Shou-Qin Sun1,2, Hui-Ying Cai3,2, Scott X Chang2, Jagtar S Bhatti4. 1. Key Laboratory of Mountain Surface Processes and Ecological Regulation, Institute of Mountain Hazards and Environment, Chinese Academy of Sciences, No. 9, Block 4, South Renmin Rd., Chengdu, 610041 China. 2. Department of Renewable Resources, 442 Earth Sciences Building, University of Alberta, Edmonton, AB T6G 2E3, Canada. 3. Center for Ecological Research, Northeast Forestry University, No.26 Hexing Rd., Xiangfang Dist., Harbin, 150040 China. 4. Canadian Forest Service, Northern Forestry Centre, 5320 122nd St. Edmonton, AB, T6H 3S5 Canada.
Abstract
Effects of sample storage methods on the quantity and quality of labile soil organic carbon are not fully understood even though their effects on basic soil properties have been extensively studied. We studied the effects of air-drying and frozen storage on cold and hot water soluble organic carbon (WSOC). Cold- and hot-WSOC in air-dried and frozen-stored soils were linearly correlated with those in fresh soils, indicating that storage proportionally altered the extractability of soil organic carbon. Air-drying but not frozen storage increased the concentrations of cold-WSOC and carbohydrate in cold-WSOC, while both increased polyphenol concentrations. In contrast, only polyphenol concentration in hot-WSOC was increased by air-drying and frozen storage, suggesting that hot-WSOC was less affected by sample storage. The biodegradability of cold- but not hot-WSOC was increased by air-drying, while both air-drying and frozen storage increased humification index and changed specific UV absorbance of both cold- and hot-WSOC, indicating shifts in the quality of soil WSOC. Our results suggest that storage methods affect the quantity and quality of WSOC but not comparisons between samples, frozen storage is better than air-drying if samples have to be stored, and storage should be avoided whenever possible when studying the quantity and quality of both cold- and hot-WSOC.
Effects of sample storage methods on the quantity and quality of labile soil organic carbon are not fully understood even though their effects on basic soil properties have been extensively studied. We studied the effects of air-drying and frozen storage on cold and hot water soluble organic carbon (WSOC). Cold- and hot-WSOC in air-dried and frozen-stored soils were linearly correlated with those in fresh soils, indicating that storage proportionally altered the extractability of soil organic carbon. Air-drying but not frozen storage increased the concentrations of cold-WSOC and carbohydrate in cold-WSOC, while both increased polyphenol concentrations. In contrast, only polyphenol concentration in hot-WSOC was increased by air-drying and frozen storage, suggesting that hot-WSOC was less affected by sample storage. The biodegradability of cold- but not hot-WSOC was increased by air-drying, while both air-drying and frozen storage increased humification index and changed specific UV absorbance of both cold- and hot-WSOC, indicating shifts in the quality of soil WSOC. Our results suggest that storage methods affect the quantity and quality of WSOC but not comparisons between samples, frozen storage is better than air-drying if samples have to be stored, and storage should be avoided whenever possible when studying the quantity and quality of both cold- and hot-WSOC.
