In the early 1940’s, during the early stages of the Manhattan Project (WWII), of rural communities in Anderson County, Tennessee was rapidly converted into laboratory facilities and the city of Oak Ridge. The environment that became Oak Ridge experienced not only pollutants from the laboratory activities, but also alterations from the land-use change from rural to urban areas. Therefore, a study was conducted to determine the impacts of land-use change from rural to urban area on 1) street tree diversity and performance; and 2) the biological, chemical and physical properties, and nutrient dynamics of street tree ecosystem soils. There were a total of 607 street trees, composed of 37 different species, on the five main roadways in Oak Ridge, Tennessee. The street tree inventory revealed that the street tree ecosystems had a high relative abundance of Acer rubrum (21.91%) and Pyrus calleryana (19.93%). Chemical, rather than physical, soil and site properties in street tree ecosystems had the greatest impact on street tree performance. Soils differed street by street in their biological, chemical, and physical properties but were not influenced by traffic rates. There were also differences in soil microbial biomass carbon (MBC) during the winter on streets based on their diversity of trees; however, the most diverse street was among the lowest in soil microbial biomass. Seasonally, the winter proved to have not only greater amounts of soil microbial biomass carbon and nitrogen (MBN), but significantly less extractable organic carbon (EOC) and nitrogen (EON) and total labile carbon (TLC) than that in the spring. Overall, this study provided insights into the post urbanization impacts on the street trees, soils, sites, and nutrient dynamics within street tree ecosystems of Oak Ridge.
Urban trees (street trees, park trees, residential trees, etc.) face a host of environmental stressors such as pests, diseases, harsh climatic conditions, and poor soil qualities (Miller, 1997). Trees in more natural or rural settings are still exposed to many environmental factors such as pests or climatic conditions, but urban trees must be able to withstand natural stressors as well as issues associated more closely with an urban environment (Miller, 1997). The proximity of street trees to construction activities has been found to greatly impact the survival of street trees. These construction sites alter urban soils through compaction, chemical contamination, water saturation or depravation, and altered nutrient cycles, all of which can impact the ability for trees to thrive (Day et al., 2010; Tomiczek, 2003; Nielson et al., 2007). Hauer et al. (1994) found 5% greater mortality of street trees adjacent to construction activities, and also that there was a significant positive correlation between street tree conditions and tree lawn widths (the area in which street trees are growing). Impervious surfaces play a large role in the ecosystem processes in an urban environment (Nowak and Greenfield, 2012). Most notably, impervious surfaces increase local temperature, thereby creating an urban heat island (UHI) that affects the hydrology, pollutant emissions, and ozone production (Heisler and Brazel, 2010; U.S. EPA, 1983; National Research Council, 2008). The hydrological impacts on street trees range from excessive amounts of water to completely devoid water. Street trees that are planted in poorly drained soils are at risk of oxygen deficiencies due to the flooding of the root zone (Saebo et al., 2003). On the other hand, Nielson et al. (2007) suggests that street tree planting pits can be totally depleted of soil water during the growing season due to poor water retention in tree pit soils. The lack of water available to street trees is also due to the size of a planting pit, rainfall interception by buildings, other impervious surfaces, the actual tree, and increased rates of evapotranspiration from the heat island (Lemaire and Rossignol, 1999; Tomiczek, 2003).
In 1942, during WWII, laboratories were built in East Tennessee whose purpose was to develop the uranium bomb (DOE, 2013). The rural forests and farmland that were in that area were rapidly converted into laboratory facilities and the City of Oak Ridge (Resen, 2010). The environment that became Oak Ridge not only experienced the pressures that came with land-use change from rural to urban, but also the inputs of excess heavy metals and toxic chemical wastes from the laboratory activities. Pollutants from the laboratory have also been found in streams that are adjacent to roadways within the city itself; therefore, the trees and soils that are in close proximity to the highly polluted streams may be impacted by the wastes from the laboratory facilities (Jean- Philippe et al., 2011). Since the environment has gone through so much disturbance and change, it is important to determine how the vegetation and soils have been impacted by the land-use change.
