Please wait a minute...
Journal of Arid Land
Journal of Arid Land  2023, Vol. 15 Issue (8): 989-1005    DOI: 10.1007/s40333-023-0024-5     CSTR: 32276.14.s40333-023-0024-5
Research article     
Saxicolous lichen communities in three basins associated with mining activity in northwestern Argentina
Juan M HERNÁNDEZ1,*(), Renato A GARCÍA2, Edith R FILIPPINI3, Cecilia ESTRABOU3, Martha S CAÑAS1, Juan M RODRÍGUEZ3
1Faculty of Technology and Applied Sciences, Regional Centre of Energy and Environment for Sustainable Development, National University of Catamarca, Catamarca 4700, Argentina
2Laboratory of Biodiversity and Environmental Genetics, National University of Avellaneda, Avellaneda 1870, Argentina
3Institute of Biological and Technological Research
4Centre for Ecology and Renewable Natural Resources, Faculty of Exact, Physical and Natural Sciences, National University of Cordoba, Cordoba 5000, Argentina
Download: HTML     PDF(1362KB)
Export: BibTeX | EndNote (RIS)      

Abstract  

Mining activity affects the vegetation and soils of the ecosystems. However, the effects of mining activity on saxicolous lichen communities are less concerned. Thus, the aim of this study was to characterize saxicolous lichen communities in three basins (Vis-Vis River basin, Poteros River basin, and Capillitas River basin) surrounding metalliferous mining projects of different types of operation and at different stages of exploitation. A large-scale mine (Bajo de la Alumbrera) with more than 25 a of open-pit mining located in the Vis-Vis River basin (CRV). A pre-exploitation mine (Agua Rica) located in the Poteros River basin (CRP), and a small-scale mine (Minas Capillitas) with more than 160 a of underground mining located in the Capillitas River basin (CAC). In each basin, species richness, cover, and frequency of lichen communities were measured on 40 rock outcrops. Also, explanatory variables were recorded, i.e., altitude, slope, aspect, vegetation cover, rock, and soil cover around the rocky area sampled. Richness and total cover of lichen communities were analysed using linear models, and species composition was explored using multivariate ordination analysis. Results showed that a total of 118 lichen species were identified. The species richness differed among basins and the lichen composition present in areas close to mining sites responded mainly to basins, altitude, and microsite variables. The lichen cover showed no difference among basins, but it changed under different rock and vegetation cover. It was not possible to quantify the effects of mining activity on species richness and composition. However, the low richness values found in the downstream of Minera Alumbrera could be associated with the negative impact of open-pit mining. Moreover, the effects of large-scale mining activity on lichen communities needs more investigation.

Key wordslichen community      altitude      microsite      metalliferous mining      vegetation     
Received: 08 March 2023      Published: 31 August 2023
Corresponding Authors: * Juan M HERNÁNDEZ (E-mail: juanhernandez@tecno.unca.edu.ar)
Service
E-mail this article
Add to my bookshelf
Add to citation manager
E-mail Alert
RSS
Articles by authors
Juan M HERNÁNDEZ
Renato A GARCÍA
Edith R FILIPPINI
Cecilia ESTRABOU
Martha S CAÑAS
Juan M RODRÍGUEZ
Cite this article:

Juan M HERNÁNDEZ, Renato A GARCÍA, Edith R FILIPPINI, Cecilia ESTRABOU, Martha S CAÑAS, Juan M RODRÍGUEZ. Saxicolous lichen communities in three basins associated with mining activity in northwestern Argentina. Journal of Arid Land, 2023, 15(8): 989-1005.

URL:

http://jal.xjegi.com/10.1007/s40333-023-0024-5     OR     http://jal.xjegi.com/Y2023/V15/I8/989

Fig. 1 Location of sampling sites in the study area. (a), overall of the study area including the three river basins; (b), Vis-Vis River basin (CRV); (c), Poteros River basin (CRP); (d), Capillitas River basin (CAC).
Fig. 2 Venn diagram showing the number of lichen species shared among the three basins close to metalliferous mines. CRV, Vis-Vis River basin; CRP, Poteros River basin; CAC, Capillitas River basin.
Fig. 3 Richness of saxicolous lichens in the three basins associated with mining activity. CRP, Potreros River basin; CAC, Capillitas River basin; CRV, Vis-Vís River basin. Black boxes show mean values. Black boxes show mean values. Bars are standard deviations.
Index Variable Deviance P value
Richness Basin 64.13 0.0001
Basin>Altitude 9.72 0.0211
F value
Total lichen cover Rock cover 5.39 0.0226
Vegetation cover 4.14 0.0448
Table 1 Best fit models for species richness and total lichen cover
Fig. 4 Cover of saxicolous lichens in the three basins associated with mining activity. CRP, Potreros River basin; CAC, Capillitas River basin; CRV, Vis-Vìs River basin. Black boxes show mean values. Bars are standard deviations.
