Experiencing innovative biomaterials for buildings: Potentialities of mosses

Journal Pre-proof Experiencing innovative biomaterials for buildings: potentialities of mosses Katia Perini, Paola Castellari, Andrea Giachetta, Claudia Turcato, Enrica Roccotiello PII:

S0360-1323(20)30066-4

DOI:

https://doi.org/10.1016/j.buildenv.2020.106708

Reference:

BAE 106708

To appear in:

Building and Environment

Received Date: 6 November 2019 Revised Date:

24 January 2020

Accepted Date: 30 January 2020

Please cite this article as: Perini K, Castellari P, Giachetta A, Turcato C, Roccotiello E, Experiencing innovative biomaterials for buildings: potentialities of mosses, Building and Environment, https:// doi.org/10.1016/j.buildenv.2020.106708. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2020 Elsevier Ltd. All rights reserved.

1

Experiencing innovative biomaterials for buildings: potentialities of mosses

2

Katia Perini*a, Paola Castellaria, Andrea Giachettaa, Claudia Turcatob, Enrica Roccotiellob

3

*Corresponding author: [email protected] a

4 5 6 7

b

Polytechnic School of the University of Genoa, Architecture and Design Department, Italy

University of Genoa, Department of Earth Life and Environmental Sciences, Laboratory of Plant Biology, Genoa, Italy

8

Abstract

9

Vertical greening systems and green roofs provide ecosystem services in the urban context. Despite

10

the important benefits they provide, economic (initial and maintenance costs) and environmental

11

issues may limit the widespread diffusion of these greening systems. Mosses can be a low-cost and

12

low-maintenance alternative green envelope for large-scale application on existing urban and

13

industrial buildings thanks to their low requirements in terms of growing substrates, low amount of

14

water and nutrients needed, and high desiccation tolerance. The study assesses the’ growing ability

15

of mosses on building materials and low-cost materials, by means of growing tests performed under

16

controlled environmental conditions on horizontal and vertical surfaces. Moss growth depends

17

mainly on the physical characteristics of the materials, although an acidic moss mixture improves

18

species richness. Results show different surface coverage: capillary matting > cement plaster > lime

19

plaster > terracotta brick > slate > quartzite. The water retention capacity and its homogeneous

20

distribution on the growing surface are the limiting factors for moss growth.

21 22

1. Introduction

23

Urban areas pose significant environmental issues that have to be addressed, i.e. poor air quality

24

with high levels of PMx, NO2, O3 (European Environment Agency, 2018), the Urban Heat Island

25

phenomenon (Nakamatsu and Tsutsumi, 2002), the extreme alteration of urban surfaces (waterproof

26

artificial surfaces with low albedo) and water resources and the deterioration of the urban ecosystem

27

(Rees, 1997).

28

Urban greening is able to mitigate Urban Heat Island phenomenon (Alexandri et al., 2008; Armson

29

et al., 2012; Onishi et al., 2010), collect fine dusts and mitigate the vertical dispersion of gaseous

30

pollutants in urban canyons, with a consequent improvement in air, water and soil quality (Dover,

31

2018a; Perini and Roccotiello, 2018). Moreover, plants contribute to decrease the superficial water

32

flow (Livesley et al., 2014) and remove water pollutants (Jackson and Boutle, 2008), to improve

33

human wellbeing (Fjeld et al., 1998; Grahn and Stigsdotter, 2003; Ulrich, 1984) and support

34

biodiversity on an urban scale (Atkins, 2018).

35

Vertical greening systems and green roofs can provide ecosystem services within densely built

36

fabrics, to address a range of challenges facing urban areas (Dover, 2018b; Manso and Castro-

37

Gomes, 2015a). In addition, green envelopes work as thermal (Sadineni et al., 2011) and acoustic

38

protection (Wong et al., 2010) and as passive systems for energy savings (Coma et al., 2017; Pérez

39

et al., 2014a), contributing to building sustainability performances (Eumorfopoulou and Kontoleon,

40

2009; Ottelé et al., 2011). However, installation and maintenance costs of green infrastructure

41

systems, specifically vertical greening systems, are not always balanced within their life span by the

42

(economic) benefits provided (Ottelé et al., 2011; Pérez et al., 2014b; Perini and Rosasco, 2013;

43

Rosasco and Perini, 2019).

44 45

Table 1: Main characteristics of green roofs and vertical greening systems (Bellomo, 2003; Fernández-

46

Cañero et al., 2018; Manso and Castro-Gomes, 2015b; Medl et al., 2017; Ottelé et al., 2011; Pérez and

47

Coma, 2018; Perini and Rosasco, 2016*, 2013; Rosasco, 2018**)

48 49 50 51 52

Green roofs Extensive

Vertical greening systems

Semi-intensive

Intensive

Direct green façade

Indirect green façade – Ground based

Indirect green façade – Wall based

Living Wall Boxes

Living Wall Felt

Depends on plant species

Depends on plant species and supporting material

Depends on planter boxes size, plant species and supporting materials

94 kg/m² + plant species

13 kg/m² + plant species

Creepers planted in the ground and cling directly to the wall

Light support structures for creepers of stainless steel or similar (cables, nets, trellis)

Planter boxes at different heights connected by means of light supporting structures for creepers

Container elements (galvanized steel, polyethylene, or recycled plastic) with organic substrate

Textile or nonwoven felt with pockets. Hydroponics.

