkages; 
however, it is easy to argue that both channels are linked with income. In addition, consumption from 
own production has opportunity costs; therefore, increased consumption may not be due to own 
production but to higher income from the adoption of new aquaculture technology. Similarly, some of the 
employment linkages (for example, consuming nutrient-rich food and the ability to earn wage income) 
can also fall under income linkages. It is true that increased intake of nutrient-rich food can increase labor 
productivity, which can lead to higher income and to a shift in the demand curve for fish. Therefore, it 
appears that three linkages in AL’s framework are not as distinct, which, from an empirical standpoint, 
means the linkages are not identifiable.  

A recent study by Toufique and Belton (2014; hereafter, TB) extends the AL framework in two 
ways: (1) it provides more nuance to direct and indirect linkages, and (2) it adapts a framework for 
assessing the pro-poorness of aquaculture growth. The study defines the following four linkages: direct 
consumption links (increased consumption from own production), indirect consumption links (increased 
availability and accessibility of fish), direct income links (increased income for aquaculture producers), 
and indirect income links (employment in the fish value chain and consumption linkages).  
  

                                                      
7 To illustrate the point, suppose that (1) a rural economy is divided into two sectors, agriculture and nonagriculture; (2) 

marginal propensity to consume (MPC) is low, at 0.5, for agricultural commodities; and (3) MPC is high, at 0.9, for 
nonagricultural commodities. The second and third assumptions are particularly realistic for poor economies in that a large share 
of incremental income is likely to be spent on nonagricultural goods and services (for example, housing, clothing, education, and 
other nontradables) than on agricultural goods (for example rice and wheat). Given these assumptions, multiplier effects for 
nonagriculture, given by 𝑀𝑀𝑛𝑛𝑎𝑎 = 1

(1−0.9)
= 10, will be five times larger than the multiplier effects of agriculture, given by 𝑀𝑀𝑎𝑎 =

1
(1−0.5)

= 2. This was the key insight of Johnston and Mellor’s (1961) seminal study, as well as of many subsequent studies, on 
the role of agriculture in economic development. 



 

4 

TB’s framework is nicely presented and easier to understand, but like AL’s framework, it limits 
linkages only to the fish sector. Hence, it suffers from some of the same weaknesses. The other 
contribution of TB is that it presents a conceptual framework for assessing whether aquaculture growth is 
pro-poor. Drawing from the pro-poor growth literature proposed in Ravallion (2004, 2009) and Kakwani 
et al. (2004), TB classifies four types of pro-poorness: benchmarked, weakly pro-poor, strong relative 
pro-poor, and strong absolute pro-poor. Growth in aquaculture is defined as benchmarked pro-poor if it is 
associated with an increase in fish consumption by households below the poverty line; weakly pro-poor, 
if fish consumption by the poor increases at a faster rate than in the past; strong relative, if fish 
consumption by the poor increases at a faster rate than by the non-poor; and strong absolute, if the amount 
of fish consumed by the poor is higher than by the non-poor.  

Although TB’s characterization helps illustrate the pro-poorness of aquaculture, it has serious 
pitfalls. The pro-poor economic growth classification is applied to the entire economy, not to any 
particular sector within an economy. More specifically, pro-poor growth literature compares two 
measurable outcomes—growth and poverty—that are identifiable. This is not the case for a given sector, 
as both growth and overall poverty reduction can be influenced by the economy’s other sectors. In 
addition, the key variable in TB’s framework—that is, fish consumption—can also be affected by 
economic factors outside of aquaculture. Not accounting for these conceptual issues has major 
implications for the way results are interpreted. For example, one conclusion in TB states “aquaculture 
has proven unequivocally pro-poor in terms of the ‘indirect consumption’ pathway.” An implicit 
assumption of this conclusion is that the increase in fish consumption resulted from the growth in 
aquaculture alone. This conclusion is flawed, as an increase in fish consumption can be caused by a host 
of other factors, including growth in other sectors and subsectors. In this paper’s assessment, all of the 
available evidence confirms that there has been an increase in fish consumption by all income groups and 
that the real prices have declined due to technological innovation and a rightward shift in the supply 
curve. However, neither of these can be attributed to the growth in aquaculture alone, as there are other 
contributing factors, including years of overall economic growth.  



 

5 

3.  DATA AND METHODS 

Data  
This study uses three rounds of Household Income and Expenditure Survey (HIES), conducted by the 
Bangladesh Bureau of Statistics (BBS) in collaboration with the World Bank. The sampling methods and 
the key results from various rounds of the HIES are presented in HIES reports produced after the 
completion of each round.8 Although this paper uses three rounds of surveys (2000, 2005, 2010) to 
explore trends in aquaculture, the microsimulation analysis is based on the latest round (2010). The 
sampling of this round was based on the Integrated Multipurpose Sample, which consisted of 1,000 
primary sampling units. This unit is defined as two or more contiguous enumeration areas used in the 
2001 Bangladesh census. Following a two-stage stratified random sampling method, a total of 12,240 
households were sampled, of which 7,840 were from rural areas and 4,400 were from urban areas.  

In addition, secondary data from other sources were used. Production data, disaggregated by 
location and sources, were compiled from the Fisheries Yearbook published by the Ministry of Fisheries 
and Livestock. This yearbook is based on the Fisheries Resources Survey System administered by the 
Department of Fisheries (DoF). Historical data on fish prices, disaggregated by location and varieties, and 
on export-import data were also obtained from the DoF. These data were particularly helpful in analyzing 
the trends and triangulating the estimates generated from the HIES data.  

