Krishen Rana and Anton Immink
Fishery Information, Data and Statistics Service (FIDI)
Preamble
As we move into the next millennium finfish and other aquatic products will be in greater short supply as domestic and international demand for both high and low valued species increases due to rising populations, living standards and disposable incomes. With globally dwindling yields from many traditional marine and inland capture fisheries, shortfalls in supply of aquatic products will largely need to be met from culture through increased utilisation and output of current and hitherto uncultured species. The issues and challenges we therefore face in aquaculture particularly, are how to: (i) promote aquaculture as a legitimate, long term farming activity and (ii) sustain and increase the current utilisation of species and production base. As well as increased technical assistance, achievements in both the private as well the public sector will largely depend on positive national policies that promote the sector and also integrate, and give high priority to, the collection of necessary and relevant information on which to make informed decisions.
The potential of aquaculture to meet the challenges of food security and to generate employment and foreign exchange is clearly demonstrated by the rapid expansion of this sector, which has grown at an average annual rate of almost 10% since 1984 compared with 3% for livestock meat and 1.6% for capture fisheries production.
What have the major production achievements from aquaculture been in the last few years?
In this commentary, the recent production of the major cultured species and the key features of recent developments in aquaculture production are reviewed to provide an overall perspective, based largely on data provided by countries to FAO.
Recent Changes to FAO Aquaculture Database and Reporting of Statistics.
Before considering recent production trends in aquaculture, it may be of value to point out recent changes to the FAO aquaculture database. From 1998, the FAO Fisheries Yearbook of Catches will contain only inland and marine capture fisheries data and the Fisheries Circular no. 815 (Aquaculture Production Statistics), which will continue to use the same species classification, will contain aquaculture production and value statistics. The electronic provision of these databases will now be through a new Windows-based programme called ‘Fishstat +’. This new programme contains separate datasets for each part of the database, but they can all be run through one programme. The main global datasets available at present are: aquaculture production 1984 – 1996, by quantity; aquaculture production 1984 – 1996, by value; capture fisheries 1984 – 1996, by quantity; total fisheries production 1950 – 1996, by quantity; and trade and production 1976 – 1997.
The global aquaculture production statistics reported for 1984 – 1996 are noticeably higher than those between 1984 – 1995. This was due to underreporting of Chinese aquaculture production statistics. It has recently come to light that China has been reporting production statistics of three molluscs species; the blood cockle, Japanese carpet shell, Pacific cupped oyster and unclassified marine molluscs to FAO as shelled or shucked weight. Consequently, to date, the contribution of:
have been understated. This year FAO, in consultation with the Chinese Ministry of Agriculture, has adjusted the Chinese and global aquaculture production time series statistics and reflects these adjustments in its databases, and subsequent analysis.
The general reporting and classification of species in the various culture environments has also been reviewed in recent years and one major consequence of this is the apparent increase in aquaculture production in brackish water environments. Although there was some increase in production, mainly of penaeid shrimps, the bulk of the increase reflected in the 1984 – 1996 statistics for total production from brackish environments was due to the transfer of P. vannamei production from the marine to brackish water environments.
The Contribution of Aquaculture to Total Aquatic Production
Aquatic production (including plants) has steadily increased since 1984 and in 1996 total world production of finfish and shellfish from capture fisheries and aquaculture reached 120.3 million tonnes. The addition of plants raises the total production reported in 1996 by a further 8.8 million tonnes (t) to 129.1 million t, an increase of around 26 million t since 1990 (Figure 1).
Figure 1
A significant proportion
of this increased production was of cultured origin. For cultured finfish
and shellfish the annual contribution to total finfish and shellfish production
rose from 13% in 1990 to 22% in 1996 (Figure 1).
The corresponding annual contribution of total aquaculture including plants
to total aquatic production was higher and increased from to 16% to 26% for
the same period. For food fish (fish destined for human consumption), over
a quarter of total world supply was derived from aquaculture.
Global and Continental Production of Aquaculture
Figure 2
Aquaculture represents one of the fastest growing food producing sectors,
providing a product that is an acceptable supplement and substitute to wild
fish and plants. By 1996, the total production of cultured finfish, shellfish
and aquatic plants reached 34.12 million t which was valued at US$46.5 thousand
million (billion). This represents an increase of around 11.0% and 6.2% over
1995 quantity and value, respectively (Figure 2).
In keeping with recent trends, the increase over 1995 was higher for finfish
and shellfish than for all aquatic organisms, an average of 13.6% and 7.4%
for quantity and value, respectively. Much of the reported increase originated
from the Low-Income Food-Deficit Countries (LIFDCs), in particular China.
Greater allocation of natural resources for aquaculture, particularly pond
and sea area in China, development and implementation of national aquaculture
frameworks and holistic management to further diversify production of species
and technology used continues to support further increases.
Figure 3 |
National Importance of Aquaculture to Total Aquatic Production in Principal Countries
Figure 4
The average global contribution of aquaculture masks the relative importance
of aquaculture to national aquatic production. The contribution of aquaculture
to total aquatic production varied and ranged from 14% to 62% for the top
14 producing (Figure 4).
In 1996, Chinese aquaculture accounted for 62% of total national aquatic
production, nearly twice that of either Italy, Philippines, India, France
or Bangladesh (Figure 4). A considerably lower
contribution to national aquatic production was reported for similar activities
by Thailand (14%) and Indonesia
(17%) (Figure 4) -
inset), United Kingdom
(11%), Norway (10%) and USA (7.0%) in 1996.
Main Producers
Figure 5
Global production of aquaculture continues to be dominated by China, which
in 1996 accounted for over 67.8% of world output (Figure
5). Because of the relatively
low value of carps and seaweeds ,
that dominate Chinese culture, itscontribution to the
value of world aquaculture was lower than its contribution to quantity
at 45.4% (Figure 5). The global ranking of countries
to quantity and value varied depending on the predominance of the culture
of high value species (Figure 5). Although Japan
accounted for 4% of total world quantity ,
the culture of predominately high value marine finfish species such as the
amberjack and shellfish such as the yesso scallop and oyster, more than doubled
its world share in terms of value and made it the second largest global contributor.
Similarly, the higher valued penaeid shrimps in Indonesia and Thailand and
salmonids in Norway approximately doubled their proportional value contribution
to global production when compared with their reported tonnage (Figure
5).
Aquaculture Production in LIFDCs
Although a few developed countries such as Japan and USA feature amongst top producers (Figure 5), aquaculture production is predominately an activity in the Low Income-Food Deficit Countries (LIFDCs; (Figure 6), which in turn are greatly influenced by developments in China.
Figure 6
By 1996, 27.9 million tonnes, or around 82% of world total finfish, shellfish
and aquatic plant production through aquaculture originated from LIFDCs and
represented an increase of 3.4 million tonnes over 1995. The contribution
of LIFDCs to world production has increased sharply since 1990 (Figure
6). The average expansion rate of the aquaculture sector within LIFDCs
(16.7%) between 1990 and 1996 was nearly six times faster than that for non-LIFDCs
(2.9%). The high average growth rate within the LIFDCs, however, is highly
influenced by Chinese production and this distorts development trends in other
LIFDCs.
Figure 7 |
Aquaculture Production in the Former USSR Region
Figure 8
The aquaculture production statistics reported for the former USSR region
were revised in 1998 and consequently the time series reported for the period
1988–1996 is different from that reported in 1997 for 1988–1995. Conditions
related to the transition to a free economy continue to adversely affect aquaculture
development and the reporting of statistics. Since 1990 total aquaculture
production has continued to decline in all countries, with output falling
at an average rate of 21%/yr between 1990 – 1996. In 1996, 104 000 tonnes, valued at US$ 270 million
, were reported for the
region (Figure 8) and accounted for 0.3 and 0.5%
of world output in terms of tonnage and value, respectively. The rate of decline
varied between the former USSR countries by a factor of four. Between 1990-1996
Armenia reported a 13% decline in aquacultural output compared with 47% from
Tajikistan. Aquaculture production within the former USSR area continues to
be dominated by the Russian Federation (53 000 tonnes) and Ukraine (33 000)
which between them accounted for 83% of total production in 1996. Although
there is continued interest in sturgeon and mussel culture, in the Russian
Federation much of the present production is based on freshwater carp aquaculture.