Knowledge about the diversity of street tree ecosystems and the performance of street trees in Oak Ridge could help determine how resilient the street tree ecosystems are to current pressures within the city, as well as the potential threats posed by pests and disease. Furthermore, knowledge about the soils within the street tree ecosystems could offer insight as to how street tree ecosystems have been impacted by land-use change from rural to urban area in their biological, chemical, and physical properties as well as nutrient cycling. We investigated the impacts of land-use change on established street trees and their soils environment. A field study was conducted in the City of Oak Ridge, Tennessee in order to determine the impacts of land-use change on street tree diversity, performance, site and soil biological, chemical and physical properties, and nutrient dynamics within street tree ecosystems.
Oak Ridge, Tennessee is located in Anderson county of East Tennessee, USA (
Ridge Turnpike (−84 12.419, 36 2.99). All roadways had two traffic lanes with the exception of Illinois Avenue, which had three lanes of traffic from its intersection with Lafayette to its intersection with Tulane before it decreased to two lanes. Along these five streets, the street trees were inventoried and random plots were generated for soil sampling (
All live trees, dead trees, and stumps that were within the public right-of-way were included in the total inventory of the five main streets. The stumps and dead trees were included in the inventory for the Oak Ridge Recreation & Parks Department to utilize at their own discretion in future management. Species name, diameter at breast height (dbh), geographic coordinates, and tree condition (good, fair, poor, dead) were recorded for each street tree that had a dbh of 2.54 cm or greater. A Garmin etrex 20 hand-held GPS was used with the mark waypoint feature to assign each tree and stump with latitudinal and longitudinal coordinates. To assess the health of The City of Oak Ridge street tree ecosystems a 25% (152 street trees) random sample of live trees was selected from the total street tree inventory. Each of the 152 street trees was treated as a separate study plot. However, the sample size decreased to 136 street trees due to the removal of trees for maintenance or development purposes. The percentage of street trees from the random sample compared to the total amount of street trees along each street was 32% for Illinois, 42% for Rutgers, 15% for Tulane, 25% for Lafayette, and 23% for ORTP. The distance of each street tree to the nearest impervious surface was measured in order to determine the confinement of each planting space. To assess tree condition, Scharenbroch and Catania (2012) cumulative score ranking for different tree characteristics were adopted (
Live crown ratio (LCR), expressed as a percentage (%) was also determined for each of the sample street trees to be used as an additional condition variable. A three person consensus was used for determining tree score, tree crown width, and LCR.
Shannon’s diversity index was calculated for the total inventory, and each street utilizing the calculation below:
where Pi = the relative abundance of each tree species found at each site, S = number of tree species found, and ∑ = sum of tree species 1 to species S (Shannon and Weaver, 1949). For the Oak Ridge street tree diversity calculations, five 100 m long transects were randomly generated along each street. Based on the random transects, all of the trees that were perpendicular to or bisected by each transect were used in the diversity calculations.
To assess seasonal variation in street tree ecosystem soils, soil samples were taken both in the winter of 2013 (2/25/2013-3/15/2013) and spring of 2013 (5/9/2013-5/28/2013) within the drip line of each study street tree. Six 2.5 cm diameter soil cores 20 - 30 cm deep were taken randomly; from which a composite sample was produced for each study plot. Soil samples then were bagged, labeled and stored at −80˚C until analyzed. Subsamples were taken from composite soil sample for all soil analyses.