Fig. 5 Canonical correlation analysis (CCA) using the relative frequency of lichen species. Grey arrows show the correlation of each axis with altitude and soil cover. CRP, Potreros River basin; CAC, Capillitas River basin; CRV, Vis-Vìs River basin; A.alto, A. altoandina; A.chry, Acarsopora chrysops (Tuck.) H.Magn; A.lore, Acarospora lorentzii (Müll. Arg.) Hue; A.xant, Acarospora xanthopahana (Nyl.) Jatta; B.spur, Buellia spuria (Schaer.) Anzi; B.sulf, Buellia sulphurea Malme; C.aff.al, Caloplca aff. altoandina (Malme) Zahlbr.; C.ama3, C.amer 3; C.atro, Caloplaca atroflava (Turner) Mong.; C.conc, Candelaria concolor (Dicks.) Arnold; C.nubi, Culbersonia nubile (Moberg) Essl.; C.ochr, Caloplaca ochraceofulva (Müll. Arg.) Jatta; C.side, Caloplaca aff. sideritis (Tuck.) Zahlbr.; C.sono, C. sonorae; C.vite, C. vitellina; F.hays, Flavoparmelia haysomii (C.W. Dodge) Hale; Fla.sp, Flavoplaca sp; L.argo, Lecanora argopholis (Ach.) Ach.; L.carp, Lecidella carpathica K?rb.; L.disp, Lecanora dispersa (Pers.) R?hl.; L.gran, L. granulosula; L.mura, Lecanora muralis (Schreb.) Rabenh.; Lep.sp, Lepraria sp.; N.pulc, Nephroma pulchella (Borrer) Nyl.; P.aipo, Physcia aipolia (Ehrh. ex Humb.) Fürnr.; P.badi, Protoparmelia badia (Hoffm.) Hafellner; P.breu, Pyrenula aff. breutelii (Müll. Arg.) Aptroot; P.cand, Placomaronea candelarioides R?s?nen; P.dist, Psiloparmelia distinta (Nyl.) Hale; P.micr, Punctelia microsticta (Müll. Arg.) Krog; P.peer, Punctelia perreticulata (R?s?nen) G. Wilh. & Ladd; P.ponc, Physcia poncinsii Hue; P.punc, Punctelia punctilla (Hale) Krog; P.reti, Parmotrema reticulatum (Taylor) M. Choisy; P.sema, Punctelia semansiana (W.L. Culb. & C.F. Culb.) Krog; P.stic, Punctelia stictica (Delise ex Duby) Krog; R.cela, Ramalina celastri (Spreng.) Krog & Swinsc.; R.conf, Rinodina confragosa (Ach.) K?rb.; R.disp, Rhizocarpon disporumn (N?geli ex Hepp) Müll. Arg.; R.inca, Ramalina incana Kashiw.; R.long, Rinodina longisperma Matzer & H. Mayrhofer; T.nodu, Teloschistes nodulifer (Nyl.) Hillmann; T.sedi, Toninia sedifolia (Scop.) Timdal; U.calv, Umbilicaria calvescens Nyl.; U.duri, Usnea durietzii Motyka; U.ploy, Umbilicaria polyphylla (L.) Baumg; X.cord, Xanthoparmelia cordillerana (Gyeln.) Hale; X.fari, Xanthoparmelia farinosa (Vain.) T.H. Nash, Elix & J. Johnst.; X.hass, Xanthomendoza hasseana (R?s?nen) S?chting, K?rnefelt & S.Y. Kondr.; X.loxo, Xanthoparmelia loxodes (Nyl.) O. Blanco, A. Crespo, Elix, D. Hawksw. & Lumbsch; X.micr, Xanthoparmelia microspora (Müll. Arg.) Hale; X.punc, Xanthoparmelia punctulata (Gyeln.) Hale; X.sant, Xanthoparmelia santessonii T.H. Nash & Elix.
Species Basin IV GF P
Xanthoparmelia punctulata (Gyeln.) Hale CAC 25.0 F 0.05
Protoparmelia badia (Hoffm.) Hafellner 12.5 C 0.01
Ramalina incana Kashiw. 9.7 Fr 0.05
Xanthoparmelia cordillerana (Gyeln.) Hale 24.6 F 0.00
Lecidella aff granulosula (Nyl.) Knoph & Leuckert 29.4 C 0.00
Punctelia perreticulata (Räsänen) G. Wilh. & Ladd 21.2 F 0.01
Umbilicaria haplocarpa Nyl. 59.7 FU 0.00
Psiloparmelia distincta (Nyl.) Hale 21.9 F 0.00
Xanthoparmelia microspora (Müll. Arg.) Hale 24.0 F 0.00
Xanthomendoza hasseana (Räsänen) Søchting, Kärnefelt & S.Y. Kondr. 17.1 F 0.00
Caloplaca aff sonorae Wetmore 67.5 C 0.00
Teloschistes nodulifer (Nyl.) Hillmann 27.9 Fr 0.00
Caloplaca aff. altoandina (Malme) Zahlbr. 52.5 C 0.00
Candelariella vitellina (Hoffm.) Müll. Arg. 33.3 C 0.00
Lecidella carpathica Körb. 28.1 C 0.00
Xanthoparmelia loxodes (Nyl.) O. Blanco, A. Crespo, Elix, D. Hawksw. & Lumbsch 17.5 F 0.00
Rinodina confragosa (Ach.) Körb. 15.4 C 0.01
Buellia sulphurea Malme 17.6 C 0.03
Caloplaca atroflava (Turner) Mong. CRP 30.9 C 0.00