-

-

-

-

Scheme/sk etch

Weight

Layers / materials / supportin g structure

2

50-150 Kg/m

Vegetation, substrate (thickness 6-20 cm), filter, drainage, root barrier, protection and water retention layers. Only accessible for maintenance (slope < 100%)

2

120-350 Kg/m

2

>350 Kg/m

Vegetation, substrate Vegetation, substrate (thickness 10-25 (thickness > 25 cm), cm), filter, drainage, filter, drainage, root root barrier, barrier, protection protection and water and water retention retention layers. layers. Pedestrian areas but with a moderate use (slope < 20%)

Pedestrian / recreation areas (slope < 5%)

Succulent, herbaceous and grasses

Herbaceous, grasses and shrubs, perennials

Herbaceous, grasses, shrubs and trees, perennials

Growing speed

Fast

Fast

Medium

Slow

Medium-slow

Medium-fast

Maintena nce

Low

Moderate

High

Low (2-5 €/m²/year)

Low (2-5 €/m²/year)

Low (5-7,5 €/m²/year)

Irrigation

Never or periodically

Periodically

Regularly

Use

Plant characteri stics

Costs

140-250 €/m² *

Mostly climbing and hanging plants

Periodically depending on plants and climate

22-39 €/m² **

127-270 €/m² **

190-365 €/m² (depending on system conception and material) **

Epiphytic, lithophytic and Bromeliads, ferns, succulent, herbaceous, small shrubs, climbers and even vegetables Fast Medium-high (40-100 €/m²/year)

High (40-100 €/m²/year)

Computerized irrigation (1-5 l/m2/day)

210-590 €/m² (depending on system conception and material) **

53

Among the systems available on the market (Table 1), living wall systems can support a wide

54

variety of plant species. An automated irrigation system covering the entire surface provides water

55

and nutrients, according to the position and requirements of each plant species (Fernández-Cañero

56

et al., 2018). Green façades based on climbers are generally cheaper and easy to maintain

57

(Fernández-Cañero et al., 2018; Perini and Rosasco, 2013), but it is worth mentioning that, although

58

the growing speed depends on several parameters (e.g., climate conditions, plant health, amount of

59

soil available and species), it can range from 50 to 200 cm/year (Bellomo, 2003). Therefore

60

climbers planted on the ground in front of a building can take few years to cover the whole

61

buildings’ surface.

62

Currently, few studies have been carried out on overcoming the economic limitations of vertical

63

greening systems, including the development of a new living concrete material, which allows plants

64

to grow directly on it, resulting in a 50% reduction in installation costs, compared to living wall

65

systems, and a reduction in costs of maintenance (Riley et al., 2019).

66

Since the effect of vegetation in cities is more important the more widespread it is, research is

67

needed to find low-cost and low maintenance green envelopes for large-scale application in

68

existing urban (e.g. social housing) or industrial buildings, where environmental and architectural

69

regeneration interventions are often requested.

70

Although mosses can cover and, in some cases, damage buildings, recent studies highlighted their

71

potential use to protect buildings and other urban surfaces (Kaufman, 2016; Park and Murase,

72

2008). Studies on insertion of mosses onto green roofs demonstrate good stormwater management

73

of some moss species (Anderson et al., 2010; Brandão et al., 2017), the ability to decrease surface

74

temperatures (Aisar et al., 2017), contribution to the mitigation of the UHI phenomenon (Khalid et

75

al., 2017) and the feature of being more durable, resistant, light-weight and easy to maintain than

76

vascular plants (Burszta-Adamiak et al., 2019).

77

Mosses are the second most species-rich group of plants, after the enormously richer Angiosperms.

78

a distinct lineage of Bryophytes that consist in about 12,750 recognized species worldwide (Crosby

79

et al., 1999). Mosses have a mop-like structure, dominance of vegetative reproduction and thin

80

“false” roots (rhizoids) that adhere to building surfaces (Aleffi and Tacchi, 2008). Mosses are an

81

almost perfect sink for some elements, being able to tolerate high levels of salinity (salt crusts),

82

metals (e.g., copper mosses) and air pollutants (ability to accumulate PMx), for this reason some

83

taxa are commonly used as bioindicators for air quality monitoring (Aleffi and Tacchi, 2008;

84

Szczepaniak and Biziuk, 2003).

85

Higher plants have several useful characteristics, already extensively listed above, that cannot be

86

found in mosses. However, mosses can survive in unfavourable environmental conditions because

87

of their ecological needs in terms of growing substrates, low amount of water and nutrients

88

required, ability to absorb liquids up to 20 times their weight and vegetative desiccation tolerance

89

(Wood, 2007). Research is needed to clarify the possible use of mosses as green envelopes of

90

building, growing directly on building materials, and to find the most performing species able to

91

sustain stressful conditions such as those found on building surfaces (e.g., wind, solar radiation, air

92

pollution, etc.).

93 94

1.1 Aim of the study

95

The aim of the study is to evaluate whether mosses could be suitable as a green envelope system,

96

i.e. able to grow under limited water requirements and to cover horizontal/vertical surfaces, and

97

under which environmental conditions. Spontaneous growth of mosses on buildings under certain

98

microclimatic conditions is quite common, but research is needed to develop a promising new

99

building coverage system and material.

100

This research assesses the growing ability of mosses directly on building commonly used materials

101

and low-cost materials, with different physical characteristics (structure and porosity). Tests were

102

performed under controlled environmental conditions on horizontal and vertical surfaces to evaluate

103

moss growth rate and homogeneity, level of maintenance required (water needs, physical and

104

chemical influence of moss mixture- i.e., neutro-acidic for buttermilk moss-mixture, pH 5, or

105

alkaline for water-moss mixture, pH 8), moss mixture performance with respect to biomass

106

production. Verifying the growing capacity of mosses on such materials represents the first step for

107

the evaluation of potential uses and performances of mosses as green envelopes.