Methodology  
This study employs an expanded version of Deaton’s (1989) model for analyzing the welfare implications 
of food price changes. Since its publication, Deaton’s model has been used to analyze the welfare effects 
of price shocks, most notably following the 2007/2008 global food crisis.9 Theoretically, the model is 
derived from the fact that the welfare impact of price changes can be defined in terms of compensating 
variation (CV), which is defined as the monetary compensation needed to offset the effects of price and 
income changes, leaving household utility at the same level as it was before the changes. Formally, CV 
can be expressed as 

 𝐶𝐶𝐶𝐶 = 𝑒𝑒(𝑝𝑝0𝑐𝑐 ,𝑢𝑢0)− 𝑒𝑒(𝑝𝑝1𝑐𝑐 ,𝑢𝑢0) + 𝜋𝜋�𝑝𝑝1
𝑝𝑝,𝑤𝑤1� − 𝜋𝜋�𝑝𝑝0

𝑝𝑝,𝑤𝑤0� , (1) 

where e(.) is an expenditure function; 𝑝𝑝𝑐𝑐  is a vector of consumer prices; u is the utility that the consumer 
derives from the fish; 𝜋𝜋(. ) is the profit function income-generating activities of the household; 𝑝𝑝𝑝𝑝 is the 
price received for goods and services sold by the household; and w is the price of goods and services that 
a household buys as input into productive activities, including labor and a set of assets that are fixed in the 
short run. The subscripts 0 and 1 refer to times: before and after price changes, respectively. This study 
focuses on aquaculture as the income-generating activity; thus, 𝑝𝑝𝑝𝑝 is the producer price of fish, and w is 
the price of aquaculture inputs. 

With some algebraic manipulations, the welfare implications of price changes can be expressed in 
terms of elasticities: 

𝐶𝐶𝐶𝐶
𝑌𝑌

= ∑ −𝑞𝑞𝑖𝑖0𝑝𝑝𝚤𝚤�𝑁𝑁
𝑖𝑖=1 +  1

2
∑ ∑ 𝜀𝜀𝑖𝑖𝑖𝑖𝑁𝑁

𝑖𝑖=1 𝑝𝑝𝚤𝚤�𝑁𝑁
𝑖𝑖=1 𝑝𝑝𝚥𝚥� +  ∑ 𝑠𝑠𝑖𝑖0𝑀𝑀

𝑖𝑖=1 𝑝𝑝𝚤𝚤
𝑝𝑝� +  1

2
∑ ∑ 𝜃𝜃𝑖𝑖𝑖𝑖𝑀𝑀

𝑖𝑖=1 𝑝𝑝𝚤𝚤�𝑀𝑀
𝑖𝑖=1 𝑝𝑝𝚥𝚥� +

∑ 𝑥𝑥𝑖𝑖0
𝑝𝑝
𝑖𝑖=1 𝑤𝑤𝚤𝚤�  + 1

2
∑ ∑ 𝛾𝛾𝑖𝑖𝑖𝑖𝑃𝑃

𝑖𝑖=1 𝑤𝑤𝚤𝚤�𝑃𝑃
𝑖𝑖=1  𝑤𝑤𝚥𝚥�, (2) 

where 𝑞𝑞𝑖𝑖0 is the budget share of the consumer good i; 𝑠𝑠𝑖𝑖0 is the value of output as a share of income; 𝑥𝑥𝑖𝑖0 
is the value of spending on input I as a proportion of income; 𝜀𝜀𝑖𝑖𝑖𝑖is the absolute value of Hicksian cross-

                                                      
8 The report on the 2010 round of the HIES is available at http://www.bbs.gov.bd/WebTestApplication/userfiles/Image/ 

LatestReports/HIES-10.pdf.  
9 See Ivanic and Martin (2008) for a review. 

http://www.bbs.gov.bd/WebTestApplication/userfiles/Image/LatestReports/HIES-10.pdf
http://www.bbs.gov.bd/WebTestApplication/userfiles/Image/LatestReports/HIES-10.pdf


 

6 

price elasticities between good i and good j; 𝜃𝜃𝑖𝑖𝑖𝑖 is the cross-price elasticity of supply between good I and 
good J; 𝛾𝛾𝑖𝑖𝑖𝑖 is the elasticity of demand for good i with respect to the price of good j; and the “hat” operator 
indicates the proportion of change in the respective variables.  

Deaton’s (1989) model is derived from equation (2) with four simplifying assumptions: (1) these 
is no change—or only negligible change—in input prices, thus eliminating the last two terms on the right 
side of the equation; (2) consumers do not respond to price changes in the short run, thus eliminating the 
second term on the right side; (3) farmers do not respond to price changes in the short run, thus removing 
the fourth term on the right; and (4) changes in consumer and producer prices are proportional, which 
allows for a combination of the first and the third terms on the right. With these simplifying assumptions, 
Deaton (1989) expressed equation (2) as follows:  

 𝐶𝐶𝐶𝐶
𝑌𝑌

= ∑ (𝑠𝑠𝑖𝑖0 − 𝑞𝑞𝑖𝑖0)𝑝𝑝𝚤𝚤�𝑁𝑁
𝑖𝑖=1 , (3) 

where (𝑠𝑠𝑖𝑖0 − 𝑞𝑞𝑖𝑖0) represents the net benefit ratio (NBR), defined as the value of net sales of commodity i 
as a proportion of household income. Equation (3) has been the workhorse in examining the welfare 
implications of price shocks. Following the 2007/2008 global food crisis, several studies used this 
approach to examine the welfare implications of food price increase.10  