Buellia spuria (Schaer.) Anzi 51.9 C 0.00
Lecanora argopholis (Ach.) Ach. 39.6 C 0.00
Punctelia borrerina (Nyl.) Krog 17.3 F 0.00
Ramalina celastri (Spreng.) Krog & Swinscow 20.0 Fr 0.00
Usnea durietzii Motyka 21.9 Fr 0.00
Umbilicaria calvescens Nyl. 20.0 FU 0.00
Normandina pulchrella (Borrer) Nyl. 10.0 E 0.03
Physcia aipolia (Ehrh. ex Humb.) Fürnr. 12.5 F 0.01
Rhizocarpon disporum (Nägeli ex Hepp) Müll. Arg. 12.2 C 0.03
Acarospora lorentzii (Müll. Arg.) Hue CRV 17.8 C 0.02
Caloplaca ochraceofulva (Müll. Arg.) Jatta 27.9 C 0.00
Lecanora muralis (Schreb.) Rabenh. 12.0 P 0.03
Punctelia punctilla (Hale) Krog 24.6 F 0.00
Rinodina longisperma Matzer & H. Mayrhofer 29.2 C 0.00
Caloplaca aff americana (Malme) Zahlbr. 29.3 C 0.00
Table 2 Indicator Species Analysis (ISA) according to basins and applied to presence-absence lichen data
Taxon Basin Family Growth form
CRP CAC CRV
Acarospora aff. altoandina H. Magn. + Acarosporaceae C
Acarospora aff. obnubila H. Magn. + Acarosporaceae C
Acarospora boliviana H. Magn. + Acarosporaceae C
Acarospora lorentzii (Müll. Arg.) Hue + + + Acarosporaceae C
Acarosporoide negro + Acarosporaceae C
Acarospora xanthophana (Nyl.) Jatta + + Acarosporaceae C
Acarospora chrysops (Tuck.) H. Magn. + + Acarosporaceae C
Buellia aff. umbrina Malme + Caliciaceae C
Buellia spuria (Schaer.) Anzi + + + Caliciaceae C
Buellia sulphurea Malme + + Caliciaceae C
Caloplaca aff. americana (Malme) Zahlbr. + + Teloschistaceae C
Caloplaca aff. sideritis (Tuck.) Zahlbr. + Teloschistaceae C
Caloplaca aff. sonorae Wetmore + Teloschistaceae C
Caloplaca aff. subsquamosa (Müll. Arg.) Zahlbr. + Teloschistaceae C
Caloplaca amarillo + Teloschistaceae C
Caloplaca atroflava (Turner) Mong. + + Teloschistaceae C
Caloplaca ochraceofulva (Müll. Arg.) Jatta + + + Teloschistaceae C
Caloplca aff. altoandina (Malme) Zahlbr. + Teloschistaceae C
Candelaria concolor (Dicks.) Arnold + + Lecanoraceae F
Candelaria fibrosa (Fr.) Müll. Arg. + Lecanoraceae F
Candelariella vitellina (Hoffm.) Müll. Arg. + + Candelariaceae C
Cladonia pyxidata (L.) Hoffm. + Cladoniaceae F
Crustoso amarillo 1 + - C
Crustoso amarillo 2 + - C
Crustoso amarillo 3 + - C
Crustoso blanco 1 + - C
Crustoso blanco 2 + - C
Crustoso blanco 3 + - C
Crustoso blanco con peritecios + - C
Crustoso gris verdoso + - C
Crustoso negro + - C
Crustoso sp. 1 + - C
Crustoso verde + + - C
Culbersonia nubila (Moberg) Essl. + + Physciaceae F
Diploschistes euganeus (A. Massal.) J. Steiner + Thelotremataceae C
Diploschistes bisporus (Bagl.) J. Steiner + Thelotremataceae C
Diploschistes scruposus (Schreb.) Norman + Thelotremataceae C
Diplotomma hedinii (H. Magn.) P. Clerc & Cl. Roux&nbsp + Caliciaceae C
Escuamuloso marrón + - E
Flavoparmelia haysomii (C.W. Dodge) Hale + + + Parmeliaceae F
Flavoparmelia papilosaun (Lynge ex Gyeln.) Hale + Parmeliaceae F
Flavoparmelia soredians (Nyl.) Hale + Parmeliaceae F
Flavoplaca austrocitrina (Vondrák, Říha, Arup & Søchting) Arup, Søchting & Frödén + Teloschistaceae C
Flavoplaca sp. + Teloschistaceae C
Heterodermia albicans (Pers.) Swinscow & Krog + Physciaceae F
Heterodermia diademata (Taylor) D.D. Awasthi + Physciaceae F
Heterodermia lutescens (Kurok.) Follmann + Physciaceae SFr
Heterodermia obscurata (Nyl.) Trevis. + Physciaceae F
Hyperphyscia syncolla (Tuck. ex Nyl.) Kalb + Physciaceae F
Lecanora argopholis (Ach.) Ach. + + Lecanoraceae C
Lecanora dispersa (Pers.) Röhl. + Lecanoraceae C
Lecidella aff. granulosula (Nyl.) Knoph & Leuckert + + + Lecanoraceae C
Lecidella carpathica Körb. + + Lecanoraceae C
Leprarioide sp. + Stereocaulaceae C
Leptogium austroamericanum (Malme) C.W. Dodge + Collemataceae F
Leptogium hypotrachynum Müll. Arg. + Collemataceae F