The culture of silver carp and in particular common carp (68% of total carps)
was the main aquacultural activity accounting for 89% of total aquaculture
production in 1996.
Reported Use of Culture Environments for Aquaculture Production
Although lower in value, output from freshwater environments, in terms of quantity, expanded at an average rate of 12%/yr between 1990 and 1996, whilst its contribution to total world aquaculture production decreased from 47 to 44%, respectively.
The expansion rate, in terms of quantity, for aquaculture production derived from the brackishwater environment was one third that of the freshwater environment, and the contribution to world aquaculture production decreased from 8% to 5% for the same period. The higher value of products, mainly shrimps, however, resulted in production from the brackishwater environment accounting for a greater share of the total world value (16%) in 1996.Figure 9
In contrast, output from
the marine environment expanded at 15%/yr and in 1996 accounted for 51% of
total world aquaculture output. Although the proportion of total aquaculture
production by weight and value originating from marine waters in 1996 is high
(17.5 million metric tonnes) over 90% of mariculture production is still centred
around primary users of nutrients (i.e., aquatic plants and filter feeding
invertebrates) and only 7% for mainly carnivorous finfish species. Moreover,
when aquatic plants are excluded from the marine environment total, around
86% of the contribution to total finfish and shellfish production originates
from filter -feeders such
as mussels, scallops and cockles. In addition to total aquaculture production
from the marine environment generating over US$19.6 billion in 1996, the predominant
use of plants and filter-feeders in mariculture may also contribute to minimising
the levels of nutrient enrichment of coastal waters resulting from human activities.
Major Reported Culture Groups and Species of Aquatic Organisms
The contribution of major culture groups to aquaculture production in 1996 was similar to that of 1995. Production of finfishes continues to be the dominant global aquaculture activity in 1996, accounting for about 49% by weight and 55% by value (Figure 10).The higher unit-value of shrimps, salmonids, bass and breams resulted in the crustaceans, diadramous and marine fishes accounting for a greater share in total value than their share of production (Figure 10).
Figure 10 |
Recent Developments of Reported Production of Cultured Species and Species Groups
The highest reported global production of any cultured aquatic organism for 1996 was the kelp, Laminaria japonica, totalling just over 4 million tonnes (Table 1). Moreover, two of the top ten species or species groups produced are plants.
Table 1. Reported World Production of the Top Ten Species or Species Groups in 1996
Common name |
Species name |
Production (tonnes x 106) |
Kelp |
Laminaria japonica |
4.17 |
Pacific cupped oyster |
Crassostrea gigas |
2.92 |
Silver carp |
Hypophthalmichthys molitrix |
2.88 |
Grass carp |
Ctenopharyngodon idellus |
2.44 |
Common carp |
Cyprinus carpio |
1.99 |
Unclassified freshwater fishes |
Osteichthyes |
1.59 |
Algae |
Aquatic plants nei |
1.42 |
Bighead carp |
Hypophthalmichthys nobilis |
1.41 |
Yesso scallop |
Pecten yessoensis |
1.27 |
Mollusca |
Marine molluscs nei |
1.20 |
All the above species for 1996 and those of the top 10 over the last decade, represent organisms low in the food web or chain, i.e. they are either filter feeders, plants or finfish which are considered herbivores and omnivores (Figure 11).
The ranking of the top species changed over the last year, but this was largely due to adjustment to Chinese statistics that resulted in an increase in the tonnage of the Pacific oyster. Although highest in value, the production of shrimps and prawns, in terms of tonnage do not feature in the top 10 species. The major species of cultured shrimp, Penaeus monodon, was ranked 17th in 1996 and the production of P. vannamei, and P. chinensis, which are predominantly cultured in Ecuador and China, respectively, were ranked 37th and 42nd.
The Reporting of Incompletely Identified Production
Figure 11 |