Factor | Score | ||||
---|---|---|---|---|---|
5 | 4 | 3 | 2 | 1 | |
Trunk | Sound and solid throughout | Minor damage | Early decay signs | Extensive decay, hollowness cambium damage | Same as two, but cross-section is a half circle |
Crown | Dense, evenly balanced crown | Dense, slightly unbalanced crown | Thin or severely imbalanced crown | Thin and slightly imbalanced crown | Thin and severely imbalanced crown |
Root | Three or more evenly balanced root flares | Three or more slightly unbalanced root flares | Less than three or severely unbalanced root flares | No root flares & structural root (2 to 15 cm deep) | Structural roots (>15 cm deep) |
Structure | No major limbs missing, broken, or dead no narrow crotches; good radial distribution | Narrow crotch on a major limb | One of major limbs is dead or broken | Two or three major limbs with narrow crotches & one broken or dead major limb | Two or three major limbs with narrow crotches & broken or dead major limbs |
Growth | >15 cm annual twig elongation | 10 - 15 cm annual twig elongation | 5 - 10 cm annual twig elongation | 2 - 5 cm annual twig elongation | <2 cm annual twig elongation |
Pest | No insect or disease problems | Minor insect or disease problems | Minor insect & disease problems | Serious disease or insect problems | Serious disease & insect problems |
Life | >50 years | 30 to 50 years | 20 to 30 years | 10 to 20 years | <10 years |
expectancy |
In order to determine which streets had the most traffic, traffic rates needed to be determined for each street. Traffic rates, measured as cars per day, where obtained through traffic records from the Tennessee Department of Transportation 2011 report for Oak Ridge East Anderson County (TDOT, 2011). Distance from street tree to the nearest stream was determined by using the points collected by the Garmin etrex 20 during the inventory at each street tree, ArcMap 10, and stream vector data from the USGS National Hydrography Dataset (ESRI, 2011; USDA/NRCS, 2012). To determine the distance of each street tree to the nearest stream, the Join function was used in ArcMap to join the streams polyline shapefile to the street tree inventory point shapefile. Joining the two shapefiles by location resulted in a point shapefile with the street tree attributes as well as the attributes of the closest stream and the distance of each tree to that stream.
All soil samples were air dried and passed through a 250 µm (60-mesh) sieve. Total elemental analysis was determined as described by Nadkarni (1984), using microwave oven digestion with modifications. Total elemental analysis of the digested soil samples was analyzed by inductively coupled atomic emission spectrometry (ICP). Exchangeable Ca, K, Mg, Pb, Cd, Mn, Fe, Zn, Ni and Cu were determined by extraction with 1 N ammonium acetate (1NH4OAc, pH 7.0). The pH of the 1NH4OAc was adjusted by adding concentrated ammonium hydroxide. Exchangeable were analyzed by ICP. Sodium saturation method (pH 7.0) was used to determine cation exchange capacity (CEC) (Chapman, 1965). The 1:1 method was used to measure pH. An adaptation of Blake (1965) bulk density for gravelly soils was used to determine the bulk density by dividing each total dry weight (g) by the volume (cm3) of each hole. Gravimetric soil moisture was attained by the difference between soil fresh weight (m) and oven dry weight (d) divided by d using the following equation: Θ g = m − d/d.
The simultaneous chloroform fumigation extraction (sCFE) “slurry” method was adapted from Fierer (2003) for microbial biomass carbon (MBC) and microbial biomass nitrogen (MBN). To analyze total carbon and nitrogen a TOC-VCPH SHIMADZU (detection limit 0.1 ppm) was used. Microbial C biomass was determined using the following equation:
where the chloroform-labile pool (EC) is the difference between C in the fumigated and non-fumigated extracts, and kEC is soil-specific and estimated as 0.45 (Beck et al., 1997). Microbial N biomass was determined using the following equation:
where the chloroform-liable N pool is the difference between N in the fumigated and non-fumigated extracts, and kEN is soil-specific and estimated as 0.54 (Brookes et al. 1985). MBC and MBN were expressed as µg∙N∙g−1. Soil carbon to nitrogen, microbial biomass carbon to nitrogen and microbial carbon to organic carbon ratios were calculated. To analyze total organic carbon the TOC by acidification/sparging method was used. To analyze total nitrogen a TNM-1 SHIMADZU unit was used (detection limit 0.1 ppm).
A Pearson’s two-tailed correlation coefficient in SPSS 21 was used to determine what soil biological, chemical and physical properties were correlated with microbial biomass carbon (MBC) and microbial biomass nitrogen (MBN) in the urban soils at street tree planting locations (IBM Corp. Released 2012). A Principal Components Analysis (PCA) in JMP Pro 10.0.2 was used to determine the soil properties that were the most heavily characterizing the urban soil of Oak Ridge, Tennessee (JMP® (1989-2007), Version Pro 10.0.2). Multivariate Analysis of Variance (MANOVA) was used to measure the variance of different means of dependent variables (elemental concentrations, total C, total known N, soil pH, bulk density, soil microbial biomass MBC and MBN, and soil water content) between the five streets. A one-way Analysis of Variance (ANOVA) using JMP Pro was used to determine the differences between seasons in MBC, MBN, soil water content, and pH. A log10 transformation was used for the MBC and MBN data in order to satisfy the ANOVA assumption of normality. The log10 transformed means were then reverted to its original state by raising it as an exponent over ten: 10^log10 (MBC or MBN). Levenne’s test for unequal variance was done for all ANOVA’s in order to meet ANOVA assumptions. All variables with standard deviation within five fold of each other were also considered to have met the equal variance assumption. A Pearson’s two tailed correlation coefficient and the principal components from the PCA was used to investigate which urban environmental stressors were likely influencing street tree conditions and growth. Urban environmental stressors, elemental concentrations, soil pH, bulk density, soil microbial biomass MBC and MBN, soil water content, tree distance from impervious surface, and distance from closest stream were independent variables that were tested for their influences on the dependent variables, tree condition score and growth.