Leptogium phyllocarpum (Pers.) Mont. + Collemataceae F
Microfolioso marrón + - F
Normandinaephroma pulchella (Borrer) Nyl. + Nephromataceae E
Paraparmelia sp. + Parmeliaceae F
Parmotrema consors (Nyl.) Krog & Swinscow + Parmeliaceae F
Parmotrema muelleri (Vain.) O. Blanco, A. Crespo, Divakar, Elix & Lumbsch + Parmeliaceae F
Parmotrema reticulatum (Taylor) M. Choisy + + Parmeliaceae F
Phaeophyscia hirsuta (Mereschk.) Essl. + Physciaceae F
Physcia aipolia (Ehrh. ex Humb.) Fürnr. + Physciaceae F
Physcia poncinsii Hue + + Physciaceae F
Physcia tribacia (Ach.) Nyl. + Physciaceae F
Placidium ruiz-lealii (Räsänen) Breussruiz-lealli + Verrucariaceae E
Placomaronea candelarioides Räsänen + + + Lecanoraceae FU
Protoparmelia badia (Hoffm.) Hafellner + Parmeliaceae C
Psiloparmelia distincta (Nyl.) Hale + + Parmeliaceae F
Punctelia borrerina (Nyl.) Krog + + Parmeliaceae F
Punctelia perreticulata (Räsänen) G. Wilh. & Ladd + + + Parmeliaceae F
Punctelia punctilla (Hale) Krog + + + Parmeliaceae F
Punctelia semansiana (W.L. Culb. & C.F. Culb.) Krog + + Parmeliaceae F
Punctelia stictica (Delise ex Duby) Krog + + + Parmeliaceae F
Pyrenula aff. breutelii (Müll. Arg.) Aptroot + + Pyrenulaceae C
Ramalina celastri (Spreng.) Krog & Swinsc. + Ramalinaceae Fr
Ramalina incana Kashiw. + + Ramalinaceae Fr
Rhizocarpon disporumn (Nägeli ex Hepp) Müll. Arg. + + Rhizocarpaceae C
Rinodina confragosa (Ach.) Körb. + + Physciaceae C
Rinodina longisperma Matzer & H. Mayrhofer + + + Physciaceae C
Rinodina oxydata (A. Massal.) A. Massal. + + + Physciaceae C
Rinodina peloleuca (Nyl.) Müll. Arg. + Physciaceae C
Rinodina sp. + Physciaceae C
Staurothele areolata (Ach.) Lettau + + Verrucariaceae C
Teloschistes chrysophthalmus (L.) Th. Fr. + Teloschistaceae Fr
Teloschistes nodulifer (Nyl.) Hillmann + Teloschistaceae Fr
Toninia sedifolia (Scop.) Timdal + Ramalinaceae E
Toninia aff submexicana B. de Lesd. + Ramalinaceae E
Trimmatothelopsis smaragdula (Wahlenb. ex Ach.) Cl. Roux & Nav.-Ros. + Acarosporaceae C
Umbilicaria calvescens Nyl. + Umbilicariaceae FU
Umbilicaria haplocarpa Nyl. + + Umbilicariaceae FU
Umbilicaria polyphylla (L.) Baumg. + + Umbilicariaceae FU
Usnea amblyoclada (Müll. Arg.) Zahlbr. + Parmeliaceae Fr
Usnea cirrosa Motyka + Parmeliaceae Fr
Usnea dasaea Stirt. + Parmeliaceae Fr
Usnea durietzii Motyka + + Parmeliaceae Fr
Usnea sp. + Parmeliaceae Fr
Verrucarioide sp. + Verrucariaceae C
Xanthomendoza hasseana (Räsänen) Søchting, Kärnefelt & S.Y. Kondr. + + Parmeliaceae F
Xanthoparmelia cordillerana (Gyeln.) Hale + + Parmeliaceae F
Xanthoparmelia farinosa (Vain.) T.H. Nash, Elix & J. Johnst. + + + Parmeliaceae F
Xanthoparmelia ferraroiana T.H. Nash, Elix & J. Johnst. + + Parmeliaceae F
Xanthoparmelia fumarprotocetrarica (Elix & J. Johnst.) Elix + Parmeliaceae F
Xanthoparmelia loxodes (Nyl.) O. Blanco, A. Crespo, Elix, D. Hawksw. & Lumbsch + Parmeliaceae F
Xanthoparmelia mahuiana T.H. Nash & Elix + Parmeliaceae F
Xanthoparmelia microspora (Müll. Arg.) Hale + + Parmeliaceae F
Xanthoparmelia mougeotii (Schaer. ex D. Dietr.) Hale + Parmeliaceae F
Xanthoparmelia punctulata (Gyeln.) Hale + + + Parmeliaceae F
Xanthoparmelia santessonii T.H. Nash & Elix + + Parmeliaceae F
Xanthoparmelia subulcerosa T.H. Nash & Elix + Parmeliaceae F
Xanthoparmelia ulcerosa (Zahlbr.) Hale + Parmeliaceae F
Xanthoparmelia villamilianus T.H. Nash & J. Johnst. + Parmeliaceae F
Table S1 List of lichen taxa identified by basin, taxonomic family, and growth form
[1]   Abas A. 2021. A systematic review on biomonitoring using lichen as the biological indicator: A decade of practices, progress and challenges. Ecological Indicators, 121, doi: 10.1016/j.ecolind.2020.107197.