The effect of sample storage methods on soil properties being studied is an important
issue that needs to be considered before planning an experiment. Although research
suggests that soil samples should be analyzed immediately after sampling12, sample storage is not avoidable in many cases for reasons of time
limitation or long-distance sample shipping3. In such cases, soil samples
are commonly air-dried for storage345 or frozen-stored at
−20 °C or lower in a freezer6.Sample storage methods may influence both the physicochemical and biological properties
of soils17891011. For example, both air-drying and frozen
storage may cause a breakdown of soil aggregates7. Air-drying has been
reported to decrease soil pH and increase extractable Mn, Fe, Cu and Zn contents812, and is considered to be the worst storage method if soil biological
properties are to be studied on those stored samples110 as it may cause
the death of some bacteria because of hydric stress by the osmotic effects of the
drying/rewetting process9. Although frozen storage at
−20 °C (the most common frozen storage condition)
may also change some of the microbial properties, its effects are generally more
moderate as compared to that caused by air-drying101314. The
Organization for Economic Cooperation and Development15 recommended that
soil samples should be frozen-stored not exceeding one year if storage in the laboratory
is unavoidable. However, some argue that the effect of sample storage methods on soil
properties depends on the soil parameter to be studied1011.Soil water soluble organic carbon (WSOC) is the most labile organic C form with fast
turnover rates1617 and has been extensively studied in recent years due
to the important role it plays in C cycling. However, different sample storage methods
including air-drying and frozen storage are commonly used prior to sample analysis3456. These sample storage methods might influence the concentration
and chemical property of WSOC. As a result, comparison between studies using different
sample storage methods can be difficult.According to Laura et al.18, drying would result in the breakdown
of organic matter. Air-drying of soil samples has been found to enhance the
mineralization of organic matter as air-drying increases the solubilization of organic
matter and disrupts soil aggregates19. A 3- to 10-fold increase in WSOC
was detected in air-dried soil samples in comparison to samples kept in a field moist
state220. Zhao et al.21 found that air-drying
increased the WSOC concentration while decreased the difference in WSOC concentrations
among soil samples. Even though there are few studies on the effects of air-drying on
WSOC and in all these studies the WSOC was extracted by water at room temperature
(cold-WSOC), no one has tested the effect of sample storage on WSOC extracted by hot
water (70–80 °C, hot-WSOC), and no one has reported
the impact of sample storage methods on the changes in the quality of cold- and
hot-WSOC. In fact, the quality of WSOC such as the degradability and the aromaticity may
be markedly affected by sample storage methods, even if the amount of WSOC is not
affected. In addition, few have studied the effect of frozen storage of soil samples on
the concentration or quality of both cold- and hot-WSOC, although natural freeze-thaw
processes have been found to increase the concentration of simple sugars, carbohydrates
and polyphenols in the soil2223.In this study, the concentration and properties of both the cold- and hot-WSOC in various
soil types in fresh, air-dried and frozen-stored soil samples were measured. Our
objectives were to: 1) test whether air-drying and frozen storage would change the
concentration and property of cold- and hot-WSOC in different soil samples; and 2) to
explore the relationships between the concentrations of WSOC in fresh soil samples and
those in air-dried and frozen-stored samples. We hypothesized that 1) frozen storage
would not change while air-drying would increase the concentrations and change the
properties of both cold- and hot-WSOC, and 2) there would be a linear relationship in
WSOC concentrations between samples stored with different methods as storage methods
will cause a systematic shift in the extractability of soil organic C.
Results
Concentrations and properties of cold- and hot-WSOC
Sample storage methods affected cold-WSOC (F2,
22 = 28.9,
P < 0.001) and its carbohydrate
concentrations (F2, 22 = 25.2,
P < 0.001) (Fig. 1, Table 1). Air-drying
resulted in the highest concentrations of WSOC and its carbohydrate
concentrations in cold-WSOC. The amount of cold-WSOC in the air-dried soils was
linearly correlated with that in the fresh soils (two-tailed test,
R2 = 0.89,
P < 0.001) (Fig. 2).
Frozen storage did not significantly alter the concentration of WSOC and that of
carbohydrate in cold-WSOC (Fig. 1a,c). Both air-drying
(P < 0.001) and frozen storage
(P = 0.002) increased the concentration of
polyphenol in cold-WSOC, with the highest value in the air-dried followed by
that in the frozen-stored samples (Fig. 1e). In contrast,
neither air-drying nor frozen storage influenced the concentration of WSOC or
its carbohydrate concentrations in hot-WSOC (Fig. 1d,e).
However, increases in the polyphenol concentration were observed in hot-WSOC in
both the air-dried (P = 0.001) and the
frozen-stored soils (P = 0.002) (Fig. 1f).
Figure 1
Concentrations of cold- and hot-WSOC and concentrations of carbohydrate and
polyphenol in cold- and hot-WSOC (mean ± SE): (a) concentration of
cold-WSOC; (b) concentration of hot-WSOC; (c) concentration of carbohydrate in
cold-WSOC; (d) concentration of carbohydrate in hot-WSOC; (e) concentration of
polyphenol in cold-WSOC; and (f) concentration of polyphenol in hot-WSOC.
FS, fresh soil; AD, air-dried soil; FZ, frozen-stored soil; WSOC, water soluble
organic carbon.Means with different lowercase letters are significantly different at
P < 0.05.
Table 1
ANOVA for the effects of sample storage methods on the concentration and the
quality of the cold- and the hot-WSOC.