108 109

2. Materials and Methods

110

The most promising moss taxa were selected by means of field sampling and literature screening.

111

Five building materials were chosen for the subsequent experiments, allowing the identification of

112

the characteristics needed for the mosses to grow. The study includes two experiments, on both

113

horizontal and vertical surfaces, implemented in a growth chamber, described below. 2.1 Moss sampling

114 115

Several taxa were collected in October-November 2018 from different edaphic conditions (e.g.,

116

from soil to plaster, from low to high water availability, from shadow to full sunlight) at 350 m a.s.l.

117

Details on the sampled mosses and related conditions are summarized in table 2. The pHs of the

118

different substrates were also evaluated. Taxa were identified according to Cortini Pedrotti (Cortini

119

Pedrotti, 2001). In moss sampling, it is not possible to count the number of individuals precisely,

120

due to their small size. For this reason 10x10 cm moss samples were collected (Eldridge et al.,

121

2003).

122 123

Table 2: Determination of the sampled plant taxa and their respective habitats (Cortini Pedrotti, 2001).

124 Taxon

Family

Geographical coordinates

Sampling habitat

Common habitat

Isothecium myosuroides Brid.

Brachytheciaceae

44°29’06.28’’ N 8°50’15.18’’E

Soil, shady rocks, under shrubs. Dry stone wall mortar, sunny position.

Barbula unguiculata Hedw.

Pottiaceae

44°29’15.63’’ N 8°50’21.10’’E

Rhynchostegium confertum (Dicks.) Schimp.

Brachytheciaceae

44°29’14.45’’ N 8°50’20.77’’E

Hypnum jutlandicum Holmen & Warncke

Hypnaceae

44°29’16.64’’ N 8°50’21.29’’E

Hypnum sp.

Hypnaceae

44°29’16.19’’ N 8°50’21.15’’E

Rock, sunny position.

Brachythecium salebrosum (Hoffm. ex F. Weber & D. Mohr) Schimp.

Brachytheciaceae

44°29’13.43’’ N 8°50’19.55’’E

Isothecium alopecuroides (Lam. ex Dubois) Isov.

Brachytheciaceae

44°29’11.23’’ N 8°50’18.29’’E

Wood, shaded position in the undergrow th, wet environme nt. Concrete wall, sunny position.

Dry stone wall shaded by brambles and creepers. Rock, semishaded position.

Soil, base of trees, shady rocks, acid environments; from the plain to the mountain. Neutral or baserich, disturbed and open habitats such as the edges of paths, gardens, fields and old walls. Stones, rocks, walls, old stumps, damp, and shaded environments, both basic and acid. Soil, rocks, tree base, rotting wood, edge of marshes, dry or wet environments, exposed or shaded. Wide variety of habitats and climatic zones. It typically grows on tree trunks, logs, walls, rocks and other surfaces. It prefers acidic environments and is quite tolerant of pollution (Vujičić et al. 2011). Soil, rocks, stumps, base trees, humus forests, shaded environments, acids.

Base of trees, stumps and damp rocks, shady forests, along streams of water, rarely on stony ground.

125 126

2.2 Selection of plant taxa

127

Among the sampled species, a screening was carried out to evaluate the greatest resistance to

128

climatic conditions based on the ecological characteristics of each taxa as a discriminating factor.

129

Basing on literature and ecological requirements (wide species distribution, low water requirements,

130

good coverage, high adaptability to different temperatures), Barbula unguiculata was the species

131

chosen for subsequent growing experiment due to its ability to be more resistant than other sampled

132

taxa with respect to high light radiation level and strong dehydration, and to be able to grow on

133

walls and rocks with alkaline pHs (Segal, 2013). 2.3 Selection of building materials

134 135

Five common (building) materials were selected, considering structure and porosity of the surface

136

(Dassori, 2011). In addition to building materials – i.e. quartzite, plaster, slate, and brick – capillary

137

matting, and gauze were chosen because of their application for floricultural purposes or their

138

previous use to grow mosses (Park and Murase 2008), respectively. As shown in Table 3, the

139

materials selected have different uses (e.g. coating, external and internal flooring, masonry,

140

finishing of exterior and interior walls, growing plants) and physical characteristics. To implement

141

the experiment, quartzite, slate, bricks and plaster were treated with the addition of gauze, as

142

reported in literature (Kaufman, 2016). Lime and cement-based plasters were treated with a trowel

143

to obtain a rougher surface, to allow better adhesion of the moss mixture.

144 145 146 147

Table 3: Materials used for the experiment and related uses, characteristics and eventual surface treatment (Dassori 2011). Photo

Material

Common use

Physical characteristics

Surface treatment waterproof with a structured As is surface

Quartzite plates

coatings

Slate plates

roofing, external and waterproof with a structured As is internal flooring, surface coverings

Full bricks masonry, floors in terracotta coverings

and very porous with a structured As is surface

Lime based finishing of exterior very porous with a structured with a trowel finishing and interior walls surface. Holds moisture to obtain a plaster rougher surface

Finishing finishing of exterior very porous with a structured plaster based and interior walls surface. Holds moisture on white cement

Capillary matting

Gauze

with a trowel to obtain a rougher surface

water irrigation system in fabric, covered with a As is. for indoor plants, seed perforated plastic membrane The capillary trays, greenhouses on both sides, retains moisture matting was tested both by keeping both membranes and by removing one used to support rooting cotton net that promotes As is. of moss rhizoids on a rhizoid attachment and The gauze vertical surface moisture retention was applied (Kaufman, 2016) on half of each traditional building material considered

148 149

2.4 Experimental design and set up

150

Two experiments in growth chamber were set up to establish the response in terms of biomass

151

development on the different building materials used as growing support for the moss mixture,

152

under controlled temperature and light and adequate water supply on horizontal and vertical

153

surfaces. Since water could be a limiting factor in the development of new (vegetative) biomass and

154

water flows easily on vertical surfaces, the experiment on horizontal surface was carried out first.