doi: 10.1016/j.ecolind.2020.107197
[2]   Adler M T. 1992. Keys to the genera and species of Parmeliaceae (Lichenes, Ascomycotlna) Buenos Aires Province (Argentina). Boletín de la Sociedad Argentina de Botánica, 28(1-4): 11-17. (in Spanish)
[3]   Álvarez L M. 2002. The socioeconomic impacts of the Bajo la Alumbrera project and an approach to the economic indicators of sustainability. In: Villas-Bôas R, Beinhoff C. Indicators of Sustainability for the Mineral Eextraction Industries. Carajas: CYTED/MAA/UNIDO, 331-338.
[4]   Baniya C B, Solhøy T, Gauslaa Y, et al. 2010. The elevation gradient of lichen species richness in Nepal. The Lichenologist, 42(1): 83-96.
doi: 10.1017/S0024282909008627
[5]   Bässler C, Cadotte M W, Beudert B, et al. 2016. Contrasting patterns of lichen functional diversity and species richness across an elevation gradient. Ecography, 39(7): 689-698.
doi: 10.1111/ecog.01789
[6]   Bielczyk U, Jędrzejczyk-Korycińska M, Kiszka J. 2009. Lichens of abandoned zinc-lead mines. Acta Mycologica, 44(2): 139-149.
doi: 10.5586/am.2009.012
[7]   Boamponsem L K, Adam J I, Dampare S B, et al. 2010. Assessment of atmospheric heavy metal deposition in the Tarkwa gold mining area of Ghana using epiphytic lichens. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms, 268(9): 1492-1501.
doi: 10.1016/j.nimb.2010.01.007
[8]   Calvelo S, Liberatore S. 2002. Catalog of lichens of Argentina. Kurtziana, 29(2): 7-170. (in Spanish)
[9]   Cleavitt N L, Clyne A B, Fahey T J. 2019. Epiphytic macrolichen patterns along an elevation gradient in the White Mountain National Forest, New Hampshirel. Journal of the Torrey Botanical Society, 146(1): 8-17.
doi: 10.3159/TORREY-D-18-00021.1
[10]   Comba A. 2017. Annex 1, rainfall records. In: Technical Report of the Problems in the Southern Area of Tucumán, Eastern Catamarca and Río Hondo. Water Resources Department, Tucumán Province, Argentina. (in Spanish)
[11]   Costas S M, Cantón N, Rodríguez J M. 2021. The relative effect of altitude and aspect on saxicolous lichen communities at mountain summits from central-west of Argentina. Rodriguésia, 72: e00282020. 2021, doi: 10.1590/2175-7860202172064.
doi: 10.1590/2175-7860202172064
[12]   Di Rienzo J A, Macchiavelli R, Casanoves F. 2017. Generalized linear mixed models applications in InfoStat. InfoStat, FCA. [2022-08-15]. http://www.infostat.com.ar. (in Spanish)
[13]   Di Rienzo J A, Casanoves F, Balzarini M G, et al. 2020. InfoStat version 2020. InfoStat Transfer Center, FCA, National University of Córdoba, Argentina. [2022-10-12]. http://www.infostat.com.ar. (in Spanish)
[14]   Dufrêne M, Legendre P. 1997. Species assemblages and indicator species: The need for a flexible asymmetrical approach. Ecological Monographs, 67(3): 345-366.
[15]   Estrabou C. 1999. The family Parmeliaceae (Lichenized Ascomycetes) Sensu stricto of the province of Córdoba: A systematic-biogeographical study.PhD Dissertation. Córdoba: National University of Córdoba. (in Spanish)
[16]   Estrabou C, Rodríguez J M, Prieri B, et al. 2006. Contribution to the knowledge of the macrolichens of the extreme south of the Gran Chaco (Argentina). Kurtziana, 32(1-2): 25-43. (in Spanish)
[17]   Estrabou C, Mohaded Aybar C B, Rodríguez J M, et al. 2010. Lichen diversity in three areas from Catamarca Province: Basis for the environmental changes control. Ciencia, 5(12): 85-95. (in Spanish)
[18]   Filippini E R, Rodríguez J M, Estrabou C. 2014. Lichen community from an endangered forest under different management practices in central Argentina. Lazaroa, 35: 55-63.