Dependent variable
Source of variation
Cold-WSOC
Source of variation
Hot-WSOC
df
SS
F
df
SS
F
WSOC concentration
Block
11
12595
13.2 ***
Block
11
158557
63.6***
Treatment
2
27567
28.9***
Treatment
2
6188
2.5
Residuals
22
955
Residues
22
2492
Carbohydrate
Block
11
2033
5.3***
Block
11
58272
17.4***
Treatment
2
9715
25.2***
Treatment
2
2947
0.9
Residuals
22
386
Residues
22
3351
Polyphenol
Block
11
154
19.8***
Block
11
2019
87.3***
Treatment
2
201
25.8***
Treatment
2
251
10.9**
Residuals
22
7.8
Residues
22
23.1
SUVA 254
Block
11
<0.001
3.7**
Block
11
<0.001
7.9***
Treatment
2
0.004
117.1***
Treatment
2
<0.001
5.6*
Residuals
22
<0.001
Residues
22
<0.001
HIX
Block
11
6.9
4.6**
Block
11
4.1
7.2***
Treatment
2
114
77***
Treatment
2
14.6
25.4***
Residuals
22
1.5
Residues
22
0.6
Biodegradability
Block
8
0.01
0.4
Block
11
0.008
1.751
Treatment
2
0.04
10.8**
Treatment
2
0.003
0.712
Residuals
16
0.04
Residues
22
0.005
Significance levels:
*P < 0.05;
**P < 0.01,
***P < 0.001; WSOC, water
soluble organic carbon; SUVA254, specific UV
absorbance at 254 nm; HIX, humification
index.
Figure 2
Relationships of cold- and hot-WSOC concentrations between air-dried (AD) and
fresh soils (FS) and between frozen-stored (FZ) and fresh soils. WSOC, water
soluble organic carbon.
Quality of cold- and hot-WSOC
Air-drying and frozen storage decreased the specific UV absorbance at 254 nm
(SUVA254) of cold-WSOC (P < 0.001), with
the lowest SUVA254 in the air-dried, followed by the frozen-stored
and then the fresh samples (Fig. 3a). In contrast,
air-drying (P = 0.043) and frozen storage
(P = 0.013) resulted in a significant
increase in SUVA254 of hot-WSOC (Fig. 3b). The
humification index (HIX) in both the cold- and hot-WSOC was significantly
increased by air-drying (cold- and hot-WSOC:
P < 0.001) and frozen storage (cold-WSOC:
P < 0.001; hot-WSOC:
P = 0.006), with the highest value in the
air-dried soils, followed by the frozen-stored and then by the fresh soil
samples (Fig. 3c,d).
Figure 3
The SUVA254 and HIX values and biodegradability of cold- and
hot-WSOC (mean ± SE): (a) SUVA254 values of cold-WSOC;
(b) SUVA254 values of hot-WSOC; (c) HIX of cold-WSOC; (d) HIX of
hot-WSOC; (e) Biodegradability of cold-WSOC; and (f) Biodegradability of
hot-WSOC.
The biodegradability of cold-WSOC was significantly influenced by air-drying of
samples, where 98.4% increases in biodegradability was observed in the air-dried
relative to the fresh samples (P = 0.045) (Fig. 3e). However, there was no significant difference among
sample storage methods in the biodegradability of hot-WSOC (Fig.
3f).
Discussion
Air-drying increased while frozen storage at
−20 °C in this study did not affect the
concentrations of cold-WSOC and carbohydrate in cold-WSOC, supporting part of our
first hypothesis. The linear relationships for WSOC concentrations between the
air-dried and fresh soils and that between the frozen-stored and fresh soils support
our second hypothesis, while it differs with previous results where the difference
in cold-WSOC concentration among soil samples was decreased by air-drying21 , as well as those reporting that the differences in cold-WSOC
concentration between air-dried and fresh soils were proportionately greater for
soils with higher total soil organic matter concentrations20.The higher cold-WSOC concentration in air-dried, relative to fresh soils is
consistent with results reported by Zsolnay et al.24, Kaiser
et al.25, Jones & Willett2 and Zhao
et al.21. The increased cold-WSOC concentration in
air-dried soils may partly come from lysed microbial cells during the drying and
rewetting processes that follows (during WSOC extraction)92126.