In the context of aquaculture in Bangladesh, however, it is important to examine whether these 
simplifying assumptions can have a significant effect on the magnitudes of welfare change. Based on the 
available secondary data, it is evident that the assumption of proportional changes in consumer and 
producer prices does not hold in the case of aquaculture. Similarly, the real price of aquaculture fish in 
Bangladesh has declined over time, implying that supply responded (a rightward shift) to technological 
innovation. In other words, the fourth term in equation (2), representing second order approximation of 
the welfare change, will not be equal to zero.11  

                                                      
10 Notable examples include Ivanic and Martin (2008) and Wodon and Zaman (2010).  
11 Following Minot and Goletti (1998) and Minot and Dewina (2013 and 2015), we conducted sensitivity analysis for 

robustness. These results are available from the authors upon request.  



 

7 

4.  TRENDS IN AQUACULTURE IN BANGLADESH  

Production  
Bangladesh has made remarkable progress in promoting aquaculture. From 1983/1984 to 1992/1993, the 
average annual production of aquaculture fish was only about 178,000 tons; this number jumped to about 
1.3 million tons in the most recent decade (Table 4.1). Production of capture and marine fisheries also 
increased in absolute terms since 1983/1984, but their average shares in total production declined from 53 
to 36 percent and from 26 to 19 percent, respectively. In 2012/2013, the latest year for which data are 
available, total aquaculture production was 1.6 million metric tons, equivalent to 55 percent of the total 
fish production of 3.4 million tons.  

Table 4.1 Trends in fish production in Bangladesh, 1983/1984–2012/2013 

Sources 

Annual average production (metric tons) and production shares  
1983/1984–
1992/1993 

Shares 
(%) 

1993/1994–
2002/2003 

Shares 
(%) 

2003/2004–
2012/2013 

Shares 
(%) 

A. Inland fisheries 
Capture             
River  175,285 20.6 151,561 10.0 140,552 5.1 

Sunder ban 6,852  0.8 9,865 0.6 18,220 0.7 

Beel (lake) 47,397  5.6 67,403 4.4 79,136 2.9 

Kaptai lake 3,714 0.4 6,490 0.4 8,096 0.3 

Flood lands 220,170 25.8  404,291 26.5 728,193 26.4 

Total  453,418 53.2 639,610 42.0 974,197 35.3 
Culture              
Ponds 153,258 18.0 479,867 31.5 1,010,184 36.6 

Semiclose 1,293 0.2 3,277 0.2 5,261 0.2 

Baors/culture -- -- -- -- 107,782 3.9 

Shrimp  23,378 2.7 79,611 5.2 151,610 5.5 

Total  177,929 20.9 562,755 37.0 1,274,837 46.1 
B. Marine fisheries  

Industrial 11,393 1.3 17,411 1.1 42,805 1.5 

Artisanal 210,092 24.6 303,123 19.9 471,245 17.1 

Total  221,485 26.0 320,534 21.0 514,050 18.6 
National total  852,832 100.0 1,522,899 100.0 2,763,084 100.0 

Source:  Based on data compiled by the authors from Fisheries Statistical Year Book of Bangladesh, 1983–2013 (Ministry of 
Fisheries and Livestock various years).  

Of the four subcategories of culture fisheries, pond culture has experienced the fastest growth. 
Average annual pond fish production increased from about 150,000 tons in the 1980s to more than 1.0 
million tons in the past decade, equivalent to about 80 percent of the total culture production of 1.3 
million tons. The growth has been faster in recent years, with production from pond culture jumping from 
750,000 tons in 2007/2008 to 1.45 million tons in 2012/2013. Shrimp production, which receives much 
more attention in policy discussion, increased only by about 65,000 tons during the same period. Another 
new development in aquaculture in Bangladesh is the seasonal production of cultured fish in haors and 
baors (the depressions that get flooded during the monsoon season). The DoF began collecting data on 
seasonal culture fish production in 2009/2010, when it recorded a total production of about 46,000 tons; 



 

8 

this number increased to 201,000 tons by 2012/2013. Thus, this appears to be another growth area for 
Bangladesh aquaculture.  

Exports  
Bangladesh exports seven categories of fish products—frozen shrimp, frozen fish, dry fish, salted fish, 
shark fin, turtle, and others; shrimp is by far the largest export in terms of value and volume. Of the total 
export of 85,000 tons in 2012/2013, more than 50,000 tons (or about 60 percent) was shrimp produced by 
large commercial farmers with the primary objective of exporting. The share of shrimp in the total export 
value was even larger, at 81 percent of the total export of $533 million. By contrast, the total volume of 
frozen fish was only about 11,000 tons, which included not only farm-raised fish but also marine and 
other capture fisheries. Therefore, the actual volume of aquaculture fish export was much smaller than 
11,000 tons, which is less than 1 percent of the 1.3 million tons of cultured fish. These numbers imply 
that the growth in the production of common aquaculture fish varieties is overwhelmingly driven by 
domestic demand. This is a key point because multiplier effects are much larger, in terms of both nutrition 
and income generation, for aquaculture than for other fish subsectors not considered in this study.  