[19]   Filippini E R, Rodríguez J M, Quiroga G, et al. 2020. Differential response of epiphytic lichen taxa to agricultural land use in a fragmented forest in central Argentina. Cerne, 26(2): 272-278.
doi: 10.1590/01047760202026022733
[20]   Gonzalez-Bonorino F. 1972. Geological description of the 13C sheet, Fiambalá, Catamarca Province. In: Technical Report Note 127. National Service of Mining and Geology, Buenos Aires, Argentina. (in Spanish)
[21]   Gunawardana D I, Edirisinghe S M, Abayasekara C L, et al. 2021. Air pollution affects lichen species richness, species density, relative growth form abundance and their secondary metabolite production: A case study in Kandy district, Sri Lanka. Ruhuna Journal of Science, 12(2): 115-127.
doi: 10.4038/rjs.v12i2.106
[22]   Hawksworth D L, Grube M. 2020. Lichens redefined as complex ecosystems. New Phytologist, 227(5): 1281-1283.
doi: 10.1111/nph.16630 pmid: 32484275
[23]   Hestmark G. 2010. Typification of the Andean taxa of Umbilicaria described by William Nylander. Mycotaxon, 111(1): 51-63.
doi: 10.5248/111.51
[24]   Karlin U O, Karlin M S, Zapata R M, et al. 2017. The phytogeographic province of Monte: Territorial limits and its representation. Multequina, 26: 63-75. (in Spanish)
[25]   Kidron G J, Temina M. 2010. Lichen colonization on cobbles in the Negev Desert following 15 years in the field. Geomicrobiology Journal, 27(5): 455-463.
doi: 10.1080/01490450903490805
[26]   Knudsen K, Elix J, Reeb V. 2008. A preliminary study of the genera Acarospora and Pleopsidium in South America. Opuscula Philolichenum, 5: 1-22.
[27]   Knudsen K, Flakus A. 2016. The identity of Acarospora xanthophana (Fungi: Ascomycota) and a description of A. congregata sp. nov. to accommodate a widely distributed saxicolous species occurring in the higher elevations of South America. Taxon, 65(1): 146-151.
doi: 10.12705/651.10
[28]   Körner C. 1995. Alpine plant diversity: A global survey and functional interpretations. In: Chapin F S, Körner C. Arctic and Alpine Biodiversity: Patterns, Causes and Ecosystem Consequences. Berlin: Springer, 45-62.
[29]   Körner C, Spehn E M. 2002. Mountain Biodiversity:A Global Assessment. Boca Raton: Parthenon Publication Group, 225-237.
[30]   Körner C. 2007. The use of 'altitude ' in ecological research. Trends in Ecology & Evolution, 22(11): 569-574.
doi: 10.1016/j.tree.2007.09.006
[31]   Kuffour R A, Tiimub B B M, Manu I, et al. 2020. The effect of illegal mining activities on vegetation: A case study of Bontefufuo Area in the Amansie West District of Ghana. East African Scholars Journal of Agriculture and Life Sciences, 3(11): 353-359.
doi: 10.36349/easjals.2020.v03i11.002
[32]   Llambías E J. 1972. Structure of the Farallón Negro volcanic group, Catamarca, Argentina. Journal of the Argentine Geological Association, 27: 161-169. (in Spanish)
[33]   Lücking R, Matzer M. 2001. High foliicolous lichen alpha-diversity on individual leaves in Costa Rica and Amazonian Ecuador. Biodiversity & Conservation, 10(12): 2139-2152.
[34]   Lücking R, Hodkinson B P, Leavitt S D. 2017. The 2016 classification of lichenized fungi in the Ascomycota and Basidiomycota-Approaching one thousand genera. The Bryologist, 119(4): 361-416.
doi: 10.1639/0007-2745-119.4.361
[35]   Márquez-Zavalía M F. 2002. Minas Capillitas, an epithermal deposit in northwestern Argentina. In: Trombotto D T, Villalba D I. 30 Years of Basic and Applied Research in Environmental Sciences. Buenos Aires: Institute of Nivology, Glaciology and Environmental Sciences, 249-253. (in Spanish)
[36]   Márquez-Zavalía M F, Galliski M Á, Drábek M, et al. 2014. Ishiharaite, (Cu, Ga, Fe, In, Zn) S, a new mineral from the Capillitas mine, northwestern Argentina. The Canadian Mineralogist, 52(6): 969-980.
doi: 10.3749/canmin.1400064
[37]   McCune B, Mefford M J. 1998. PC-ORD: Multivariate analysis of ecological data. Ecological Society of America, 79(2): 144-145.
[38]   McCune B, Grace J B, Urban D L. 2002. Analysis of ecological communities. Journal of Experimental Marine Biology and Ecology, 289(2), 00091, doi: 10.1016/S0022-0981(03)00091-1.
doi: 10.1016/S0022-0981(03)00091-1
[39]   Minera Alumbrera YMAD-UTE. 2017. Environmental monitoring. In: III Quarterly Report 2017. Meteorological Climate Monitoring, Buenos Aires, Argentina. (in Spanish)
[40]   Moretton J, Guaschino H, Amicone C, et al. 1996. Air pollution in Argentina:General aspects, legislation, situation in the Buenos Aires. In: Technical Report of Buenos Aires. Buenos Aires, Argentina. (in Spanish)
[41]   Morlans, M C. 1995. Natural regions of Catamarca: Geological provinces and phytogeographical provinces. Scientific Journal of UNCa, 2(2): 1-42. (in Spanish)
[42]   Nash T H, Gries C. 2002. Lichens as bioindicators of sulfur dioxide. Symbiosis, 33(1): 1-21.
[43]   Neitlich P N, Berryman S, Geiser L H, et al. 2022. Impacts on tundra vegetation from heavy metal-enriched fugitive dust on National Park Service lands along the Red Dog Mine haul road, Alaska. PloS ONE, 17(6): 269801, doi: 10.1371/journal.pone.0269801.
doi: 10.1371/journal.pone.0269801
[44]   Orange A, James P W, White F J. 2001. Microchemical Methods for the Identification of Lichens. London: British Lichen Society, 20-36.