For example, air-drying and the following rewetting process have been found to kill
up to ca.70% of the microbial population in soils27. The C contained
in these dead microbial cells can be rapidly released as soluble organic C when the
soil is rewetted28. The higher concentration of carbohydrates, one of
the main constituents of microbial cells29, in the air-dried soils
(Fig. 1c) supports the microbial source of the increased
cold-WSOC in these soils. In contrast, the unchanged concentrations of cold-WSOC and
carbohydrate concentrations in cold-WSOC in frozen-stored soils are likely because
microbial cells were preserved when samples were frozen-stored10131430. Although when compared to fresh and frozen samples
air-drying may lead to some loss of volatile organic matter from manure where the
volatile organic matter concentration is high31, we do not expect
that to be the case in our soil samples in which the volatile organic matter
concentration should be very low.The WSOC and the carbohydrate concentrations in hot-WSOC were altered neither by
air-drying nor by frozen storage, rejecting part of the first hypothesis. This is
likely because hot water itself can hydrolyze organic matter, lyse microbial cells,
make microbial components extractable3233343536, and
dissociate organic materials from inorganic colloids33; the sum of
those effects together likely eliminates the differences among samples with
different storage methods. The result further illustrates that, hot water being a
strong extractant that can dissolve a large portion of the soil organic matter, the
hot water extraction method is less sensitive for detecting sample storage effects
on WSOC. The higher concentrations of polyphenol in both cold- and hot-WSOC in the
air-dried and frozen-stored soils relative to the fresh soils were likely caused by
the release of humified materials from soil matrixes when samples went through
drying/rewetting and freezing/thawing processes, as changes in soil matrixes would
increase the release of humified materials24.Although the effect of sample storage such as air-drying on WSOC concentration has
been studied, few studied the effect of sample storage on the change in the quality
of WSOC as measured by the degree of aromaticity and biodegradability, which is more
important in reflecting the stability of WSOC. The aromaticity of WSOC can be
measured by the SUVA254 index3738; the lower
SUVA254 values in cold-WSOC in the air-dried and frozen-stored soils
than in the fresh soils in this study indicate that cold-WSOC was less aromatic and
less stable in the air-dried and frozen-stored than in the fresh soils. The HIX
provided information about aromatic structures and the complexity of the
molecules39; the HIX values in cold-WSOC in this study indicate
that the air-dried and frozen-stored soils had a higher degree of complexity,
conjugation and condensation (i.e., low H/C ratio) of the molecules such as those
being variously substituted, condensed aromatic rings, and/or highly unsaturated
aliphatic chains4041. Contradictory results on the stability of
WSOC based on SUVA254 vs. HIX were probably because some
small-molecular-weight fractions which have low absorbance but high fluorescence
were produced during air-drying and frozen storage4243. The results
also suggest a possibility that part of the aromatic structures in cold-WSOC were
broken down and some condensed molecules such as unsaturated aliphatic chains were
formed during the air-drying/frozen storage and the wetting/thawing processes that
followed. In addition, the evaporation of volatile organic matter during the
air-drying processes may change the chemical composition of organic matter in the
air-dried soils, resulting in the lowest SUVA254 and highest HIX values
in those soils relative to the fresh and the frozen-stored soils.Higher SUVA254 values in hot-WSOC in the air-dried and the frozen-stored
soils than in the fresh soils were likely because that hot water could extract a
wider range of C compounds including phenols, lignin monomers and heterocyclic
N-containing compounds44, especially when soil aggregates had been
physically disrupted by the air-drying/rewetting or the freezing/thawing
processes724. Again, the higher HIX indices in hot-WSOC in the
air-dried than in the frozen-stored soils show that air-drying and frozen storage
promoted the conjugation and condensing of C compounds2445.The higher biodegradability only in cold-WSOC in air-dried soils than in fresh soils
in this study is consistent with the elevated carbohydrate concentration in
cold-WSOC in the studied soils (Figs 1 and 3). The results are consistent with previous findings that the
degradable portion of dissolved organic C is positively correlated with the
concentration of carbohydrates464748, and suggest that the
effects of air-drying on WSOC properties was greater than frozen storage and
cold-WSOC was more sensitive to sample storage methods than hot-WSOC.
