Effects of varying organic matter content on the development of green roof vegetation: a six year experiment

Green roofs can potentially be used to tackle a variety of environmental problems, and can be used as development mitigation for the loss of ground-based habitats. Brown (biodiversity) roofs are a type of green roof designed to imitate brownfield habitat, but the best way of engineering these habitats requires more research. We tested the effects of altering organic matter content on the development of vegetation assemblages of experimental brown (biodiversity) roof mesocosms. Three mulch treatments were tested: (1) Sandy loam, where 10mm of sandy loam mulch (about 3% organic matter by dry weight) was added to 100mm of recycled aggregate; (2) Compost, where the mulch also contained some garden compost (about 6% organic matter by dry weight); and (3) No mulch, where no mulch was added. Mesocosms were seeded with a wildflower mix that included some Sedum acre, and vegetation development was investigated over a six-year period. Species richness, assemblage character, number of plants able to seed, and above-ground plant biomass were measured. Drought disturbance was an important control on plant assemblages in all mulch treatments, but there were significant treatment response interactions. The more productive Compost treatment was associated with larger plant coverage and diversity before the occurrence of a sequence of drought disturbances, but was more strongly negatively affected by the disturbances than the two less productive treatments. We suggest that this was due to the over-production of plant biomass in the more productive treatment, which made the plants more vulnerable to the effects of drought disturbance, leading to a kind of 'boom-bust' assemblage dynamic. The 'ideal' amount of added organic matter for these green roof systems was very low, but other types of green roof that have a larger water holding capacity, and/or more drought resistant plant floras, will likely require more organic matter or fertiliser. Nonetheless, nutrient-supported productivity in green roof systems should be kept low in order to avoid boom-bust plant assemblage dynamics. Research into the best way of engineering green roof habitats should take place over a long enough multi-year time period to include the effects of temporally infrequent disturbances

Effects of recycled aggregate growth substrate on green roof vegetation development: a six year experiment

Green roofs have the potential to address several of the environmental problems associated with urbanisation, and can be used as mitigation for habitats lost at ground level. Brown roofs (a type of green roof) can be used to mitigate for the loss of brownfield habitat, but the best way of designing these habitats remains unclear. This paper reports an experiment to test the effects of different types of recycled aggregate on the development of vegetation assemblages on brown roof mesocosms. Five recycled aggregates were tested: (1) crushed brick, (2) crushed demolition aggregate, (3) solid municipal waste incinerator bottom ash aggregate, (4) a 1:1 mix of 1 and 2, and (5) a 1:1 mix of 3 and 2. Each was seeded with a wildflower mix that also included some Sedum acre and vegetation development was studied over a six-year period. Species richness, assemblage character, number of plants able to seed, and plant biomass were measured. Drought disturbance was the key factor controlling changes in plant assemblage, but effects varied with substrate treatment. All treatments supported a similar plant biomass, but treatments with a high proportion of crushed brick in the growth substrate supported richer assemblages, with more species able to seed, and a smaller amount of Sedum acre. Crushed brick, or recycled aggregates with a high proportion of crushed brick, are recommended as good growth substrate materials for encouraging brown roof plant diversity. This investigation demonstrates the importance of multi-year studies of green roof development for the generation of robust findings

Transport pathways for viruses in a sandstone aquifer

Following the discovery of viable human enteric viruses at depth in a sandstone aquifer in the U.K., a set of tracer experiments was conducted between March 2004 and August 2005 at a test site in a similar sandstone aquifer, using bacteriophages as human virus surrogates. Initial tests showed a range of bacteriophages (PRD1, φX174, H40/1 and MS2) to be transported between two 50 m boreholes, but attempts to identify the transport pathway(s) by tracer tests in packered horizons between boreholes proved unsuccessful. A new inter-borehole tracer test with injection at one borehole and abstraction from a pumping borehole has now been designed with novel instrumentation to identify the lithological horizons transporting viruses. In addition to the detailed descriptions of core available, the array of boreholes has been subjected to extensive geophysical logging (resistivity, natural gamma, optical televiewer) and hydraulic testing (constant discharge tests, single-hole and cross-hole packer tests). On the basis of these data a detailed conceptualisation of the site has been constructed, with a number of hydraulically significant low permeability horizons clearly identified. The new instrumentation allows the viruses and a conservative tracer to be sampled at different horizons in the abstraction borehole while the hole is being pumped. Viruses are enumerated by plaque assay an