155

The cultivation methods used direct application of the moss mixture onto the material surfaces.

156

The tests were divided into two experiments (Figure 1): 1) horizontal surface to identify the moss

157

response in terms of growth, with homogeneous water distribution and incident light (i.e. the light

158

that directly falls on the leaf surfaces), and to obtain information on the optimal water supply and

159

better growing support for the moss mixture to develop new biomass and 2) vertical surface to test

160

the same species with different water distribution and mixture response to gravity. The experiment

161

on vertical surface was conducted on the most promising materials obtained after the test on

162

horizontal surface.

163

The experimental design can be applied to other species, adapting the supply of water and light.

164 165 166

167

Figure 1: scheme of the experimental set-up.

168

2.4.1

Test on horizontal surface

169

The moss was cleaned from substrate residues and weighed. Dried B. unguiculata was hydrated

170

with 1:2 (w/v) deionized water. After removing the excess of water, the moss increased by about

171

2/3 its weight.

172

Two types of moss application were prepared.

173

1). Moss: water (1:2) mixture obtained by blending hydrated mosses;

174

2). Moss: water: buttermilk 1:2:0.2 obtained by blending hydrated mosses with the addition

175

of buttermilk.

176

The mixtures of gametophytes of B. unguiculata were placed with a spatula to obtain a spot (about

177

1 mm thick and 5x5 cm wide) on the surfaces on different materials used. Each spot weighs

178

approximately 3.80 g, corresponding to 1.52 kg/m². Half of them were covered with gauze, except

179

for the capillary matting, for each growing surface 8 replicates were done (n=8 each covered

180

material and n=8 each uncovered material, as explained in figure 1).

181

Each application spot was clearly separated from the others, to avoid cross-contamination.

182

The felt was placed in an open Petri dishes (glass-made) with and without its upper semi-waterproof

183

film and submitted to hydration up to 70% WHC.

184

The mosses applications were monitored once a day, for 4 months (i.e. development of new

185

biomass , reached after about 3 months and kept under control for 1 month). Each spot was

186

hydrated by spraying the surface with approximately 4 ml of deionized water for the first 40 days.

187

The capillary matting was imbibed with the same amount of water.

188

Afterwards, the amount of water was increased to 6.5 ml due to the thickening of the moss cushions

189

with the production of new biomass.

190

Each material was moved regularly every 2 days to ensure that each of them received the same

191

amount of light as the others.

192

Gametophytes mixture was incubated in a growth chamber at 18±2°C, 20 µM/m²s light intensity,

193

photoperiod 12/12, 60% of relative humidity.

194

Each spot was photographed once a week to study the evolution of each application.

195

2.4.2

Test on vertical surface

196

Once the most effective materials, in terms of adhesion of the moss mixture and water capacity and

197

distribution, and application techniques, in term of growing capacity and new biomass production,

198

were established with horizontal experimentation, tests began on the vertical surface.

199

The materials were also chosen based on their characteristic surface roughness, to avoid moss

200

washout. The materials (covered and uncovered with gauze) selected for the vertical experiments

201

were: brick, lime-based plaster, cement-based plaster and capillary matting without waterproof

202

membrane. For each material 8 replicates were made. Each replicate consisted of a portion of

203

material approximately 5x5 cm and they were glued in groups of 4 on a 20x20 cm PVC panel.

204

It was decided to adopt the compound consisting of moss and water, based on the results obtained in

205

the previously reported experiment. Application on the materials was performed differently from

206

the tests carried out during the first phase, that is by dipping a brush in the compound and spreading

207

the moss on the different materials.

208

The panels were hung from the grids inside the growth chamber, so that each of them received

209

direct light from the lamps.

210

Each spot was sprayed once a day with 10 ml of deionized water and panels were rotated every 3

211

days and moved off the shelf to partially reproduce less controlled conditions, such as in a natural

212

environment.

213

In addition, a constant daily water supply was provided on capillary matting. Capillary matting

214

strips were applied to transfer water from a beaker to capillary matting samples on 8 replicates.

215

2.4.3

Data acquisition and processing

216

In order to analyse the surface covered by mosses, high resolution photographs were taken for each

217

sample. In order to compare the surface covered by each sample, a portion corresponding to 4 x 4

218

cm was extracted from the photographs and analysed with Adobe Photoshop and ImageJ software.

219

ImageJ (http://imagej.nih.gov/ij/) allowed quantifying the coverage percentage of moss with respect

220

to the whole image.

221

2.4.4

Data analysis

222

One-way ANOVA with Tukey post-hoc test was performed to evaluate significant differences

223

among the selected moss mixture and substrates for the mosses applications on horizontal surface.

224

Results were presented as average (±standard deviations).

225 226

3. Results and Discussion

227

After two months of incubation new moss biomass was produced. The first results show that the

228

growing support is important for its physical characteristics because of its high-water retention and

229

homogeneous water distribution ability. Vertical surfaces have more physical limitations in terms of

230

water distribution and adhesion of moss mixture to the surface.