Materials and Methods
Study site, and soil sampling and processing
To obtain a set of soils representing a range of soil types and properties, 12
soil samples were collected from three sites representing two dominant
agroforestry systems (shelterbelt and silvopastural systems) in central Alberta,
Canada. In each agroforestry system, there are two land use types, forest (or
shrub) and agricultural land uses. The shelterbelt system consists of a variety
of trees and shrubs planted in 1–2 rows as shelterbelts49 and corresponding agricultural field where the trees and shrubs
provide protection against wind and reduce erosion. The silvopasture system
consists of grazed aspen forest and the adjacent open pasture where the trees
provide shade, shelter and forage for livestock, reducing stress and increasing
forage production. Site one (54°35.244′ N and
112°48.204′ W) had a silvopastural system located near
Athabasca in north Central Alberta, Canada. The soil type is Dark Gray Chernozem
with a loam texture, the mean annual temperature was
2.3 °C and the mean annual precipitation was
469 mm based on data collected between 2009 and 2014 at nearby
Atmore AGCM weather station. The trees were dominated by aspen (Populus
tremuloides Michx.), white birch (Betula papyrifera Marsh.), and
balsam poplar (Populus balsamifera L.), and the dominant herbaceous
vegetation was introduced species such as Bromus inermis and the system
was grazed by cattle in either a rotational or a season-long grazing system.
Site two (53°31.793′ N and
113°31.845′ W) was a shelterbelt system located near
Camrose in north Central Alberta, Camada. The soil was Black Chernozem with a
clay loam texture, the mean annual temperature was
3.7 °C and the mean annual precipitation was
388 mm based on data collected between 2005 and 2014 at nearby
University of Alberta Metabolic Centre weather station. The agricultural land
was under monocultural annual production system and was converted to agriculture
about 100 years ago. Most landowners in the area practice minimum tillage, apply
fertilizers, and grow barley (Hordeum vulgare L.), wheat (Triticum
aestivum L.), or canola (Brassica napus L.) in rotation. Site
three (50°53.996′ N and
111°56.611′ W) was a silvopastural system located at
Mattheis Ranch, a microcosm of southern Alberta, Canada, where the land use was
grassland and shrubland, the soil type was Brown Chernozem and the soil texture
was loamy sand. The mean annual temperature was 4.3 °C
and the mean annual precipitation was 319 mm based on data collected
between 2005 and 2014 at nearby Rosemary AGDM weather station. The dominant
grass species was Bouteloua gracilis (H. B. K.) Lag. ex Steud and the
dominant shrub was Shepherdia argentea (Pursh) Nutt.Within each site, two paired plots were established in the treed (or shrub) area
and its adjacent agricultural land use of the same ecosite, elevation and slope.
In each plot, soil samples were collected from the 0–10 and
10–20 cm layers using a soil corer (3.2 cm diameter) in
June, 2014, from 20 points along a 100 m transect within each
forest- or shrubland-based and adjacent agricultural land use systems.
Therefore, four soil samples were collected from each of the three sites,
resulting in a total 12 soil samples. The 12 soil samples had different
physicochemical properties such as texture, pH, and organic C concentration
(Table 2). Soil samples were placed in sealed
plastic bags, and kept cool (<4 °C) until they were
transported to the laboratory for processing. In the laboratory, samples were
sieved (2 mm) to homogenize the sample and to remove visible roots and coarse
fragments.
Table 2
Physical and chemical properties
(mean ± SD) of the 12 soil samples.
Site location
Soil type
Soil texture
Land use
Sample ID
Soil layer (cm)
TOC (%)
TN (%)
pH
N 54°35.244′
W 12°48.204′
Dark Gray Chernozem
Loam
Grassland
1
0−10
2.59 ± 0.17
0.19 ± 0.04
4.98 ± 0.01
2
10−20
0.81 ± 0.01
0.04 ± 0.04
5.44 ± 0.04
Woodland
3
0−10
2.08 ± 0.17
0.15 ± 0.01
4.63 ± 0.01
4
10−20
0.53 ± 0.12
0.03 ± 0.02
4.63 ± 0.04
N 53°31.793′,
W 13°31.845′
Black Chernozem
Clay loam
Cropland
5
0−10
4.05 ± 0.15
0.36 ± 0.01
4.59 ± 0.00
6
10−20
4.16 ± 0.13
0.33 ± 0.04
5.55 ± 0.01
Shelterbelt
7
0−10
5.79 ± 0.06
0.47 ± 0.03
5.55 ± 0.01
8
10−20
4.90 ± 0.16
0.41 ± 0.03
5.23 ± 0.01
N 50°53.996′,
W 10°56.611′
Brown Chernozem
Loamy sand
Grassland
9
0−10
1.44 ± 0.01
0.13 ± 0.01
5.76 ± 0.05
10
10−20
0.74 ± 0.02
0.04 ± 0.00
6.00 ± 0.00
Shrubland
11
0−10
2.43 ± 0.03
0.20 ± 0.03
5.82 ± 0.01
12
10−20
1.35 ± 0.06
0.13 ± 0.02
7.36 ± 0.00
TOC and TN represent total organic carbon and total nitrogen,
respectively.