Consumption 
The small volume of nonshrimp aquaculture exports indicates that the growth in production has translated 
into increased consumption at the aggregate level. However, it tells little about the patterns of 
consumption by location, gender, and income groups, which are central to drawing welfare implications. 
To this end, this paper analyzes three rounds of HIES data. The only problem in carrying out this analysis 
is that HIES does not clearly disaggregate nonshrimp aquaculture from other types of fish consumption, 
especially from inland capture fisheries. The authors follow Toufique and Belton’s (2014) strategy of 
categorizing fish into four major groups: (1) primarily aquaculture, (2) inland capture and culture, (3) 
primarily inland capture, and (4) primarily marine. Table 4.2 presents the results of the analysis. The 
aggregate estimates of rural and urban consumption are fairly similar to those in Toufique and Belton 
(2014), though two additional dimensions are added to this analysis—disaggregation by gender and by 
income quintile.  

Three main points can be drawn from the results. First, fish consumption has increased for every 
category of household shown—rural, urban, male, female—as well as for each income quintile. At the 
national level, per capita annual fish consumption increased from 13.4 kg in 2000 to 18.1 kg in 2010, 
implying 35 percent growth over the decade or 3 percent per year. This achievement is remarkable 
because, not too long ago, achieving 18.0 kg per capita annual consumption was a national target and seen 
as a potential for aquaculture growth. This goal is reflected in an FAO (2005) report: “The present per 
capita annual fish consumption in Bangladesh stands at about 14 kg/year against a recommended 
minimum requirement of 18 kg/year; hence there is still need to improve fish consumption in the 
country.” Now that the country has achieved the target, perhaps a different set of questions needs to be 
asked. In particular, policies can now focus on improving distribution across income groups and perhaps 
accessing international markets.  
  



 

9 

Table 4.2 Changes in annual per capita fish consumption (kg/person/yr) in Bangladesh, 2000–2010  

Year Fish sources 
Location  

Sex of the 
household head* Income quintile 

Rural  Urban  Male Female 1st 2nd 3rd 4th Richest All  

20
00

 

Primarily aquaculture 3.4 3.9 3.3 3.5 1.6 2.3 3.0 3.9 6 3.5 
Inland capture and 
culture 4.5 3.8 5.1 4.3 3.2 4.0 4.5 4.8 5.1 4.4 

Primarily inland capture 3.6 3.5 3.6 3.6 2.8 3.6 3.5 4.0 3.9 3.6 
Primarily marine 2.0 3.6 3.0 2.3 0.8 1.3 2.3 3.0 3.6 2.3 
Total  13.6 14.9 15.0 13.7 8.4 11.2 13.3 15.7 18.5 13.4 

20
05

 

Primarily aquaculture 5.5 6.2 6.5 5.6 3.2 4.0 4.8 6.3 8.7 5.7 
Inland capture and 
culture 5.1 4.6 5.7 4.9 4.6 4.5 4.7 5.1 5.5 4.9 

Primarily inland capture 2.7 3.4 2.8 2.9 2.3 2.4 2.7 3.1 3.4 2.9 
Primarily marine 1.5 4.1 2.5 2.1 1.3 1.6 2.0 2.2 3.1 2.1 
Total  14.7 18.3 17.5 15.5 11.4 12.4 14.2 16.8 20.8 15.6 

20
10

 

Primarily aquaculture 7.5 7.8 8.2 7.5 5.3 6.2 6.7 8.5 10 7.5 
Inland capture and 
culture 5.3 6.4 6.4 5.5 4.7 4.9 5.3 5.9 6.7 5.6 

Primarily inland capture 2.4 3.2 2.9 2.6 2.0 2.2 2.5 2.8 3.3 2.6 
Primarily marine 1.6 4.5 2.8 2.3 1.3 1.4 1.9 2.7 4.0 2.4 
Total  16.7 21.9 20.2 17.8 13.2 14.6 16.4 19.8 23.9 18.1 

Change since 2000 (%) 23.8 46.9 34.7 29.9 57.1 30.4 23.3 26.1 29.2 35.1 
Source:  Authors’ calculations from HIES rounds 2000, 2005, 2010 (BBS 2010).  
Note:  * The differences between mean consumptions are statistically significant. 

Second, in relative terms, households in the bottom two income quintiles experienced the fastest 
growth in fish consumption between 2000 and 2010. The poorest households increased their consumption 
by more than 57 percent, which is larger than any other income groups in Table 4.2. This finding is 
consistent with studies that suggest that both price and income elasticity of demand for fish are higher (in 
absolute value) for the poor than for richer households (Dey, Alam, and Bose 2010).  

Finally, the results show that levels of fish consumption are diverging between urban and rural 
households. In 2000, per capita consumption in urban households was 14.9 kg, which was only about 10 
percent higher than consumption by rural households. In 2010, per capita annual consumption by urban 
households jumped to almost 22.0 kg, which is about 31 percent higher than for rural households.  

Price Trends 
Since the main way that the boom in Bangladeshi aquaculture helps nonproducers is through the price 
effect, it is important to explore trends in fish prices over this period. Estimates from the HIES data 
suggest that fish prices declined between 2000 and 2005 but increased again in 2010. The HIES data refer 
to unit values, not prices per se, and may be influenced by seasonality and changes in quality.  

