The eight experimental sites were l

The eight experimental sites were located at Ubon
Ratchathani (158140N, 1048510E), Khon Kaen (168260N,
1028500E), Udon Thani (178240N, 1028470E), Chum Phae
(168320N, 1028050E), Phi Mai (158120N, 1028300E), Sakhon
Nakhon (178090N, 1048090E), ThungKula Ronghai (158350N,
1038350E), and Surin (148530N, 1038290E) (Fig. 1). All sites
were located in the two major landscape types of northeast
Thailand, that is, in large non-floodplains and floodplains
(Ubon, Phi Mai, Surin) and in the lower positions of the gently
undulating land (Khon Kaen, Sakhon Nakhon, Thung KulaRonghai, Chum Phae, Udon Thani). Likewise, the locations
represent the main precipitation zones: northern and eastern
regions with average rainfall of 1400 mm a
1 (Ubon,
Sakhon Nakhon), western and southwestern regions with
average rainfall of 1200 mm a
1 (Khon Kaen, Phi Mai,
Chum Phae), and a central band with average rains between
1200 and 1400 mm a
1 (Udon Thani, Thung Kula Ronghai,
Surin). All sites were between 170 and 300 m above sea level
and daily temperature extremes throughout the cropping
season indicated a low risk of spikelet sterility due to extreme
temperatures (across seasons and sites, the lowest daily
minimum temperature was 16 8C and the highest daily
maximum temperature was 39.6 8C).
2.2. Experimental layout and general crop management
A total of 26 on-station experiments were conducted
during the wet seasons of 1995, 1996, and 1997. The
experimental design used at all sites was a randomized
complete block design with eight different treatments
(Table 1) and three replications. Rice was grown under
rainfed lowland conditions at all sites, but in addition the
experiment was repeated under irrigated conditions in Ubon
(below referred to as Ubon 1: irrigated; Ubon 2: rainfed).
Experimental plot size was 4 m  5 m, and subplots were
separated by bunds. Fertilizer was applied as outlined in
Table 1. Rates of N, P, and K were adjusted to the rainfed
lowland environment where much lower quantities are
common than in most irrigated systems. However, the rate of
50–22–42 kg N–P–K ha
1 was above the regional recommendation
(40–12–10 kg N–P–K ha
1) and the average
farmers’ practice (e.g., 35–14–13 kg N–P–K ha
1; Wijnhoud
et al., 2003) to achieve high yields and avoid soil
nutrient depletion, but represented especially for P an overfertilization
at most sites (Naklang et al., in preparation).
The dose of 10 t ha
1 farmyard manure was used to
guarantee an effect but was at least three to four times above
the farmers’ practice and practicable rates.
In general, transplanting was used for crop establishment
(three seedlings per hill, 0.25 m  0.25 m spacing). Seedlings
were transplanted at 25–36 days after seeding
(exception of 50-day-old seedlings at Thung Kula Ronghai
1997). Broadcast seeding of dry seed was used once (Thung
Kula Ronghai 1996). Details on sowing date, harvesting
date, and crop duration are given in Table 2. In 1996, the trial
in Phi Mai failed because of flooding from the Moon River.
Variety KDML105 was the preferred variety for the
experiments, but in three experiments (Ubon 1 and 2,
1995; Khon Kaen, 1997) the similar variety RD15 (mutant
of KDML105) was used.Weeds were controlled manually at
around panicle initiation.
2.3. Observations and analysis
At each site, a composite topsoil sample (0–0.15 m) from
10 randomly selected subsamples scattered across the
complete experimental area was collected at the beginning
of the experiments. Soil analysis conducted included texture
analysis (modified from Koehn, 1928), pH (1:1 soil–H2O
mixture), total soil N (TSN; Bremner, 1996), total organic
carbon (TOC), available P (Bray II-P; Bray and Kurtz,Daily weather data, including rainfall, minimum and
maximum temperature, relative humidity, and evaporation,
were recorded at all sites close to the experiment. Seasonal
rainfall was defined as the rainfall between actual sowing
and harvesting dates.
Crop characteristics monitored and used for this report
included crop duration (sowing to harvest), grain yield, and
grain moisture content. Grain yield was determined from an
8 m2 area in the center of each subplot. All grain yields are
reported at the standard moisture content of 14%.
Average field hydrology of the whole experimental area
was evaluated visually once a week and the dominant field
hydrology levels (ponded water, wet soil surface, dry soil
surface) were determined for the crop development stages
pre-flowering, flowering (1 week around flowering), and
post-flowering (published in Wade et al., 1999a). Based
on these data, we calculated the mean seasonal field
hydrology for all sites and seasons by attributing
numerical values to the three field hydrology levels (1,
ponded water; 2, wet soil surface; 3, dry soil surface). In
the context of crop reaction to varying water supply,
‘‘field hydrology’’ is referred to as ‘‘field water stress’’ in
the text below. The field hydrology levels can be
translated into stress levels according to level 1 equals
minimum water stress and level 3 equals maximum water
stress.
2.4. Statistical analysis
Crop data were examined using IRRISTAT and the SAS
system microcomputer program. Cluster analysis by Ward’s
method was used to determine soil groups with similar
characteristics. For the analysis of variance with a mixed
effect procedure, replication within sites and years as
random effects with heterogeneous variances across years
was used to analyze yield and yield response results.