231

On horizontal surfaces the moss grows with preference: Capillary matting (67%) > cement plaster

232

(56%) > lime plaster (47%) > terracotta brick (35%) > slate (31%) > quartzite (8%).

233

The tests result on horizontal surfaces, under constant light conditions, show that the limiting

234

factors are given by the water distribution and by the physical (i.e., surface roughness and porosity

235

of the substrate that imply a better adhesion of the moss mixture) rather than the chemical (i.e.,

236

buttermilk-moss mixture vs. water-moss mixture) characteristics.

237

The coverage analyses on horizontal surfaces after 4 months show that capillary matting has the

238

highest performances in terms of moss growth, up to a maximum of 72% (samples with buttermilk

239

without waterproofing layer, table 4). The second interesting response is given by finishing cement

240

plaster where moss coverage reaches a maximum of 67% (samples with buttermilk and gauze and

241

water without gauze, table 4). The last potentially useful growing substrate is the finishing lime-

242

based plaster where moss coverage is up to 47% (samples with buttermilk and gauze, table 4). The

243

average moss coverage on terracotta bricks, slate and quartzite is not satisfying (35, 31 and 8%,

244

respectively, table 4).

245 246

Table 4: Binary images of the samples and mosses coverage (horizontal surfaces).

247 248 249

Error! Not a valid link.

250

ability (biomass production) of B. unguiculata (under controlled environmental conditions in a plant

251

growth chamber) on horizontal and vertical surfaces, mainly depends on the moss mixture together

252

with water accumulation and distribution (with and without gauze) and, subsequently, by physical

253

characteristics of the growing support for the moss mixture.

254

The one-way ANOVA (Fig. 2) highlights significant coverage differences among the moss mixtures

255

for different building surfaces. The highest moss coverage is shown on cement plaster, specifically

256

for buttermilk moss mixture and water moss mixture.

This study shows that mosses can grow on common building and low-cost materials. The growing

80

70

Coverage (%)

60

50

40

30

20

10

0 B

BG

W

WG

Moss mixture

257

Quartzite

Slate

Brick

Lime plaster

cement plaster

258 259

Figure 2. One-way ANOVA of moss coverage (%) respect to moss mixture (B: buttermilk mixture; BG:

260

buttermilk mixture with gauze; W: water mixture; WG: water mixture with gauze) on the different building

261

materials used as substrates. n=8 each moss mixture.

262 263 264

However, the qualitative stereomicroscope analysis shows that quartzite, brick, lime and cement

265

plaster seems to favour the almost exclusive presence of B. unguiculata, although a different taxon

266

(pleurocarpous moss, i.e., branched) is quite ubiquitous (with low coverage) in the different

267

substrates and mixtures. On the other hand, capillary matting houses numerous morphologically

268

distinguishable taxa favouring higher biodiversity, especially in the presence of a more acid

269

environment (obtained by adding buttermilk to the moss mixture). They can therefore be more

270

interesting in ecological terms.

271

The tests result on vertical surfaces allow verifying that, in the presence of strong steepness, the

272

water retention and distribution capacity of the substrate represents the major limiting factor for the

273

growth of moss and production of new biomass. On vertical surface, two main problems persist: (1)

274

washing away of the mixture over time on slate, quartzite, plaster and, in part, on brick if they are

275

not covered with a gripping support such as gauze (applied on the surface); (2) water absorption and

276

distribution capacity (key factor more evident than in horizontal tests).

277

Clearly different results were obtained between irrigation once a day (1.5 ml/cm2) with water

278

sprayed on moss spot and capillary water irrigation with no dehydration phase (1.9 ml/cm2), with

279

the same materials: constant irrigation led to the formation of faster biomass (i.e. growth period of 2

280

months vs. 15 days). The coverage analyses on the vertical water capillary matting (water mixture,

281

without waterproofing layer) revealed a low performance of this material when used vertically

282

(10.4%). Capillary matting system has the best overall performance. Even if this is the only material

283

on which moss grew vertically, an adequate irrigation system will help overcome the low coverage

284

on vertical surface linked to unequal water distribution.

285

A possible way to limit the washing away on vertical surfaces could be a mixture added with

286

colloidal substances that allows moss to generate new biomass (especially during the initial

287

adhesion and growth phase). Since the irrigation system remains the focal point for obtaining a

288

functional vertical greening system with low water costs, a little and constant water supply is more

289

efficient, especially during the first biomass production, with a subsequent decrease once the moss

290

cushion is formed (as it can retain moisture more easily).

291

Compared to Kaufman 2016, in which methods were tested to allow moss adhesion to jersey road

292

barriers, the present study highlights that the moss mixture can adhere to porous surfaces and

293

structured verticals - i.e. capillary matting, gauzed surfaces - but needs further study about the

294

smoothest surfaces - i.e. traditional building materials. Moreover, it highlights the need to design a

295

specific water system to guarantee the production of new biomass without the washing away

296

phenomenon, and at the same time to guarantee good evapotranspiration capacity, as indicated in

297

Park and Murase 2008, for lowering superficial temperature of buildings.

298

Mosses may contribute to ecosystem services provision in urban areas (Aisar et al., 2017; Anderson

299

et al., 2010; Brandão et al., 2017; Burszta-Adamiak et al., 2019; Khalid et al., 2017). In particular,

300

B. unguiculata is able to withstand high concentrations of pollutants (e.g., CKD emitted by cement

301

plant contains 40%–50% CaO, 12%–17% SiO2, 6%–9% K2O, 4%–8% SO3, 3%–5% Al2O3, 2%–

302

4% MgO, 2.8%–3.2% Fe2O3, in small amounts Mn, Zn, Cu and B) such as alkaline cement-dust

303

pollution (Paal and Degtjarenko, 2015) and is particularly tolerant to drying (Guo and Zhao, 2017).