More reliable data are collected by the DoF on a regular basis in multiple markets. Figure 4.1 
presents price trends of a few popular varieties, along with three point estimates from the HIES data. 
Except for Hilsha, which is primarily a marine fish, all prices have been declining in real terms since 
2002, which is consistent with growth of aquaculture.12 For instance, commercial production of nonnative 
pangusius catfish began in Mymensingh in 1993 (Belton et al. 2012), and DoF began collecting high-
frequency price data for pangusius and other cultured fish only in the early 2000s. The prices of both 
pangusius and smaller carps, two main varieties of culture fish, have been declining ever since DoF began 

                                                      
12 Hilsha is primarily a marine fish from the shad family. In monsoon, they swim toward the upstream rivers, like the Padma. 

The fish are caught at both the Bay of Bengal and the large river. This popular fish in Bengal has a rapidly growing market in the 
countries of Europe, the Middle East, and North America, where there are Bengali immigrants or migrants.  



 

10 

recording prices in early 2000s. Finally, real prices of all fish varieties, both inland and marine, were 
increasing rapidly in the 1980s, which was when the Green Revolution was taking root, rice prices were 
falling, and the economy was enjoying overall growth. 

Figure 4.1 Real prices (2010 = 100) of selected fish varieties in Bangladesh, 1986–2014 

 
Source:  Authors’ construction based on DoF price series and HIES data (BBS 2010).  

This last point was the subject of much debate in the 1990s. One set of studies argued that income 
growth was not sufficient to improve nutrition (see, for example, Behrman and Deolalikar 1987; Bouis 
and Haddad 1992); another strand refuted it (see, for example, Subramanian and Deaton 1996). A 
recurrent observation at the time was that although the Green Revolution resulted in declining rice prices, 
prices of other food items, such as pulses, vegetables, fish, and animal products, were increasing around 
the same time. For instance, Bouis (2000) reported that although rice prices in selected Asian countries 
declined by 40 percent, the real prices of pulses, vegetables, and animal products had increased 25–50 
percent since the onset of the Green Revolution. Figure 4.1 demonstrates that this is no longer a concern 
in Bangladesh, at least in the case of fish; real prices have been declining for all fish varieties, except 
marine fish, which is largely consumed by the rich and middle-income groups.  

The empirical evidence presented suggests that demand has increased with population growth and 
higher incomes, but supply has increased even more rapidly, resulting in a decline in real price. Because 
Bangladesh has experienced sustained economic growth, and because aquaculture is a small part of the 
country’s overall economy, it is safe to assume that the shift in demand curve has resulted mainly from 
overall growth, not aquaculture per se. Given that aquaculture’s share in gross domestic product is small, 
its contribution to the shift in demand should also be relatively small, suggesting that the shift in the 
supply curve has been the main channel through which aquaculture has contributed to welfare. This is the 
point of departure of our analysis.  

Big Ruhu 

Big Katla 



 

11 

5.  WELFARE IMPLICATIONS OF AQUACULTURE GROWTH  

Market Positions and Net Benefit Ratios  
Based on data from the 2000 HIES survey, Table 5.1 shows descriptive statistics for the NBR of 
aquaculture for various types of households in Bangladesh. The first column indicates the proportion of 
all households in that category. The next three columns show the average production ratio (si0 in equation 
(1)), the average consumption ratio (qi0 in equation (1)), and the average net benefit ratio (si0 – qi0), 
respectively. The last three columns present the share of households in that category that are net sellers, 
autarkic (neither buying nor selling), or net buyers. The results are disaggregated by household location 
(rural or urban), administrative division, the sex of the household head, fishing practices, and income 
quintile.  

Table 5.1 Net positions of households in aquaculture fish in Bangladesh 

Household 
category 

Percentage 
of all 

households 

Production 
ratio 

Consumption 
ratio 

Net benefit 
ratio 

Net 
seller Autarky 

Net 
buyer 

% of total  
income 

% of households in  
each category 

Location        
Rural 80 2.51 3.90 -1.38 9.1 13.2 77.6 
Urban 20 0.32 3.27 -2.96 1.2 10.4 88.4 

Sex of head        
Male 91 2.21 3.80 -1.59 8.0 11.9 80.1 
Female 9 0.61 3.48 -2.86 2.5 20.1 77.5 

Regional        
Barisal 7 1.99 2.09 -0.10 9.7 34.5 55.8 
Chittagong 23 1.77 4.37 -2.60 5.4 12.8 81.8 
Dhaka 33 1.78 3.87 -2.09 6.9 8.6 84.6 
Khulna 12 5.38 3.74 1.64 14.0 11.6 74.5 
Rajshahi 25 1.18 3.54 -2.36 6.7 12.5 80.8 

Occupation        
Fish farmer 23 9.06 4.94 4.12 32.9 9.2 57.9 
Other 77 -- 3.42 -3.42 -- 13.7 86.3 

Income quintile        
Poorest 20 1.52 3.15 -1.63 4.7 21.4 73.9 
2nd 20 2.21 3.67 -1.45 8.1 15.1 76.8 
3rd 20 2.35 4.16 -1.81 8.6 11.8 79.7 
4th 20 2.61 4.10 -1.49 9.5 10.4 80.1 
Richest 20 1.65 3.78 -2.13 6.7 4.6 88.6 

National 100 2.07 3.77 -1.70 7.5 12.7 79.8 
Source:  Authors’ calculation based on HIES 2000 (BBS 2001).  