[45]   Osyczka P, Rola K. 2019. Integrity of lichen cell membranes as an indicator of heavy-metal pollution levels in soil. Ecotoxicology and Environmental Safety, 174: 26-34.
doi: S0147-6513(19)30209-X pmid: 30818257
[46]   Osyczka P, Lenart-Boroń A, Boroń P, et al. 2021. Lichen-forming fungi in post-industrial habitats involve alternative photobionts. Mycologia, 113(1): 43-55.
doi: 10.1080/00275514.2020.1813486 pmid: 33146594
[47]   Panagos P, van Liedekerke M, Yigini Y, et al. 2013. Contaminated sites in Europe: Review of the current situation based on data collected through a European network. Journal of Environmental and Public Health, 7309: 158764, doi: 10.1155/2013/158764.
doi: 10.1155/2013/158764
[48]   Paoli H P. 2003. Water resources use and irrigation technology in the Argentinean Altiplano. In:Technical Report of EEA INTA Salta/CIED. Water Resources Centre of the Puna. Salta, Argentina. (in Spanish)
[49]   Paoli L, Fačkovcová Z, Lackovičová A, et al. 2021. Air pollution in Slovakia (Central Europe): A story told by lichens (1960-2020). Biologia, 76: 3235-3255.
doi: 10.1007/s11756-021-00909-4
[50]   Pescott O L, Simkin J M, August T A, et al. 2015. Air pollution and its effects on lichens, bryophytes, and lichen-feeding Lepidoptera: Review and evidence from biological records. Biological Journal of the Linnean Society, 115(3): 611-635.
doi: 10.1111/bij.12541
[51]   Rajakaruna N, Harris T B, Clayden S R, et al. 2011. Lichens of the Callahan mine, a copper-and zinc-enriched superfund site in Brooksville, Maine, USA. Rhodora, 113(953): 1-31.
doi: 10.3119/10-03.1
[52]   Ramos V. 1999. Tertiary synorogenic deposits of the Andean region. In: Technical Report of Caminos R. Anales Geología, Argentina. (in Spanish)
[53]   Rodríguez J M, Estrabou C, Truong C, et al. 2011. The saxicolous species of the genus Usnea subgenus Usnea (Parmeliaceae) in Argentina and Uruguay. American Bryological and Lichenological Society, Inc. Bryologist, 114(3): 504-525.
[54]   Rodríguez J M, Renison D, Filippini E, et al. 2017. Small shifts in microsite occupation could mitigate climate change consequences for mountain top endemics: A test analyzing saxicolous lichen distribution patterns. Biodiversity and Conservation, 26(5): 1199-1215.
doi: 10.1007/s10531-017-1293-0
[55]   Rutherford R D, Rebertus A. 2022. A habitat analysis and influence of scale in lichen communities on granitic rock. The Bryologist, 125(1): 43-60.
[56]   Scheidegger C, Groner U, Keller C, et al. 2002. Biodiversity assessment tool-lichens. In: Nimis P L, Scheidegger C, Wolseley P A. Monitoring with Lichens-Monitoring Lichens. Dordrecht: Springer, 35.
[57]   Scutari N C. 1992. Studies on foliose Pyxinaceae (Lecanorales, Ascomycotina) of Argentina, IV: Keys to the genera and species of the province of Buenos Aires. Boletín Sociedad Argentina de Botánica, 28 (1-4): 169-173. (in Spanish)
[58]   Sun X, Yuan L, Liu M, et al. 2022. Quantitative estimation for the impact of mining activities on vegetation phenology and identifying its controlling factors from Sentinel-2 time series. International Journal of Applied Earth Observation and Geoinformation, 111: 102814, doi: 10.1016/j.jag.2022.102814.
doi: 10.1016/j.jag.2022.102814
[59]   Touceda-González M, Álvarez-López V, Prieto-Fernández Á, et al. 2017. Aided phytostabilisation reduces metal toxicity, improves soil fertility and enhances microbial activity in Cu-rich mine tailings. Journal of Environmental Management, 186: 301-313.
doi: S0301-4797(16)30662-4 pmid: 27817970
[60]   Unanaonwi O E, Amonum J I. 2017. Effect of mining activities on vegetation composition and nutrient status of forest soil in Benue Cement Company, Benue State, Nigeria. International Journal of Environment, Agriculture and Biotechnology, 2(1): 297-305.
doi: 10.22161/ijeab
[61]   Vetaas O R, Paudel K P, Christensen M. 2019. Principal factors controlling biodiversity along an elevation gradient: Water, energy and their interaction. Journal of Biogeography, 46(8): 1652-1663.
doi: 10.1111/jbi.13564
[62]   Vittoz P, Bayfield N, Brooker R, et al. 2010. Reproducibility of species lists, visual cover estimates and frequency methods for recording high-mountain vegetation. Journal of Vegetation Science, 21(6): 1035-1047.
doi: 10.1111/j.1654-1103.2010.01216.x
[63]   Westberg M, Frödén P, Wedin M. 2009. A monograph of the genus Placomaronea (Ascomycota, Candelariales). Lichenologist, 41(5): 513-527.
doi: 10.1017/S0024282909990156
[64]   Yu H, Zahidi I. 2023. Spatial and temporal variation of vegetation cover in the main mining area of Qibaoshan Town, China: Potential impacts from mining damage, solid waste discharge and land reclamation. Science of the Total Environment, 859: 160392, doi: 10.1016/j.scitotenv.2022.160392.
doi: 10.1016/j.scitotenv.2022.160392
[1] SUN Chao, BAI Xuelian, WANG Xinping, ZHAO Wenzhi, WEI Lemin. Response of vegetation variation to climate change and human activities in the Shiyang River Basin of China during 2001-2022[J]. Journal of Arid Land, 2024, 16(8): 1044-1061.
