Characterization of an urban-rural CO 2 /temperature gradient and associated changes in initial plant productivity during secondary succession

Ziska, Lewis H.; Bunce, James A.; Goins, Ernie W

doi:10.1007/s00442-004-1526-2

Cited by 105 publications

(91 citation statements)

References 16 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Measuring the gradient of carbon dioxide between urban and rural locations (e. g. Berry & Colls, 1990a/b;Ziska et al, 2004;George et al, 2007). All of these studies were carried out by stationary measurements.…”

Section: Wwwintechopencommentioning

confidence: 99%

A Mobile Measuring Methodology to Determine Near Surface Carbon Dioxide within Urban Areas

Henninger¹

2011

Air Quality-Models and Applications

View full text Add to dashboard Cite

Section: Wwwintechopencommentioning

confidence: 99%

A Mobile Measuring Methodology to Determine Near Surface Carbon Dioxide within Urban Areas

Henninger¹

2011

Air Quality-Models and Applications

View full text Add to dashboard Cite

“…exhaust (Lovett et al 2000), CO 2 levels are elevated (Pataki et al 2003;Ziska et al 2004), urban heat island effects cause warmer temperatures (Taha 1997), and exotic species propagules are at higher densities (Lonsdale 1999). Together, these variables can be thought of as an "urban influence", and they represent the future conditions all forests may experience as humans continue to modify the environment (Carreiro and Tripler 2005).…”

mentioning

confidence: 99%

Conifer growth and reproduction in urban forest fragments: Predictors of future responses to global change?

2012

View full text Add to dashboard Cite

Global change has a large and growing influence on forests, particularly in urban and urbanizing areas. Compared to rural forests, urban forests may experience warmer temperatures, higher CO 2 levels, and greater nitrogen deposition, with exacerbated differences at urban forest edges. Thus, comparing urban to rural forests may help predict future effects of global change on forests. We focused on the conifer western red-cedar (Thuja plicata) to test three hypotheses: at urban forest edges, relative to rural forests and urban forest centers, trees experience 1) higher temperatures and nitrogen levels, 2) lower seedling recruitment, and 3) greater growth. We additionally tested anecdotal reports that 4) tree seedling recruitment in urban and rural forests is much lower than in "pristine" old-growth forests. To test these hypotheses, we quantified air temperature, soil nitrate, adult T. plicata growth and seedling recruitment in five urban and three rural parks at both forest edges and centers. We also quantified T. plicata recruitment at five old-growth "pristine" sites. Temperatures were highest at urban forest edges, and soil nitrate was highest in urban forests. In urban relative to rural forests, we observed greater T. plicata growth, but no difference in seedling densities. However, seedling densities were lower in urban and rural forests than in old-growth forests. In all, our results suggest urban influences enhance adult T. plicata growth, but not seedling recruitment. Recruitment in urban and rural forests was reduced compared to old-growth forests, implying that fragmentation and logging reduce T. plicata seedling recruitment.

show abstract

“…For example, Gregg et al (2003) found that in urban areas (1) atmospheric CO 2 concentrations were up to 15% higher; (2) nitrogen deposition was significantly higher; (3) aerosol concentrations were up to 200% higher; and (4) tropospheric ozone levels were up to 40% lower. Additionally, the frost-free period (FFP) was at least several weeks longer at the urban Baltimore site than at the rural site (Ziska et al 2004). As noted in Gregg et al (2003), it is possible that there was no enhanced growth in urban areas; rather, suppressed growth in rural areas may have been caused by increased ozone exposure.…”

Section: Potential Impacts Of Urbanization On Nepmentioning

confidence: 99%

“…For first-year vegetation regrowth (e.g. lambsquarters Chenopodium album) on previously fallow land in the Baltimore (Maryland, USA) area, Ziska et al (2004) found that by the end of the growing season aboveground biomass at an urban site was 115% higher than that at a rural site. Similarly, Gregg et al (2003) 202 Diem et al: Urbanization and land -atmosphere carbon exchange reported that Eastern cottonwood Populus deltoides grown in urban areas in New York City had twice as much biomass as the same trees grown in nearby rural areas.…”

mentioning

confidence: 99%

Impacts of urbanization on land-atmosphere carbon exchange within a metropolitan area in the USA

Diem¹,

Ricketts²,

Dean³

2006

Clim. Res.

View full text Add to dashboard Cite

Urbanization can cause changes in carbon fluxes, which, in turn, impacts atmospheric carbon dioxide (CO 2 ) concentrations and possibly global surface temperatures. Using the Atlanta, Georgia, region as a case study, this paper explores the impact of urban expansion from 1973 to 2002 on land -atmosphere carbon exchange. The major objectives were to estimate net ecosystem production (NEP) values for multiple land-cover classes and to link urbanization-induced changes in land-cover to changes in NEP and overall carbon fluxes. The principal data were daily climatic data, year-specific land-cover data, annual net ecosystem exchange (NEE) values, and annual anthropogenic carbon emissions estimates. The principal methods were testing for climatic trends, determining the composition of the land-cover classes, estimating annual NEP values for the land-cover classes, and estimating the overall carbon exchange. The major findings: (1) there were no significant trends for any of the climatic variables; (2) the region was only ~16% urbanized in 1973; however, by 2002, the region was ~38% urbanized; (3) the NEP in 1978-1980 of 443 g C m -2 yr -1 may have continued until 1996-1998, despite the substantial loss of forest land; and (4) net carbon emissions increased from ~150 g in [1978][1979][1980] to ~940 g C m -2 yr -1 in 1996-1998. Therefore, urban expansion greatly increased the carbon emissions of the Atlanta region; however, it is possible that, through increasing the growing-season length as well as increasing nitrogen and CO 2 fertilization, urban expansion may not decrease the region-wide NEP.KEY WORDS: Net ecosystem production · NEP · Net ecosystem exchange · NEE · Urban emissions · Carbon · Carbon dioxide · CO 2 Resale or republication not permitted without written consent of the publisherClim Res 30: [201][202][203][204][205][206][207][208][209][210][211][212][213] 2006 concentrations is through changes in net ecosystem production (NEP). NEP can be defined as follows: NEP = GPP -(R a + R h )where GPP is gross primary production, R a is autotrophic respiration (i.e. respiration by vegetation) and R h is heterotrophic respiration (e.g. soil microbial respiration). NEP is measured using biometric methods (i.e. ecological-inventory technique; Barford et al. 2001, Curtis et al. 2002. NEP is similar to net primary production (NPP), with the major disparity being that R h is not used in the calculation of NPP (i.e. NPP = GPP -R a ). NEP is equivalent to net ecosystem exchange (NEE), with NEE having a negative value if NEP has a positive value. NEE is measured using the eddy-covariance method, which employs towermounted instruments to measure trace gas flux densities between the biosphere and the atmosphere (Baldocchi et al. 1996). The longitudinal dimensions of flux footprints for eddy-covariance towers range from 100 m to several km (Schmid 1994), thus flux values are applicable only at the local scale. Potential impacts of urbanization on NEPThere are multiple ways that urbanization can decrease NEP. The pr...

show abstract

Characterization of an urban-rural CO 2 /temperature gradient and associated changes in initial plant productivity during secondary succession

Cited by 105 publications

References 16 publications

A Mobile Measuring Methodology to Determine Near Surface Carbon Dioxide within Urban Areas

A Mobile Measuring Methodology to Determine Near Surface Carbon Dioxide within Urban Areas

Conifer growth and reproduction in urban forest fragments: Predictors of future responses to global change?

Impacts of urbanization on land-atmosphere carbon exchange within a metropolitan area in the USA

Contact Info

Product

Resources

About