Starting with the national estimates (the last row of the table), aquaculture production accounts 
for 2.07 percent of income,13 while aquaculture consumption represents 3.77 percent of income, giving an 
NBR of –1.7 percent. This means that a 10 percent increase in aquaculture prices would result in a 0.17 
percent decrease in income for Bangladeshi households. The last three columns of the last row indicate 
that about 80.0 percent of households are net buyers, 12.7 percent are autarkic, and about 7.5 percent are 

                                                      
13 Throughout this analysis, total household consumption expenditure is used as a proxy for income because income is 

subject to more measurement error.  



 

12 

net sellers. Putting it differently, only 7 percent of Bengali households are aquaculture farmers, and they 
supply aquaculture products to the rest of the population.  

A couple of other results are worth highlighting. First, estimated NBRs are positive only for fish 
farmers and for households in the Khulna division, implying that these two groups will gain from an 
increase in aquaculture prices and lose from a decline in prices, at least in the short run. For fish farmers, 
a positive NBR is obvious. For Khulna, the largest fish-producing region in the country, a positive NBR 
means that the gains from a price increase to producers will outweigh the losses to consumers. Second, 
among the household categories with negative NBRs, the estimates vary, from as low as –3.42 for 
nonfarmers to as high as –0.10 percent in Barisal. This implies that the impacts of an increase (decrease) 
in aquaculture fish prices will be felt differently depending on the household categories. For instance, 
urban households would benefit more, on average, from a price decline than would rural households. 
However, the magnitude of welfare gain (loss) due to a decrease (increase) in fish prices is small. A 
doubling of fish prices would lead to only about a 3 percent decline in the welfare of urban households. 
The same argument goes for male-headed households.  

Impacts of Aquaculture Growth on Income Distribution  
To estimate the distributional impact of aquaculture growth, this paper uses the information on production 
and consumption from the 2000 HIES, as well as estimates for four parameters—the growth in 
aquaculture production, changes in consumer and producer prices, the price elasticity of demand for fish, 
and the supply responses for long-run estimates. A few points about the model calibration need to be 
clarified. First, available estimates of price elasticity of demand for aquaculture vary widely. The absolute 
values of recent estimates, presented in Dey, Alam, and Paraguas (2011), range from 0.10 for Indian carp 
to 0.94 for tilapia. For live fish, which include major aquaculture fish like pangusius, the absolute value of 
price elasticity is 0.75.14  

Second, due to the limitations of using unit values from the HIES data, price changes between 
2000 and 2010 are taken from DoF estimates. The Dhaka price is used, as it reflects changes in consumer 
prices, and the Khulna price is taken to reflect trends in producer prices. The logic behind this choice is 
simple: Dhaka is the largest metropolitan city, and Khulna is the largest producer of aquaculture fish. 
Third, the simulation was carried out on 2010 survey data, with 2000 as the reference round. This 
consideration is primarily driven by the fact that aquaculture experienced the fastest growth in this period, 
as discussed in the previous section. Finally, to calculate the long-run effects—that is, to account for both 
price and supply changes—the aquaculture production estimates published by the DoF are used.  

Based on this background, we present two sets of results—one showing the impacts on income 
distribution and the other showing the impacts on poverty reduction. Table 5.2 presents the results of the 
impacts on income distribution. Similar to Table 5.1, results are disaggregated by location, gender of the 
household head, and income quintile. Both short- and long-run impacts of aquaculture growth have been 
analyzed. The short-run analysis is based on the assumption that there is no supply response or technical 
changes, so that household welfare is influenced only through price change. The long-run estimates 
account for household responses to price changes and technological change. In other words, these two 
types of estimates account for both price and quantity effects, which is more pertinent in the context of 
Bangladesh, as aquaculture fish prices consistently declined while production grew over the past several 
years. 
  

                                                      
14 Analyses have also been carried out with other elasticity assumptions, but the results remain very similar. These results are 

available from the authors upon request. 



 

13 

Table 5.2 Impacts of aquaculture growth on household’s income 

Household 
category 

Baseline 
expenditure 

(Taka/capita/ year) 
Short-run 

price effect 

Long-run effect 

Only price 
effect  

Price and 
quantity effect 

on fishers 

Price and quantity 
effect on all 
household 

  (% change in income) 
Location      

Rural 11,394 0.77 1.09 5.36 2.87 
Urban 17,003 1.32 1.53 5.19 1.75 

Sex of head      
Male 12,475 0.84 1.15 5.41 2.68 
Female 13,186 1.40 1.64 3.99 2.07 

Regional      
Barisal 11,380 0.05 0.26 3.70 1.88 
Chittagong 12,685 1.23 1.56 6.13 2.87 
Dhaka 13,886 1.02 1.32 5.80 2.57 
Khulna 12,563 -0.28 0.13 7.45 3.69 
Rajshahi 10,822 1.11 1.37 3.60 2.19 

Occupation      
Fish farmer 12,418 -1.13 -0.54 5.36 5.36 
Other 12,553 1.54 1.75 - 1.75 

Income 
quintile      

Poorest 5,774 0.84 1.08 4.65 2.08 
2nd 8,002 0.96 1.25 5.25 2.53 
3rd 10,107 0.98 1.31 5.43 2.83 
4th 13,382 0.76 1.11 5.72 3.06 
Richest 25,339 0.85 1.16 5.56 2.73 

National 12,519 0.88 1.18 5.36 2.65 
Source:  Authors’ analysis based on HIES 2000 and 2010 rounds (BBS 2001; 2010). 
Notes:  The data are based on the following assumptions: 1. Consumer and producer prices decline by 45 and 36 percent, 

respectively. 2. Growth in production is 104 percent. 3. Demand and supply elasticity estimates are –0.6 and 0.5, 
respectively. 