304

The tests conducted show that, on horizontal surfaces compared to vertical ones, moss can grow on

305

a greater quantity of materials and it can be hydrated less frequently, since the water does not flow

306

away from the surface. However, it is possible to grow moss even on vertical surfaces by finding

307

the right support material (more porous to prevent the moss from being washed away, like capillary

308

matting) and minimal but constant irrigation, especially during the first phase, in which vegetative

309

reproduction takes place. The search for a suitable moss species (able to withstand variations in

310

light intensity, temperature and humidity), optimal support materials and the type of irrigation are

311

therefore the focal points for the success of the tests.

312

4. Conclusions

313

B. unguiculata can grow on commonly used building materials and alternative low-cost materials.

314

The growing ability (biomass production and surface covered) of the selected species depends on

315

the physical characteristics of the growing support for the moss mixture. The chemical composition

316

of the substrate does not influence moss coverage but the presence of a more acidic environment

317

(obtained with the addition of buttermilk in the moss mixture) increases the species richness. The

318

most influential physical characteristics involve water, in terms of retention capacity and

319

homogeneous distribution.

320

The tests under controlled environmental conditions showed that:

321

-

is capillary matting. On horizontal surfaces,

322 323

-

-

328

on vertical surfaces attention should be paid to water distribution and adhesion of moss mixture to the surface;

326 327

interesting results were also found for cement-based plaster (coverage of 56% on average) and lime-based plaster (coverage of 47% on average);

324 325

the most performing material for the moss growth on both horizontal and vertical surfaces

-

Irrigation system design to allow constant water provision is important for moss growth: low and constant water supply provides faster moss biomass development.

329

The results obtained so far show that the use of mosses in built environments could represent an

330

interesting and affordable solution for both horizontal and vertical surfaces. This type of greening –

331

with a single layer and low-cost materials – could allow overcoming the limits deriving from the

332

installation costs and maintenance needs of many greening systems available on the market (table 1)

333

(Perini and Rosasco, 2013). Although research is needed to quantify the ecosystem services which

334

moss walls and roofs could provide in urban areas (Aisar et al., 2017; Anderson et al., 2010; Heim

335

et al., 2014; Paal and Degtjarenko, 2015), this study shows an interesting potential for the

336

development of a system. This approach could stimulate the greening of existing buildings with low

337

budget availability, such as residential buildings in low income suburbs and neighbourhoods,

338

industrial areas, etc.

339

The tests also highlighted some challenges for the future development of a moss greening system,

340

i.e. water distribution and adhesion of moss mixture. Future research should be oriented on such

341

aspects. The adaptability of mosses to different environmental conditions will also be tested on site

342

and the performances will be evaluated.

343

This interdisciplinary study between plant biology and architecture provides a more comprehensive

344

way to identify new perspectives for greening urban surfaces.

345

346

Acknowledgements

347

The research was supported by PRA 2018 funding (Progetti di Ricerca di Ateneo 2018),

348

provided by the University of Genoa – DAD. Thanks are expressed to Davide Dagnino for

349

his helpful support during mosses identification.

350 351

References

352 353

Aisar, A., Katoh, Y., Katsurayama, H., Koganei, M., Mizunuma, M., 2017. Effects of convection heat transfer on Sunagoke moss green roof: A laboratory study. https://doi.org/10.1016/j.enbuild.2017.11.043

354 355

Aleffi, M., Tacchi, R., 2008. Caratteristiche generali e sistematiche delle Bryophyta (Muschi). Antonio Delfino Editore.

356 357 358

Alexandri, E., Jones, P., Mantzakou, Ã., 2008. Temperature decreases in an urban canyon due to green walls and green roofs in diverse climates. Building and Environment 43, 480–493. https://doi.org/10.1016/j.buildenv.2006.10.055

359 360

Anderson, M., Lambrinos, J., Schroll, E., 2010. The potential value of mosses for stormwater management in urban environments. https://doi.org/10.1007/s11252-010-0121-z

361 362 363

Armson, D., Stringer, P., Ennos, A.R., 2012. The effect of tree shade and grass on surface and globe temperatures in an urban area. Urban Forestry & Urban Greening 11, 245–255. https://doi.org/10.1016/J.UFUG.2012.05.002

364 365

Atkins, E., 2018. Green Streets as Habitat for Biodiversity, in: Nature Based Strategies for Urban and Building Sustainability. Elsevier, pp. 251–260. https://doi.org/10.1016/B978-0-12-812150-4.00023-9

366

Bellomo, Antonella., 2003. Pareti verdi : linee guida alla progettazione. Esselibri.

367 368 369

Brandão, C., Cameira, M. do R., Valente, F., Cruz de Carvalho, R., Paço, T.A., 2017. Wet season hydrological performance of green roofs using native species under Mediterranean climate. Ecological Engineering 102, 596–611. https://doi.org/10.1016/j.ecoleng.2017.02.025

370 371 372

Burszta-Adamiak, E., Fudali, E., Kolasińska, K., Łomotowski, J., 2019. A pilot study on improve the functioning of extensive green roofs in city centers using mosses. https://doi.org/10.22630/PNIKS.2019.28.1.11

373 374 375

Coma, J., Pérez, G., de Gracia, A., Burés, S., Urrestarazu, M., Cabeza, L.F., 2017. Vertical greenery systems for energy savings in buildings: A comparative study between green walls and green facades. Building and Environment 111, 228–237. https://doi.org/10.1016/j.buildenv.2016.11.014

376

Cortini Pedrotti, Carmela., 2001. Flora dei muschi d’Italia. Antonio Delfino Editore.