The number of street trees that were inventoried along the five main thoroughfares in Oak Ridge was 607, with 37 different species. The diameters ranged from 5.08 cm to 93.98 cm and the average diameter of the street trees was 30.3 cm. The general street tree conditions showed 52% (313 trees) as good, 30% (185 trees) fair, 16% (96 trees) poor, and 2% (13 trees) dead. The street tree ecosystems, as a whole, were predominately Acer rubrum (21.91%) and Pyrus calleryana (19.93%). The total diversity index for the five streets was H’ = 1.39. The diversity indices (H’) of each street were Oak Ridge Turnpike 1.81, Lafayette 1.43, Illinois 1.85, Rutgers 1.12, and Tulane 0.75.
Min | Max | Mean | SE | |
---|---|---|---|---|
Tree distance from impervious surface (m) | 0.52 | 19.46 | 4.86 | 0.31 |
Tree distance from stream (m) | 11.46 | 630.18 | 245.35 | 13.60 |
Bulk density (g∙cm−3) | 0.43 | 2.11 | 1.33 | 0.03 |
Bulk density with rocks (g∙cm−3) | 0.43 | 3.21 | 1.46 | 0.04 |
Winter pH | 4.82 | 8.62 | 7.61 | 0.05 |
Spring pH | 5.28 | 8.17 | 7.27 | 0.04 |
Winter gravimetric soil moisture (%) | 20.00 | 69.49 | 29.63 | 0.47 |
Spring gravimetric soil moisture (%) | 8.45 | 43.47 | 23.08 | 0.51 |
Cation exchange capacity (cmol∙kg−1) | 1.43 | 10.40 | 4.88 | 0.13 |
ug∙g−1 | ||||
Winter microbial biomass carbon | 3.74 | 279.18 | 54.20 | 3.54 |
Winter extractable organic carbon | 9.15 | 137.92 | 5.65 | 2.18 |
Winter total labile carbon | 20.01 | 417.10 | 104.50 | 4.83 |
Winter microbial biomass nitrogen | 0.07 | 53.17 | 9.81 | 0.74 |
Winter extractable organic nitrogen | 5.83 | 56.54 | 17.86 | 0.63 |
Winter total labile nitrogen | 8.33 | 109.71 | 27.65 | 1.20 |
Spring microbial biomass carbon | 1.08 | 291.20 | 38.69 | 4.20 |
Spring extractable organic carbon | 61.60 | 499.72 | 186.83 | 7.58 |
Spring total labile carbon | 72.36 | 564.82 | 225.80 | 9.00 |
Spring microbial biomass nitrogen | 0.44 | 39.06 | 7.61 | 0.73 |
Spring extractable organic nitrogen | 9.23 | 61.07 | 20.30 | 0.64 |
Spring total labile nitrogen | 12.56 | 75.66 | 27.97 | 1.00 |
*Extreme outliers were removed. |
tions were found between wMBN and wGSM, Mg, Ni, P, S, Sr, and Zn. The wMBC was found to be significantly (p < 0.05) positively correlated to wGSM, Ca, Cr, Mg, Ni, S, Sr, Zn, and Pb; as well as negatively significantly correlated with Ba. Tree condition scores were significantly (p < 0.05) positively correlated with Ca, tree diameter, live crown ratios (LCR); likewise, tree condition scores were significantly (p < 0.05) negatively correlated with As.