The estimates of the short-run impacts, presented in the third column of Table 5.2, suggest that 
price decline by itself has been welfare enhancing for all groups of households, except for Khulna and for 
fish-farming households. Starting at the national level, the short-run impacts (the third column in the last 
row) show an increase in real income by 1.0 percent. However, nonfish farmers, representing 77 percent 
of the Bangladeshi population, gain about 1.5 percent from the decline in aquaculture fish prices. Fish 
farmers lose because supply is assumed to be fixed in the short run; thus, a decline in prices reduces their 
revenues. Although very small in magnitudes, Khulna as a whole loses as well, which suggests that the 
reduction in revenue due to a fall in prices outweighs the gain by consumers in the division. This finding 
is consistent with the fact that Khulna is the largest producer of aquaculture fish.  

In the long run, the welfare implications reverse for some household categories. Urban 
households benefit relatively more in the short run, though this trend reverses in the long run. The 
explanation for this trend reversal is simple: in the long run, rural households benefit from both an 
increase in production and a decrease in prices. The regional-level estimates are also consistent with a 
priori information about aquaculture in Bangladesh. For instance, in the short run, Khulna is negatively 
affected by a price decline (–0.18 percent), and Chittagong reaps the most benefits (1.56 percent). 
However, when production growth is factored in, Khulna becomes the biggest winner in terms of income 
gains. The same goes for fish farmers, as they gain the most in the long run. Overall, aquaculture growth 
contributed to about a 2.6 percent increase in income.  



 

14 

Impacts of Aquaculture Growth on Poverty  
Between 2000 and 2010, production of aquaculture fish (excluding shrimp) has more than doubled, and 
the real prices of major varieties of aquaculture at the retail and farm-gate level declined by 45 percent 
and 36 percent, respectively. This section presents an analysis of how these changes are translated into 
poverty reduction. We begin by estimating the baseline poverty rate by household categories using 2000 
HIES. The national poverty rate in 2000 was 48.8 percent; rural and urban poverty rates were 52.0 and 
35.0 percent, respectively. So, the estimates are very close to the ones presented in World Bank (2013) 
and the government’s figures based on the HIES data (BBS 2010).  

The first set of simulations assesses how the poverty rates decline in the short run following a 
reduction in the real price of aquaculture products. Two points should be highlighted from these results. 
First, the magnitude of overall reduction in poverty due to price change is small: a 45 percent decline in 
the retail price leads to less than 1 percent (0.77 percent) decline in poverty. This finding is not surprising 
in that, on average, aquaculture products account for less than 4 percent of the household budget. Second, 
a decline in price does not reduce poverty rates among the bottom two quintiles of households. This does 
not mean that those households do not gain from price decline; rather, it means that the gains are not large 
enough to pull those households out of poverty. To some extent, these results are similar to those of 
Belton and Little (2011), who argued that aquaculture is unlikely to benefit the poorest through own 
production and increased consumption, though they may benefit through employment in the sector. 
Finally, poverty among fish-farming households increases by 0.56 percentage points in the short run, 
which implies that fish-farming households just above the poverty line could slip into poverty when only 
price decline is considered. However, this simulation does not account for productivity gains and the 
second-round effects specified in equation (2).  

The long-run estimates are presented in the last three columns of Table 5.3. The first of these 
three columns reports the long-run effects of a decline in prices, taking into account household response; 
the second column shows the joint impact of price decline and productivity growth on fish-farming 
households only; and the final column presents the long-run impacts on all households. Four general 
conclusions can be drawn from these long-run results. First, the long-run poverty impacts are much larger 
than the short-run impacts. The impact of price decline on poverty in the long run is 1.08 percentage 
points, which is about 40 percent larger than the short-run impacts. Second, households in the third 
income quintile benefit the most. The magnitudes of poverty reduction are as high as 16.7 percent if only 
fish-farming households are considered; they are almost 10 percentage points if all households are 
considered. Third, among the other household categories, poverty reduction is greatest among fish-
farming households (3.97 percent), followed by households in Khulna (3.24 percent) and Barisal (2.6 
percent). However, the impacts are also substantial for other divisions. The final points to highlight are 
that overall impacts on households in the poorest two quintiles are modest (less than 0.4 percent) and that 
there is no change in the richest two quintiles.  
  