377 378

Crosby, M.R., Magill, R.E., Allen, B., He, S., 1999. A checklist of the mosses. St. Louis, Missouri Botanical Garden.

379 380

Dassori, E., 2011. Costruire l’architettura: tecniche e tecnologie per il progetto, Costruzioni, architettura e design. Tecniche nuove, Milano.

381 382

Dover, J.W., 2018a. Introduction to Urban Sustainability Issues: Urban Ecosystem. Nature Based Strategies for Urban and Building Sustainability 3–15. https://doi.org/10.1016/B978-0-12-812150-4.00001-X

383 384 385

Dover, J.W., 2018b. Chapter 1.1 - Introduction to Urban Sustainability Issues: Urban Ecosystem, in: Pérez, G., Perini, K. (Eds.), Nature Based Strategies for Urban and Building Sustainability. Butterworth-Heinemann (Elsevier), Oxford, United Kingdom, pp. 3–15. https://doi.org/10.1016/B978-0-12-812150-4.00001-X

386

Eldridge, D., Skinner, S., Entwisle, T.J., 2003. Survey Guidelines for Non-Vascular Plants 45.

387 388 389

Eumorfopoulou, E.A., Kontoleon, K.J., 2009. Experimental approach to the contribution of plant-covered walls to the thermal behaviour of building envelopes. Building and Environment 44, 1024–1038. https://doi.org/10.1016/J.BUILDENV.2008.07.004

390

European Environment Agency, 2018. Air quality in Europe - 2018.

391 392 393 394

Fernández-Cañero, R., Pérez Urrestarazu, L., Perini, K., 2018. Chapter 2.1 - Vertical Greening Systems: Classifications, Plant Species, Substrates, in: Pérez, G., Perini, K. (Eds.), Nature Based Strategies for Urban and Building Sustainability. Butterworth-Heinemann (Elsevier), Oxford, United Kingdom, pp. 45–54. https://doi.org/10.1016/B978-0-12-812150-4.00004-5

395 396 397

Fjeld, T., Veiersted, B., Sandvik, L., Riise, G., Levy, F., 1998. The Effect of Indoor Foliage Plants on Health and Discomfort Symptoms among Office Workers. Indoor and Built Environment 7, 204–209. https://doi.org/10.1159/000024583

398 399

Grahn, P., Stigsdotter, U.A., 2003. Landscape planning and stress. Urban Forestry & Urban Greening 2, 1– 18. https://doi.org/10.1078/1618-8667-00019

400 401

Guo, Y., Zhao, Y., 2017. Effects of storage temperature on physiological characteristics and vegetative propagation of desiccation-tolerant mosses. https://doi.org/10.5194/bg-2017-368

402 403 404

Heim, A., Lundholm, J., Philip, L., 2014. The impact of mosses on the growth of neighbouring vascular plants, substrate temperature and evapotranspiration on an extensive green roof. https://doi.org/10.1007/s11252-014-0367-y

405

Jackson, J.I., Boutle, R., 2008. Ecological functions within a Sustainable Urban Drainage System.

406 407 408 409

Kaufman, M.A., 2016. A Feasibility Growth Study of Native Mosses Associated with Self-Sustaining Flora on Vertical Infrastructure, in: International Conference on Transportation and Development 2016: Projects and Practices for Prosperity - Proceedings of the 2016 International Conference on Transportation and Development. pp. 683–695. https://doi.org/10.1061/9780784479926.063

410 411

Khalid, M.A.A., Katoh, Y., Katsurayama, H., Koganei, M., Mizunuma, M., Awata, Y., Senin, M.W.A., 2017. Thermal Relaxation by Sunagoke Moss Green Roof in Mitigating Urban Heat Island 17, 14.

412 413 414

Livesley, S.J., Baudinette, B., Glover, D., 2014. Rainfall interception and stem flow by eucalypt street trees – The impacts of canopy density and bark type. Urban Forestry & Urban Greening 13, 192–197. https://doi.org/10.1016/J.UFUG.2013.09.001

415 416

Manso, M., Castro-Gomes, J., 2015a. Green wall systems: A review of their characteristics. Renewable and Sustainable Energy Reviews 41, 863–871. https://doi.org/10.1016/j.rser.2014.07.203

417 418

Manso, M., Castro-Gomes, J., 2015b. Green wall systems: A review of their characteristics. Renewable and Sustainable Energy Reviews 41, 863–871. https://doi.org/10.1016/j.rser.2014.07.203

419 420

Medl, A., Stangl, R., Florineth, F., 2017. Vertical greening systems – A review on recent technologies and research advancement. Building and Environment 125. https://doi.org/10.1016/j.buildenv.2017.08.054

421 422 423

Nakamatsu, R., Tsutsumi, J.-I.G., 2002. RELATIONS OF ENERGY CONSUMPTION AND LOCAL CLIMATE Diurnal Energy Mean Ta ( C ) Max . Ta ( C ) Min . Ta ( C ) Diurnal Energy Mean Ta ( C ) Max . Ta ( C ) Min . Ta ( C ) Diurnal Energy Mean Ta ( C ) Max . Ta ( C ) Min . Ta ( C ). Civil Engineering 1–4.