Multivariate Analysis of Variance (MANOVA) was run to compare mean differences between street tree soils’ biological, physical and chemical properties (
One-way ANOVA tests for each seasonal variable showed multiple differences between the two seasons (Prob> F = < 0.05*) (data not shown). Overall, the winter season had significantly higher MBC and MBN. The MBC in the winter had a mean of 54.20 ug∙g−1 while the street tree soil in the spring had a mean MBC of 38.69 ug∙g−1. The wMBN had a mean of 9.81 ug∙g−1 and a spMBN of 7.61 ug∙g−1. Extractable organic carbon (EOC) and total labile carbon (TLC) were both significantly higher in the spring than the winter. EOC had mean spring concentration of 186.83 ug∙g−1 and the winter had a concentration of 50.65 ug∙g−1. TLC in the spring was at a mean concentration of 225.81 ug∙g−1. Extractable organic nitrogen (EON) differed significantly between the two seasons with a mean concentration of 20.30 ug∙g−1 in the spring and 17.86 ug∙g−1 in the winter. Total labile nitro-
Min | Max | Mean | SE | |
---|---|---|---|---|
Analytes | ||||
Aluminum—Al | 17366.67 | 91966.67 | 49397.51 | 1154.64 |
Arsenic—As | 0.7 | 46.72 | 6.22 | 0.49 |
Barium—Ba | 971.17 | 92966.67 | 9866.26 | 942.79 |
Calcium—Ca | 60.47 | 562.83 | 273.07 | 6.84 |
Cadmium—Cd | 0.18 | 2.83 | 1.04 | 0.04 |
Cobalt—Co | 4.5 | 34.9 | 14.57 | 0.47 |
Chromium—Cr | 16.2 | 171.38 | 42.48 | 1.30 |
Copper—Cu | 5.1 | 104.6 | 33.59 | 1.29 |
Iron—Fe | 10966.67 | 53966.67 | 27445.89 | 663.83 |
Potassium—K | 1536.67 | 29583.33 | 11328.44 | 363.91 |
Magnesium—Mg | 948.33 | 37716.67 | 4846.39 | 286.25 |
Manganese—Mn | 65.52 | 4476.67 | 1032.86 | 64.38 |
Molybdenum—Mo | 0.63 | 20.38 | 3.24 | 0.22 |
Sodium—Na | 545.83 | 4591.67 | 2846.06 | 72.20 |
Nickel—Ni | 6.87 | 110.93 | 22.15 | 1.05 |
Phosphorus—P | 114.43 | 1148.33 | 460.11 | 18.25 |
Lead—Pb | 2.68 | 916.5 | 69.07 | 8.91 |
Sulfur—S | 70.83 | 853.67 | 359.71 | 10.96 |
Selenium—Se | 0.63 | 35.85 | 6.95 | 0.54 |
Strontium—Sr | 9.28 | 183.65 | 40.01 | 1.48 |
Titanium—Ti | 571.17 | 3450 | 1579.79 | 38.48 |
Zinc—Zn | 28.30 | 266.23 | 95.96 | 3.25 |
*Analytes were determined for the winter sample and measured as mg∙kg−1. *Extreme outliers were removed.
Means by street | Min | Max | SE | |||||
---|---|---|---|---|---|---|---|---|
Illinois | Lafayette | ORTP | Rutgers | Tulane | ||||
Annual average daily traffic (cars/day) | 26736 | 17160 | 21077 | 11445 | 7032 | |||
Winter microbial biomass carbon (ug∙g−1) | 38.33b | 38.08b | 71.26a | 47.36ab | 56.16ab | 3.74 | 279.18 | 3.54 |
Winter microbial biomass nitrogen (ug∙g−1) | 8.46ab | 6.69b | 12.35a | 7.16ab | 5.29ab | 3.74 | 279.18 | 0.74 |
Tree distance from impervious surface (m) | 5.20ab | 6.44a | 3.74b | 7.74a | 3.52ab | 0.52 | 19.51 | 0.31 |
Bulk density (g∙cm−3) | 1.42a | 1.36ab | 1.32ab | 1.03b | 1.12ab | 0.43 | 2.11 | 0.03 |
Winter gravimetric soil moisture (%) | 27.21b | 27.24b | 31.24a | 34.15a | 28.94ab | 20.00 | 69.49 | 0.47 |
Analytes (mg∙kg−1) | ||||||||
Iron—Fe | 27250.86ab | 23034.25b | 29228.46a | 32936.25a | 22556.25ab | 10966.67 | 53966.67 | 663.83 |
Potassium—K | 13811.23a | 13069.35ab | 9838.81c | 10152.08abc | 8009.17bc | 1536.67 | 29583.33 | 363.91 |
Manganese—Mn | 994.64ab | 643.18b | 1169.67a | 1188.88ab | 1741.42a | 65.52 | 4476.67 | 64.38 |
Phosphorus—P | 559.89a | 326.08b | 472.10a | 546.90a | 454.00ab | 114.43 | 1148.33 | 18.25 |
Sulfur—S | 316.62b | 332.11ab | 396.18a | 372.69ab | 236.76ab | 70.83 | 853.67 | 10.96 |
Zinc—Zn | 94.4abab | 74.32b | 108.79a | 81.35ab | 91.69ab | 28.30 | 266.23 | 3.25 |
*Letters within rows indicate significant difference in means at the 0.05 level. *Extreme outliers were removed.
gen (TLN) did not differ seasonally. The GSM in the winter was also significantly higher than the spring with means of 29.63% water and 23.08%. There was no difference in soil pH between seasons.
Tree condition score was not significantly correlated to physical or biological properties measured (p < 0.05). The physical soil properties and planting site characteristics (tree distance to impervious surface and tree distance to closest stream) were found to have no correlation to street tree performance. However, street tree condition score was significantly positively and negatively correlated to Ca and As, respectively (data not shown). Annual twig elongation (growth) was significantly and positively correlated with Ca as well as spring gravimetric soil moisture (spGSM) (data not shown). Despite the lack of correlation between site properties and tree condition and growth, there were high concentrations of heavy metals other than As found in the street tree soils (
The current status of Oak Ridge’s street trees seems to be in fairly good standing if Emerald Ash Borer (EAB) or walnut twig beetle (the vector for TCD) should hit since the street tree ecosystems are comprised of only 2.31% Fraxinus pennsylvanica and 0.33% Juglans nigra (
The negative correlation with As and tree condition could be an indication that increased amounts of As in Oak Ridge urban soil could harmful to the street trees. Arsenic has been found to inhibit root elongation and could therefore be influencing tree performance (Song et al., 2006). The positive correlation between tree condition and growth with Ca indicate that the street trees tend to have better performance and growth on sites with higher amounts of Ca. Street trees that are receiving higher amounts of Ca could be in better condition and growing more because Ca is vital for the synthesis of cell walls in plants and cell membrane stabilization (Eklund and Eliasson, 1990; Fromm, 2010). The positive correlation with growth and spGSM could be an insight that some street trees in Oak Ridge during the spring had limited water available in their root zones; therefore, growth may have been limited to trees that had less soil moisture at their planting sites. Water availability to street tree is an issue that not only faces urban forest managers, but has also been thoroughly investigated. Excess water as well as drought can have detrimental impacts on urban tree performance (Saebo et al., 2003; Nielson et al., 2007). The positive correlation with tree growth and spGSM in Oak Ridge’s soils may suggest that lack of water may be an issue for the street tree ecosystems. Although these correlations do not indicate causation, this does open doors for more research and possible management directives to be taken. Oak Ridge in particular, may benefit by selecting street trees to plant for dryer sites that are more drought tolerant (Whitlow et al., 1992). Also, further investigation of soil chemicals on tree physiological properties would offer greater insight to the impacts of urban soils on tree growth and condition.
The interactions between site properties with tree condition and growth were further investigated by using a Principal Components Analysis (PCA). Eleven principal components, with eigenvalues over one, accounted for over seventy-three percent of the variance within the data. Since it took eleven components to explain seventy-three percent of the variance within the data, it is apparent that the street tree ecosystem soil in Oak Ridge is variable in its characteristics. In Oak Ridge, the soil and site characteristics that greatly influenced the variance of the data were the winter microbial biomass concentration, distance to impervious surface, and multiple soil chemical concentrations (Al, Fe, P, Cr, Zn, Sr, S, and Ca). When plotting the sample plots by tree score on the first two component axes, there were no apparent groupings based on better tree performance or worse tree performance. A similar study by Scharenbroch and Catania (2012) that used the same tree score method, found that soil texture and pH correlated with tree conditions while tree growth was correlated to wet-aggregate stability, bulk density, pH, soil organic matter (SOM), and particulate organic matter (POM). Their findings seemed to imply that the physical properties of soils impacted the tree conditions and growth. Whereas, Cekestere and Osvalde (2013) found that street and park trees that were in poorer condition were growing in soils that were high in Na, Cl, and Mg; and low in K, Fe, Cu, B. Therefore, chemical concentrations in the latter study were moreover what weighed the heaviest on the ability of street trees to perform.
The soil analyses indicated that urbanization has impacted Oak Ridge’s urban soil biologically, chemically, and physically. Compared to a concurrent study done in area rural forests, Oak Ridge street tree soils had higher Ca, Mg, Cu, Zn, Pb, MBN, MBC, and CEC; whereas, Oak Ridge street tree soils were lower in Mn, Na, and bulk density (Jean-Philippe, unpublished data). The initial correlation matrix showed that there were many soil and site characteristics that were correlated with one another. The correlation matrix also resulted in multiple significant correlations between distance to impervious surfaces, such as concrete, and several soil properties. The pH of Oak Ridge’s street tree soil was not among the variables that correlated with distance to impervious surface; whereas pH has been found in other areas to increase the closer the distance to roadways (Trammell et al., 2011). Trammell et al. (2011) also found that Cd, Cu, Cr, Ni, Zn, and Pb all decreased as distance to interstate increased. This same trend was found in Oak Ridge with Ca, Co, Mn, P, Pb, Sr, S, and Zn. The analyte, K, was the only element that had increasing concentrations as distances to impervious surfaces increased. One reason this trend could be more pronounced in Oak Ridge than the study conducted by Trammell et al. (2011) is that the soil samples for Oak Ridge were taken within the center of the city rather than in forests along the urban interstates. Therefore, Oak Ridge’s urban soils could be subject to more direct anthropogenic inputs. In urban areas, Ca often originates from building materials such as concrete which is incorporated into the soil formation (Orsini et al., 1986). Therefore, it makes sense that Oak Ridge’s street tree soils exhibit the pattern of having higher concentrations of Ca closer to roadways. Furthermore, since Ca can promote alkalinization, the more acidic soils that were found closer to impervious surfaces suggest that there may be inputs, such as fertilizers, that are preventing the soils from being more alkaline (Cekstere and Osvalde, 2013). Fertilizers could also explain the higher concentrations of P closer to impervious surfaces. Pouyat et al. (2007) proposed that the P and K found Baltimore, Maryland urban soils were likely from lawn fertilizers. K, however, had an opposite trend than P in regards to the impervious surfaces in Oak Ridge. The higher amounts of Zn closer to roadways could be from dust of deteriorated vehicle parts, such as tires, that contain Zn (Cekstere and Osvalde, 2013). Some motor fuels have anti-knock agents that contain Mn; thereby, offering a possible explanation for the higher Mn concentrations found closer to the roadways in Oak Ridge (Zayed et al., 1999). Furthermore, decades of Pb based fuels being used for decades within the city likely caused the street tree ecosystem soils to have greater Pb concentrations than the rural forest soils (Mielke and Reagan, 1998). Both wMBC and wMBN were significantly and negatively correlated with distance to impervious surface. This result could be showing the potential of impervious surface to promote more soil microbial biomass. A soil pH near neutral (6-7) is optimal for most soil microbes; therefore, the higher pH and microbial biomass found closer to impervious surfaces could mean that alkaline adapted microbes, such as some cyanobacteria, are more prevalent closer to roadways than other microbes (Sylvia et al., 2005). Further investigation of microbial ecology in street tree soil would provide better understanding for the types of microbes and their functions along roadways.