 

15 

Table 5.3 Impacts of aquaculture growth on poverty reduction 

Household 
category 

Baseline 
poverty rate 

(%) 
Short-run 

price effect 

Long-run effect 

Price  
effects 

Price and 
quantity effect 

on fishers  

Price and quantity 
effect on all 
households 

    (percentage point change in poverty) 
Location            

Rural  52 -0.84 -1.15 -4.02 -2.35 
Urban 35 -0.50 -0.81 -2.35 -0.89 

Sex of head            
Male  49 -0.71 -1.04 -4.11 -2.08 
Female  47 -1.71 -1.71 0.00 -1.71 

Regional            
Barisal 53 -0.98 -1.15 -4.72 -2.60 
Chittagong 45 -0.74 -1.20 -4.42 -2.01 
Dhaka 46 -0.70 -0.99 -4.09 -1.80 
Khulna 45 -0.47 -0.59 -4.59 -3.24 
Rajshahi 57 -1.00 -1.31 -2.73 -1.71 

Occupation           
Fish farmers  44 0.56 -0.03 -3.97 -3.97 
Others  50 -1.21 -1.43 - -1.49 

Income 
quintile            
Poorest 100 0.00 0.00 -0.53 -0.11 
2nd 100 0.00 0.00 -1.63 -0.36 
3rd 44 -4.33 -5.88 -16.71 -9.83 
4th 0 0.27 0.27 0.00 0.00 
Richest 0 0.21 0.21 0.00 0.00 
National 49 -0.77 -1.08 -3.97 -2.06 

Source:  Authors’ analysis based on HIES 2000 (BBS 2001). 
Notes:  This set of simulations is based on the following assumptions: 1. Consumer and producer prices decline by 45 and 36 

percent, respectively. 2. Growth in production is 104 percent. 3. Demand and supply elasticity estimates are –0.6 and 
0.5, respectively. 

To summarize, the all-inclusive long-run results suggest that, at the aggregate level, the growth of 
aquaculture in Bangladesh between 2000 and 2010 was responsible for a 2.72 percent increase in real 
incomes and a 2.06 percent reduction in poverty. Official statistics show that overall poverty in the 
country declined from 48.9 percent to 31.5 percent during the same period, for a decrease of 17.4 
percentage points. This implies that about 12 percent (2.06/17.4) of the overall reduction in poverty can 
be attributed to the growth in aquaculture during 2000–2010.  



 

16 

6.  SUMMARY AND IMPLICATIONS  

Defying many earlier predictions, global fish production has grown faster than the world’s population in 
the past couple of decades. Aquaculture has been the biggest contributor to this growth, with its share in 
total fish production rising from about 16 percent in 1990 to more than 50 percent in 2012. This 
remarkable transformation has important implications for food security, poverty, and environment, 
especially for developing countries of Asia. This paper contributes to that literature by clarifying some 
conceptual issues and presenting the quantitative evidence on the income and poverty impacts of 
aquaculture growth in Bangladesh.  

Conceptually, the aquaculture-poverty linkage literature closely resembles agricultural growth 
linkage literature. Evolved in the 1960s, the agricultural growth linkage literature demonstrated that, in 
addition to its direct benefits, agriculture generates multiplier effects through increased demand of 
nontradable goods outside of agriculture. The existing studies on aquaculture’s linkage to poverty and 
income distribution appear to miss this impact channel, however, as they focus only on aquaculture and 
ignore links to other sectors. The existing empirical literature has two important gaps—problems of 
generalizability of results and the quantification of income and poverty impacts. Because most of the 
studies are based on nonrepresentative samples, their conclusions cannot be generalized, even though they 
offer useful insights into the process. Perhaps the most important gap in the literature is that previous 
studies did not estimate the degree to which aquaculture has contributed to income growth and poverty 
reduction. This paper addresses both of these gaps by estimating the income and poverty impacts using 
nationally representative household survey data from Bangladesh, a country that has been very successful 
in promoting aquaculture and reducing poverty since the early 2000s.  

The results of this study suggest that the impacts of aquaculture growth on income distribution 
and poverty reduction in Bangladesh have been substantial, even though the impacts on households in the 
bottom income quintile have been modest. Estimates of aquaculture’s contribution to income growth 
between 2000 and 2010 range from 0.88 percentage points in the short run (only price effects) to about 
2.72 percentage points in the long run (price and quantity effects). The corresponding estimates for 
poverty reduction are 0.77 and 2.06 percentage points, respectively. Although these estimates seem small, 
they represent a substantial share of overall poverty reduction between 2000 and 2010. For instance, 
national headcount poverty rates declined from 48.9 percent in 2000 to 31.5 percent in 2010 (World Bank 
2013). This implies that the growth in aquaculture has been responsible for almost 12 percent of the 
overall poverty reduction in Bangladesh during the first decade of the 21st century. Put differently, of the 
18 million Bengalis who escaped poverty during 2000–2010, more than 2 million of them managed to do 
so because of aquaculture.  

Although these are impressive numbers, this is only part of the story. More analysis is needed to 
better understand the true benefits and costs of promoting a “blue revolution” strategy. First, a general 
equilibrium analysis could incorporate additional impact channels, such as through wage rates, which 
would likely generate higher estimates for the daily wage worker who belongs to the bottom income 
quintile. Second, it would be useful to explore the nutritional impact of the expansion of aquaculture in 
Bangladesh through both changes in income and the reduced price of fish and other aquaculture products. 
Finally, the environmental impact of the “blue revolution” needs to be incorporated into the analysis, 
raising difficult questions regarding the quantification of costs.  
   



 

17 

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	Abstract
	Acknowledgments
	1.  Introduction
	2.  Concepts and Previous Research
	3.  Data and Methods
	Data
	Methodology

	4.  Trends in Aquaculture in Bangladesh
	Production
	Exports
	Consumption
	Price Trends

	5.  Welfare Implications of Aquaculture Growth
	Market Positions and Net Benefit Ratios
	Impacts of Aquaculture Growth on Income Distribution
	Impacts of Aquaculture Growth on Poverty

	6.  Summary and Implications
	References
	RECENT IFPRI DISCUSSION PAPERS