1. IntroductionThe largest segment

1. Introduction
The largest segment of United States (U.S.) aquaculture is the
production of Ictalurid catfish. In 2008, 232,000 tonnes of food size
channel catfish, Ictalurus punctatus, were produced with an estimated
value of $410 million (USDA, 2009). About 92% of total U.S.
sales were produced in Mississippi, Alabama, Arkansas, and Texas.
Additionally in 2008, 1617 catfish operations existed in the U.S.
with a total of 66,005-water ha (USDA, 2009). As of January 2009,
only 1306 of the original farms still operated on a total of 59,450-
water ha with a reduction of 19.2% in farms and 9.9% in area.
Channel catfish farming also is the most important aquaculture
sector in Alabama. In 2008, there were 252 farms in Alabama
that utilized 8984-water ha and produced 59,693 tonnes of catfish
(USDA, 2009). The economic impact on Alabama is substantial with
approximately 3000 Alabamians engaged directly in the catfish
industry (Chappell and Crews, 2006).
Catfish are primarily cultured in embankment ponds or watershed
ponds and are harvested by seining. Despite being relatively
∗ Corresponding author. Tel.: +1 334 844 4078; fax: +1 334 844 5933.
E-mail addresses: Travis.Brown@ars.usda.gov (T.W. Brown),
boydce1@auburn.edu (C.E. Boyd). 1 United States Department of Agriculture, Agriculture Research Service, Thad
Cochran National Warmwater Aquaculture Center, Post Office Box 38, Stoneville,
MS 38776, United States.
land and labor intensive, pond production can be efficient and
profitable if production levels are increased through techniques
that maintain adequate water quality (Boyd and Tucker, 1998).
The traditional pond system typically produces 4500–5500 kg/ha
of catfish with a maximum of 7000 kg/ha (Brune, 1991; USDA,
2006). However, today, many farms in Alabama produce more than
10,000 kg/ha, and the amount of aeration provided is not adequate
to consistently maintain minimum dissolved oxygen (DO) concentrations
above 3 mg/L (Boyd and Hanson, 2010). The need for
improvedmanagement is reflected in the high feed conversion ratio
(FCR). Based on USDA/NASS data on food-size catfish production
and grow-out feed deliveries to farms in the U.S. between 2005 and
2009, FCR averaged 2.67. An FCR of 1.6–1.8 is considered acceptable
in well-managed ponds (Boyd and Tucker, 1998).
Catfish farming must become more efficient to remain profitable
and sustainable. Thus, in addition to the urgency in improving
traditional pond production methodology, there is a demand for
more efficient production techniques for raising channel catfish.
Early attempts at intensifying culture practices for warm water
fish involved raceway, tank and cage culture (Andrews et al., 1971;
Hill et al., 1974; Schmittou, 1969). However, farmers already have
ponds and Auburn University began research on floating, in-pond
raceways in the late 1990s in an attempt to develop a new methodology
that could be installed in existing ponds (Masser, 2004).
The basic floating, in-pond raceway consisted of a floating raceway
stocked with catfish fingerlings. Airlift pumps circulated pond
water through the culture unit and a waste removal system was
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doi:10.1016/j.aquaeng.2011.03.003T.W. Brown et al. / Aquacultural Engineering 44 (2011) 72–79 73
utilized to capture solid fish waste from the end of the raceways
(Hawcroft, 1994; Bernardez, 1995; Wilcox, 1998). Although the
original system was successful in research settings, it had several
disadvantages including uneven water flow throughout the raceways
and low efficiency of solid waste removal. After continued
research for several years, the problem with uneven water flow was
corrected by building the airlifts identical to each other, attaching
each airlift to the same air-manifold, and installing a restriction
orifice at the attachment of the air-manifold to the air-line (Masser
and Lazur, 1997). Moreover, survival was initially low because of
disease outbreaks, but improved as research progressed. Consequently,
several more alterations have been made in system design
and operational procedures to increase the uniformity and volume
of water flow and maximize the opportunity for biomass loading.
However, the use of in-pond raceways has not been adopted by
producers.
More recent studies demonstrated new aquaculture production
practices that utilize high rate photosynthetic systems. They are the
partitioned aquaculture system developed at Clemson University
(Brune et al., 2004), and the split-pond system that has been constructed
at the Delta Research and Extension Center at Stoneville,
MS (Tucker and Kingsburg, 2009). These systems combine a number
of biological, chemical, and physical intensification elements
into a single, integrated system that may prove more controllable
and efficient than traditional pond culture.
The present study describes a modification of the in-pond raceway
system in which the raceways are fixed rather than floating.
The efficiency of this system in producing catfish in the raceways
and co-cultured species in the surrounding pond also is discussed.
2. Materials and methods
2.1. System layout
This study was conducted on a 174-water ha commercial catfish
farm in Browns, AL. The in-pond raceway system was installed in
a 2.43-ha, traditional, earthen pond supplied by both well water
and watershed runoff. The system consisted of six individual raceways
that share common walls attached to a permanent con