[2] YAN Yujie, CHENG Yiben, XIN Zhiming, ZHOU Junyu, ZHOU Mengyao, WANG Xiaoyu. Impacts of climate change and human activities on vegetation dynamics on the Mongolian Plateau, East Asia from 2000 to 2023[J]. Journal of Arid Land, 2024, 16(8): 1062-1079.
[3] LU Qing, KANG Haili, ZHANG Fuqing, XIA Yuanping, YAN Bing. Impact of climate and human activity on NDVI of various vegetation types in the Three-River Source Region, China[J]. Journal of Arid Land, 2024, 16(8): 1080-1097.
[4] SUN Hui, ZHAO Yunge, GAO Liqian, XU Mingxiang. Reasonable grazing may balance the conflict between grassland utilization and soil conservation in the semi-arid hilly areas, China[J]. Journal of Arid Land, 2024, 16(8): 1130-1146.
[5] LI Chuanhua, ZHANG Liang, WANG Hongjie, PENG Lixiao, YIN Peng, MIAO Peidong. Influence of vapor pressure deficit on vegetation growth in China[J]. Journal of Arid Land, 2024, 16(6): 779-797.
[6] QU Wenjie, ZHAO Wenzhi, YANG Xinguo, WANG Lei, ZHANG Xue, QU Jianjun. Effects of wind speed, underlying surface, and seed morphological traits on the secondary seed dispersal in the Tengger Desert, China[J]. Journal of Arid Land, 2024, 16(4): 531-549.
[7] SHEN Jianxiang, WANG Xin, WANG Lei, WANG Jiahui, QU Wenjie, ZHANG Xue, CHANG Xuanxuan, YANG Xinguo, CHEN Lin, QIN Weichun, ZHANG Bo, NIU Jinshuai. Spatiotemporal characteristics of seed rain and soil seed bank of artificial Caragana korshinskii Kom. forest in the Tengger Desert, China[J]. Journal of Arid Land, 2024, 16(4): 550-566.
[8] DUN Yaoquan, QU Jianjun, KANG Wenyan, LI Minlan, LIU Bin, WANG Tao, SHAO Mei. Formation and ecological response of sand patches in the protection system of Shapotou section of the Baotou-Lanzhou railway, China[J]. Journal of Arid Land, 2024, 16(2): 298-313.
[9] MAO Zhengjun, WANG Munan, CHU Jiwei, SUN Jiewen, LIANG Wei, YU Haiyong. Feature extraction and analysis of reclaimed vegetation in ecological restoration area of abandoned mines based on hyperspectral remote sensing images[J]. Journal of Arid Land, 2024, 16(10): 1409-1425.
[10] NAN Weige, DONG Zhibao, ZHOU Zhengchao, LI Qiang, CHEN Guoxiang. Ecological effect of the plantation of Sabina vulgaris in the Mu Us Sandy Land, China[J]. Journal of Arid Land, 2024, 16(1): 14-28.
[11] WU Wangyang, ZHANG Dengshan, TIAN Lihui, SHEN Tingting, GAO Bin, YANG Dehui. Morphological change and migration of revegetated dunes in the Ketu Sandy Land of the Qinghai Lake, China[J]. Journal of Arid Land, 2023, 15(7): 827-841.
[12] ZHANG Hui, Giri R KATTEL, WANG Guojie, CHUAI Xiaowei, ZHANG Yuyang, MIAO Lijuan. Enhanced soil moisture improves vegetation growth in an arid grassland of Inner Mongolia Autonomous Region, China[J]. Journal of Arid Land, 2023, 15(7): 871-885.
[13] GAO Xiang, WEN Ruiyang, Kevin LO, LI Jie, YAN An. Heterogeneity and non-linearity of ecosystem responses to climate change in the Qilian Mountains National Park, China[J]. Journal of Arid Land, 2023, 15(5): 508-522.
[14] LI Hongfang, WANG Jian, LIU Hu, MIAO Henglu, LIU Jianfeng. Responses of vegetation yield to precipitation and reference evapotranspiration in a desert steppe in Inner Mongolia, China[J]. Journal of Arid Land, 2023, 15(4): 477-490.
[15] ZHANG Wensheng, AN Chengbang, LI Yuecong, ZHANG Yong, LU Chao, LIU Luyu, ZHANG Yanzhen, ZHENG Liyuan, LI Bing, FU Yang, DING Guoqiang. Modern pollen assemblages and their relationships with vegetation and climate on the northern slopes of the Tianshan Mountains, Xinjiang, China[J]. Journal of Arid Land, 2023, 15(3): 327-343.