Experiment design
We used a completely randomized block design to study the effect of three
different sample storage methods on the quantity and quality of labile organic
C: 1) samples stored at 4 °C and analyzed within
48 hours (fresh, FS); 2) samples were air-dried for two weeks
(air-drying, AD) and stored at room temperature until analysis; and 3) samples
were frozen-stored in a freezer at −20 °C
for one month, and taken out and thawed immediately before measurements (frozen
storage, FZ). In the experiment the 12 soil samples served as 12 blocks. Each of
the 12 soil samples was divided into three sub-samples and randomly assigned to
one of the three treatments. In the laboratory analysis, three previously
air-dried soil samples were analyzed together with the FR, AD and FS samples in
order to ensure that the data from the two different runs were comparable. The
data for those three previously air-dried soil samples were not different
between the two runs and thus the data for the experimental samples from the two
runs were treated as from the same run.
Extraction of cold- and hot-WSOC
The cold- and hot-WSOC were extracted and measured according to Li et
al.50. For determining cold-WSOC, a portion of a soil
sample equivalent to 15 g oven-dry weight was placed into a
50 mL centrifuge tube, and 30 mL of distilled water was
added (soil:water = 1:2, w-v). The centrifuge tube was
then shaken at 120 rpm for 30 min at
25 °C, centrifuged for 20 min at
4000 g, and filtered through a 0.2 μm
membrane filter (Millipore Corp, USA). For determining hot-WSOC,
15 g of oven-dry equivalent soil samples were placed into
50 mL centrifuge tubes and to each centrifuge tube 30 mL
of distilled water was added (soil:water = 1:2, w-v).
The centrifuge tubes were then placed in a water bath
(80 °C) for 16 h, and then shaken at
120 rpm for 30 min, followed by centrifuging for
20 min at 4000 g. The extract was then also filtered
through a 0.2 μm membrane filter (Millipore Corp,
USA).
Analysis of the concentration and quality of cold- and hot-WSOC
The organic C concentrations in cold- and hot-WSOC were analyzed using a Shimadzu
TOC-V CSH/CSN analyzer (Shimadzu Corporation, Kyoto, Japan). Subsample of both
the cold- and hot-WSOC extracts were analyzed for a) total sugars by the
phenol-sulfuric method51, using glucose as a standard, after the
samples were treated with 0.1 M EDTA (Ethylene diaminetetraacetate), titrated to
pH 3.5–4.0 with 5 M KOH and centrifuged at 4000 g for
20 min to prevent co-precipitation of the sugars with cations52; and b) total polyphenols by the Folin-Ciocalteu method53. A weight/C ratio of 2.5 was used to convert carbohydrates to
carbohydrate C, and a ratio of 1.86 was used to convert polyphenols to
polyphenolic C54.The cold- and hot-WSOC were then assessed by absorbance and fluorescence analyses
on subsamples of cold- and hot-WSOC extracts. The UV–Vis absorbance
was measured using a Thermo Spectronic Genesys 10S UV–Visible
spectrometer. Samples were placed into a 1 cm quartz cuvette and
distilled water was used as the blank. Specific UV absorbance at
254 nm (SUVA254), which increases linearly with dissolved
organic C aromaticity3738, was calculated by dividing the
measured absorbance by the concentration of WSOC (L mg
C−1 cm−1).The fluorescence spectra were obtained with a Photon Technologies International
MP-1 spectro fluorimeter (Birmingham, NJ) using quartz cuvettes. Fluorescence
emission spectra were collected at an excitation wavelength of
254 nm and an emission wavelength range of 280–500 nm.