The impacts of urbanization on the street tree ecosystem soils in Oak Ridge can be seen in the properties and the distribution of the soils along roadways. Firstly, the soils along the roadways biologically, chemically, and physically differed between certain streets (
Chemically, certain the streets differed significantly from each other in Fe, K, Mn, P, S, and Zn concentrations. Although Zn did not differ between Illinois and Tulane (busiest and least busy street), a significant difference was found between ORTP (21077 cars/day) and Lafayette (17160 cars/day) (
The winter soil samples showed higher concentrations of MBC and MBN than the spring as well as significantly lower concentrations of EOC, TLC, and EON. Ros et al. (2009) found that EON was significantly higher in the spring than the winter season which was due to increased soil moisture and temperature that promoted soil microbial activity. The higher EON in the spring in Oak Ridge, along with the significantly less MBN in the spring, shows that as the seasons change the soil microbes were immobilizing soil nutrients into labile organic matter. Both EOC and TLC were significantly greater in the spring which also shows that the MBC was immobilizing nutrients into labile organic matter. These results demonstrate that even though the microbes were acting as a source for soil nutrients, they were allocating them into temporary immobilized pools of labile C and N. Ectomycorrhizae and some plants are able to utilize labile organic nutrients from the soil organic matter (SOM) such as EON, EOC, and TLN (Van Der Heijerdan, 2008). Since the soil samples were taken before the street trees’ buds broke, the soil nutrients may have been held immobile long enough in their different organic forms in order to be allocated to the tree roots rather than lost to the environment. The winter also had wetter soils than the spring, indicated by the significant difference in GSM. Soil moisture and temperature is known to be essential for soil microorganisms and their functioning (Sylvia et al., 2005). Therefore, it makes sense that the season with the most soil moisture would harbor the most MBC and MBN. A study conducted on forest soils in a mixed oak ecosystem in India found that the soil microbial biomass (C & N) was not only higher in the wetter months, but that the winter season had lower soil microbial biomass (C & N) than the spring months (Devi and Yadava, 2006). However, since the spring soil were dryer than the winter soils in Oak Ridge, then the soil microbial biomass seemed to have been impacted by the lack of moisture. The lack of precipitation during the spring sample period in Oak Ridge could have been the factor that led to less MBC and MBN. Devi and Yadava (2006) also suggest that the higher microbial N in the wetter periods could be a mechanism for conserving nutrients during times when losses are likely. Also, the decrease in MBN during from winter to spring could mean that the microbes are not acting as a sink for nutrients. Tessier and Raynal (2003) had a similar finding; the microbes were acting as a source and the understory vegetation was an N sink during the change from winter to spring when nutrient losses are high. In the case of Oak Ridge’s urban forest, this could mean that nutrients are being lost (leached out or volatilized) since there is little to no understory along the street tree plantings. The SOM in Oak Ridge street tree ecosystem soils acted as a temporary sink for the soil nutrients until the trees were ready to have nutrients allocated to them. Therefore, the labile organic C and N served as an alternative sink in the street tree ecosystems since they lack native understory plant species. The predominant vegetation along the roadsides, other than the street trees, is turfgrass. Lawns have been found to exhibit greater N retention than forests; therefore, in order to fully understand the nutrient losses and storage from winter to spring, the C and N in the grass that constitutes the understory of the roadsides must also be tested (Raciti et al., 2008).
When determining the impacts of land-use change on urban soil and site biological, chemical, and physical pro- perties and nutrient dynamics within street tree ecosystems, it was found that Oak Ridge street tree ecosystems differed. Streets with greater street tree diversity overall did not harbor more soil microbial biomass. The most diverse street, Illinois, was one of the lowest streets in wMBC. There were differences found between two other less diverse streets and ORTP, the second most diverse street. However, this finding does not fully support a relationship between street tree diversity and soil microbial biomass. These findings do show that specific street tree species in abundance could influence the soil microbial biomass rather than total tree diversity. The seasonal variation of C and N within street tree ecosystems indicates that even though there is a lack of native understory plants, street tree ecosystems are not experiencing significant nutrient losses from winter to spring. Even though MBC and MBN were significantly less in the spring than that in the winter, the higher levels of EOC, TLC, and EON in the early spring show that the nutrients are being temporarily immobilized into labile forms of C and N that will likely be a nutrient source for the street trees.
Busier streets did not seem to harbor greater amounts of heavy metals than less busy streets. Likewise, the amount of traffic did not seem to inhibit the soil microbial biomass; instead the busiest street had the highest amount of soil microbial biomass. Bulk density also was not higher along street that received more traffic. Proximity to the center could be a greater factor than the actual amount of heavy metals and microbes than the traffic density of the street trees. Also, more management such as lawn fertilization along certain roadways could be a greater influence than traffic amounts.
Financial support for this research was provided by the Department of Forestry, Wildlife and Fisheries at the University of Tennessee, Knoxville (UTK).Special thanks to the City of Oak Ridge, TN for access to street tree study sites.