2. Material andmethods2.1. Study ar

2. Material andmethods
2.1. Study area
This study was conducted in the Shanyutan wetland (26°01′46″N,
119°37′31″E; Fig. 1), the largest tidal wetland (approximately
3120 ha) in theMinjiang River estuary. The climate in this region is relativelywarmandwetwith
amean annual temperature of 19.6 °C and a
mean annual precipitation of 1346mm(Zheng et al., 2006). The soil surface
across the study site is submerged beneath 10–120 cmof water for
3–3.5 h during each tidal inundation. At lowtide, soil surfaces of the entire
estuarine wetland are exposed, and the annual average weight of
the water content (ratio of water weight to dry-soil weight) and the
soil redox potential are 116% and 12.6mV, respectively. The soil remains
flooded at somedepths. The average salinity of the tidalwater fromMay
to December 2007 is 4.2± 2.5‰. Phragmites australis is one of themost
important plant species (Liu et al., 2006) in the area and is typically
found in the upper (mid to high) portions of mudflats, which are a
main component of the Shanyutan tidal wetland.
P. australis is a C3 plant (mature height of 2mwith 150 stemsm−2).
The above- and belowground biomasses of P. australis in the study area
are 1500 and 2322 g m−2, respectively, and the above- and belowground
C, N and P storages by the plants are 0.24 and 0.85 kg m−2,
16.7 and 21.8 g m−2 and 0.60 and 1.97 g m−2, respectively (Tong
et al., 2011). The rate of decomposition of litter from these plants is
0.00384 d−1, and the amounts of C, N and P released account for 53.1,
79.6 and 79.1%, respectively, of the initial litter during the 280-day period
of decomposition (Wang et al., 2012a).
The areas of natural wetlands are gradually decreasing as human
disturbance increases. We have studied the following types of human
disturbance: (1) natural P. australis wetland with very limited or no
human disturbance was defined as the control, (2) grassland established
in P. australis wetlands where cattle have been bred for six
years, (3) mudflats where mudskippers have been bred for 10 years
(hereafter referred to as flat breeding), (4) pond aquaculture where
fish have been bred for 10 years and (5) cropland where rice has been
cultivated for 70 years was defined as very high disturbance; the rice
cropland received annual applications of N, P and K fertilizers at 95, 30
and 58 kg ha−1, respectively (Wang et al., 2012b).
2.2. Soil-sample collection and measurement
The soil sampleswere collected in October 2007. Sampling locations
were established in the P. australis wetland, grassland, flat breeding,
pond aquaculture and rice cropland (Fig. 1). Three plotswere randomly
selected in each of the locations, and soil profiles (width, 1 m; length,
1 m; depth, 0.5 m) were excavated. Samples were collected with a
small sampler (length and diameter were 0.3 and 0.1 m) from each of
five soil layers (0–10, 10–20, 20–30, 30–40 and 40–50 cm) at the center
and both sides of the soil pit. These three samples fromeach layer were
bulked to form one sample per layer. A total of 75 soil samples (five
types of land-use × three plots × five soil layers) were thus collected.
In the laboratory, the soil samples were air-dried, roots and visible
plant remains were removed and the soil samples were finely ground
in a ball mill.
Total soil organic Cwas determined by the K2Cr2O7–H2SO4 digestion
method (Bai et al., 2005; Sorrell et al., 1997), total soil N concentration
was analyzed by the K 370 Kjeldahl method (Buchi Scientific Instruments,
Switzerland), total soil P concentration was measured by
perchloric-acid digestion followed by ammonium-molybdate colorimetry,
available-P concentration was determined by extraction with acidic
ammonium fluoride and measurement using an UV-2450 spectrophotometer
(Shimadzu Scientific Instruments, Japan), total K concentration
was determined by FP 640 flame photometry (Shanghai Electronic
Technology Instruments, China) and available-N concentration was
measured by the alkaline-hydrolysis diffusion method (Lu, 1999).