424 425 426

Onishi, A., Cao, X., Ito, T., Shi, F., Imura, H., 2010. Evaluating the potential for urban heat-island mitigation by greening parking lots. Urban Forestry & Urban Greening 9, 323–332. https://doi.org/10.1016/j.ufug.2010.06.002

427 428 429

Ottelé, M., Perini, K., Fraaij, A.L.A., Haas, E.M., Raiteri, R., 2011. Comparative life cycle analysis for green façades and living wall systems. Energy and Buildings 43, 3419–3429. https://doi.org/10.1016/j.enbuild.2011.09.010

430 431

Paal, J., Degtjarenko, P., 2015. Impact of alkaline cement-dust pollution on boreal Pinus sylvestris forest communities: a study at the bryophyte synusiae level.

432 433 434

Park, J.-E., Murase, H., 2008. Evapotranspiration efficiency of sunagoke moss mat for the wall greening on the building, in: American Society of Agricultural and Biological Engineers Annual International Meeting 2008, ASABE 2008. pp. 3612–3621.

435 436 437

Pérez, G., Coma, J., 2018. Chapter 2.3 - Green Roofs Classifications, Plant Species, Substrates, in: Pérez, G., Perini, K. (Eds.), Nature Based Strategies for Urban and Building Sustainability. Butterworth-Heinemann (Elsevier), Oxford, United Kingdom, pp. 65–74. https://doi.org/10.1016/B978-0-12-812150-4.00006-9

438 439 440

Pérez, G., Coma, J., Martorell, I., Cabeza, L.F., 2014a. Vertical Greenery Systems (VGS) for energy saving in buildings: A review. Renewable and Sustainable Energy Reviews 39, 139–165. https://doi.org/10.1016/j.rser.2014.07.055

441 442 443

Pérez, G., Coma, J., Martorell, I., Cabeza, L.F., 2014b. Vertical Greenery Systems (VGS) for energy saving in buildings: A review. Renewable and Sustainable Energy Reviews 39, 139–165. https://doi.org/10.1016/J.RSER.2014.07.055

444 445 446

Perini, K., Roccotiello, E., 2018. Vertical greening systems for pollutants reduction, in: Nature Based Strategies for Urban and Building Sustainability. Butterworth-Heinemann, pp. 131–140. https://doi.org/10.1016/B978-0-12-812150-4.00012-4

447 448 449

Perini, K., Rosasco, P., 2016. Is greening the building envelope economically sustainable? An analysis to evaluate the advantages of economy of scope of vertical greening systems and green roofs. Urban Forestry & Urban Greening. https://doi.org/10.1016/j.ufug.2016.08.002

450 451

Perini, K., Rosasco, P., 2013. Cost–benefit analysis for green façades and living wall systems. Building and Environment 70, 110–121. https://doi.org/10.1016/j.buildenv.2013.08.012

452 453

Rees, W.E., 1997. Urban ecosystems: the human dimension. Urban Ecosystems 1, 63–75. https://doi.org/10.1023/A:1014380105620

454 455 456

Riley, B., de Larrard, F., Malécot, V., Dubois-Brugger, I., Lequay, H., Lecomte, G., 2019. Living concrete: Democratizing living walls. Science of The Total Environment 673, 281–295. https://doi.org/10.1016/j.scitotenv.2019.04.065

457 458 459

Rosasco, P., 2018. Chapter 4.4 - Economic Benefits and Costs of Vertical Greening Systems, in: Pérez, G., Perini, K. (Eds.), Nature Based Strategies for Urban and Building Sustainability. Butterworth-Heinemann (Elsevier), Oxford, United Kingdom, pp. 291–306. https://doi.org/10.1016/B978-0-12-812150-4.00027-6

460 461

Rosasco, P., Perini, K., 2019. Selection of (Green) Roof Systems: A Sustainability-Based Multi-Criteria Analysis. Buildings 9, 134. https://doi.org/10.3390/buildings9050134

462 463 464

Sadineni, S.B., Madala, S., Boehm, R.F., 2011. Passive building energy savings: A review of building envelope components. Renewable and Sustainable Energy Reviews 15, 3617–3631. https://doi.org/10.1016/J.RSER.2011.07.014

465

Segal, S., 2013. Ecological notes on wall vegetation.

466 467

Szczepaniak, K., Biziuk, M., 2003. Aspects of the biomonitoring studies using mosses and lichens as indicators of metal pollution. Environ. Res. 93, 221–230. https://doi.org/10.1016/s0013-9351(03)00141-5

468 469

Ulrich, R., 1984. View through a window may influence recovery from surgery. Science 224, 420–421. https://doi.org/10.1126/science.6143402

470 471 472

Wong, N.H., Kwang Tan, A.Y., Tan, P.Y., Chiang, K., Wong, N.C., 2010. Acoustics evaluation of vertical greenery systems for building walls. Building and Environment 45, 411–420. https://doi.org/10.1016/J.BUILDENV.2009.06.017

473 474

Wood, A.J., 2007. The nature and distribution of vegetative desiccation-tolerance in hornworts, liverworts and mosses. bryo 110, 163–177. https://doi.org/10.1639/0007-2745(2007)110[163:IENFIB]2.0.CO;2

475

Highlights •

Mosses can be a low-cost and low-maintenance alternative to green envelope

•

Mosses have high vegetative desiccation tolerance and low growing requirements

•

Capillary matting, cement and lime plaster are suitable for horizontal moss growth

•

Water distribution limits mosses’ growth on vertical applications

Declaration of interests ☒ The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper. ☐The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: