LEADER 05894cam  2200625 i 4500001    on1344380261
003    OCoLC
005    20240430153513.0
006    m     o  d        
007    cr unu||||||||
008    220914s2022    ncuab   obm   000 0 eng d
019    1371248806
035    (Sirsi) o1344380261
035    (OCoLC)1344380261 |z(OCoLC)1371248806
040    ERE |beng |erda |cERE |dOCLCQ |dOCLCF |dOCLCO |dERE |dUtOrBLW
043    n-us-nc
049    EREE
090    TD657
100 1  Farley, Lori, |eauthor. |?UNAUTHORIZED
245 10 Influence of permeable interlocking concrete paver performance on infiltration and temperature in an urban watershed / |cby Lori Farley.
264  1 [Greenville, N.C.] : |b[East Carolina University], |c2022.
300    1 online resource (124 pages) : |billustrations (chiefly color), maps
336    text |btxt |2rdacontent
337    computer |bc |2rdamedia
338    online resource |bcr |2rdacarrier
347    text file
347     |bPDF
347     |c5.933 MB
538    System requirements: Adobe Reader.
538    Mode of access: World Wide Web.
502     |bM.S. |cEast Carolina University |d2022
500    Presented to the Faculty of the Department of Geological Sciences
500    Advisor:  Michael O'Driscoll
500    Title from PDF t.p. (viewed March 21, 2024).
520 3  Urbanization is a form of land use change that typically results in an expansion of impervious surfaces and increased soil compaction. These urban-induced changes in watershed hydrology can result in stream channel erosion, degraded water quality and stream aquatic habitat, increased ambient air temperatures, and increased peak flows, all of which pose challenges to stormwater management. Recent efforts to improve stormwater treatment have included the implementation of green stormwater infrastructure (GSI), which include a range of measures that use plant or soil systems, permeable surfaces or other features to store, infiltrate, or evapotranspire stormwater and reduce flows to storm sewer systems and surface waters. Permeable Interlocking Concrete Pavers (PICP) are one type of GSI implemented in urban settings to reduce runoff through infiltration of stormwater at its source. Over the past decade, East Carolina University has been implementing GSI on their Greenville, NC East Campus, and has installed approximately 0.3 hectares (3,000 square meters) of PICPs, to reduce flooding and ponding and urban stormwater impacts to local streams. Surface infiltration rates were measured at 18 PICP, 10 forested, 21 campus lawn, and 12 fractured asphalt locations to evaluate the effectiveness of PICPs on campus. Infiltration rates between the groups were significantly different (p <0.05). The median infiltration rate of PICP sites was 587.41 cm/h and it was estimated that peak discharge to local streams may be reduced by approximately 11.47 cubic feet per second (cfs) with current PICP installations. Regular asphalt (RA) sites were tested for infiltration where fractures in the pavement intersected, with a median infiltration rate of 3.8 cm/h; however, there were not enough data to draw conclusions on the secondary permeability of fractured asphalt in this study. Forested and campus lawn soils had median infiltration rates of 5.46 cm/h and 0.95 cm/h, respectively. A total of 93 soil cone index values (kPa) were taken at campus lawn (n = 63) and forested (n = 30) sites to determine the effect of existing surface conditions on infiltration rates. There was a significant difference between infiltration rates (p = 0.007) and maximum compaction values (p = 0.000) for forested and campus lawn sites. Surface temperatures were taken at each PICP site and RA parking lots for comparison. Recorded surface temperatures for both asphalt and PICP were lowest between 9 pm and 6 am, with the median temperature of asphalt being 1.64 °C warmer. Data collected and analyzed from this study showed that fractured asphalt and campus lawns had significantly lower infiltration rates compared to forested soils and PICP installations. Moreover, relative to PICPs, asphalt displayed elevated surface temperatures for longer periods of time that contribute to local environmental warming. The results in this study indicate that PICPs are effective in sandy soils for the management of stormwater runoff in urban settings as an alternative or addition to traditional gray infrastructure (pipes, ditches, concrete curbs, and culverts), and PICPs have the potential to minimize effects of the UHI by maintaining lower nighttime temperatures and shorter periods of peak temperatures.
504    Includes bibliographical references.
650  0 Urban runoff |zNorth Carolina |zGreenville |xManagement. |=^A10806
650  0 Pavements, Porous |zNorth Carolina |zGreenville. |=^A879069
650  0 Stormwater infiltration |zNorth Carolina |zGreenville. |=^A358603
653    Permeable Interlocking Concrete Pavers
653    Green Stormwater Infrastructure
653    Temperature
655  7 dissertations. |2aat |0(CStmoGRI)aatgf300028029
655  7 Academic theses. |2fast |0(OCoLC)fst01726453
655  7 Academic theses. |2lcgft
655  7 Thèses et écrits académiques. |2rvmgf |0(CaQQLa)RVMGF-000001173
700 1  O'Driscoll, Michael |q(Michael Anthony), |edegree supervisor. |=^A1171680
710 2  East Carolina University. |bDepartment of Geological Sciences. |=^A1066239
856 40  |uhttp://hdl.handle.net/10342/11092 |zAccess via ScholarShip
949     |owjh
994    C0 |bERE
596    1 4
998    5909051