The humification index (HIX) was calculated as the area under the emission
spectra between 435 and 480 nm divided by the sum of the areas
between 300 and 345 nm, at 254 nm excitation55. The HIX provides information about aromatic structures39 and the complexity of the molecules and the degree of
humification of soil organic C56.
Biodegradability of cold- and hot-WSOC
To determine the biodegradability of cold- and hot-WSOC, 50 mL of
each extract was placed in a clean, acid-washed, 100 mL conical
glass flask. All samples were diluted to approximately 10 mg C
L−1 with distilled water to avoid extensive
growth of microorganisms57. To each flask,
50 μL of a soil microbial inoculum was added. The soil
microbial inoculum was prepared by taking 1 g of the composite soil
sample made from all soils and shaking at 20 rpm with
10 mL of distilled water, incubating the suspension for
approximately 48 h at 20 °C, and then
passing through a 0.45-μm membrane filter. The organic C content of
the soil inoculum solution was below detection limit
(<0.01 mg L−1). No nutrients were
added. The flasks were incubated with open tops in the dark at
20 °C for 7 days. The organic C concentration of the
samples was measured on days 0 and 7 with the Shimadzu TOC-V CSH/CSN analyzer
(Shimadzu Corporation). The day-7 samples were also filtrated through a
0.2 μm membrane filter (Millipore Corp, USA) before
analysis in order to remove any potential microbial cells. The incubation was
conducted in duplicates. Evaporative losses (<1 g
day−1) was compensated by adding distilled water
every day and before each sampling, to a precision of 0.1 g.
Biodegradability was calculated by dividing the difference in organic C
concentration between days 0 and 7 by the organic C concentration on day 0.
Analysis of basic soil properties
Total organic C (TOC) and total nitrogen (TN) concentrations were determined
using a Carlo Erba NA 1500 elemental analyzer (Carlo Erba Instruments, Milan,
Italy). Soil water content was determined by oven-drying a sub-sample of the
soil at 105 °C to constant weight. Soil pH was measured
in a suspension of 1:2 soil:water (w:v) using a portable pH meter (PCE
Instruments GmbH, Meschede). Soil texture was measured following the hydrometer
method described in Kroetsch and Wang58.
Statistical analysis
All data were expressed on an oven-dry soil weight basis. The normality of data
was tested with the Shapiro-Wilk test. An analysis of variance (ANOVA) model
with the factor block (the 12 soil samples) and treatment (sample storage
methods) was used to determine the effect of sample storage methods on the
quantity and properties of WSOC. For factors with significant main effects,
Tukey’s test was used following the randomized block design ANOVAs
to perform multiple comparisons between treatments. Pearson’s
correlation analysis with two-tailed test was used to analyze the relationships
between the air-dried (AD) and frozen-stored (FZ) soils and the fresh soils for
cold- and hot-WSOC concentrations. All analyses were performed with SPSS 19.0
for Windows.
Conclusions
The concentration of cold-WSOC in soil samples was increased by air-drying but was
not affected by frozen storage as compared to the fresh soil, while that of hot-WSOC
was not influenced by any of the two storage methods. We conclude that the
concentration of cold-WSOC is more sensitive than hot-WSOC to sample storage methods
and hot-WSOC is a better estimate of soil labile organic C than cold-WSOC when
stored soil samples are to be used for WSOC analysis. Although only air-drying
increased the biodegradability of WSOC, both air-drying and frozen storage changed
UV specific absorbance and HIX of cold- and hot-WSOC, we therefore conclude that
air-drying and frozen storage shifted the molecular structure of WSOC and only
evaluating the total WSOC content can be misleading as a lack of sample storage
method effect on the concentration does not mean there would be no effect on the
properties of WSOC. We suggest that sample storage methods should be selected
according to the soil property of concern as the sample storage method effect is
soil property-specific. Frozen storage is better than air-drying if samples have to
be stored, and storage should be avoided whenever possible when studying the
quantity and quality of both cold- and hot-WSOC.
Additional Information
How to cite this article: Sun, S.-Q. et al. Sample storage-induced
changes in the quantity and quality of soil labile organic carbon. Sci. Rep.
5, 17496; doi: 10.1038/srep17496 (2015).
Authors: James L Weishaar; George R Aiken; Brian A Bergamaschi; Miranda S Fram; Roger Fujii; Kenneth Mopper Journal: Environ Sci Technol Date: 2003-10-15 Impact factor: 9.028
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