Ecosystem carbon sequestration through restoration of degraded lands in Northeast India

Brahma, Biplab; Pathak, Karabi; Lal, Rattan; Kurmi, Bandana; Das, Milon; Nath, Panna Chandra; Nath, Arun Jyoti; Das, Ashesh Kumar

doi:10.1002/ldr.2816

Cited by 71 publications

(26 citation statements)

References 68 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…In contrast, heterogeneous agricultural areas decreased markedly in the studied catchments and their upper parts, whereas no significant changes were found for arable land, permanent crops, or pastures. In addition, the ongoing reforestation process may contribute to the increase of the natural value of this mountain region, because the dense forest cover effectively protects the soil against erosion and excessive sediment transport during floods (Biro, Pradhan, Buchroithner, & Makeschin, ; Lizaga, Quijano, Palazón, Gaspar, & Navas, ; Wyżga et al, ) and facilitates carbon sequestration attenuating climate warming (Bonan, ; Brahma et al, ).…”

Section: Discussionmentioning

confidence: 99%

Land cover transitions and changing climate conditions in the Polish Carpathians: Assessment and management implications

Kędra

Szczepanek

2019

Land Degrad Dev

View full text Add to dashboard Cite

Widespread, human‐induced land cover (LC) transitions in areas surrounding national parks and nature reserves, accompanied by changing climate conditions, can trigger serious consequences for these natural environments and their ecosystems. The aim of the study was to assess the direction and magnitude of transitions in LC in the Polish Carpathians since 1990 for determining the current status of land degradation neutrality and future degradation risk as well as to analyze concomitant changes in climate conditions to enable sustainable land management. The study area encompasses six national parks with the United Nations Educational, Scientific, and Cultural Organization biosphere reserves, several dozen nature reserves, and landscape parks and is a key source of drinking water in Poland. We studied detailed changes in LC (13 classes). The Wilcoxon signed rank test indicated significant increases in built‐up areas (urban fabric and industrial/transport infrastructure), waters, dense forest cover, and herbaceous vegetation but a decrease in heterogeneous agricultural areas. On the basis of two new methods, we assessed the LC transitions for 20 mountain catchments and for the entire Polish Carpathians. Although we found a slight positive transition in LC for the entire Polish Carpathians, clearly negative transitions occurred in the five analyzed catchments, including those covering two national parks. These LC transitions are accompanied by changing climate conditions with significant increases in air temperature and precipitation. The ongoing intensive urbanization in the studied mountain region, which is accompanied by significant regional warming, implies the need to apply sustainable management practices that will avoid or reduce degradation in the catchments involved.

show abstract

Section: Discussionmentioning

confidence: 99%

Land cover transitions and changing climate conditions in the Polish Carpathians: Assessment and management implications

Kędra

Szczepanek

2019

Land Degrad Dev

View full text Add to dashboard Cite

show abstract

“…Data presented reveal the magnitude of annual CO 2 emission from the fired‐brick industry is alarming. At the present rate of C sequestration potential of Indian forests (≈4 Mg C ha −1 yr −1 ), ≈3 Mha afforestation is required per annum to offset the emission from the fired‐brick industries, which is an unfeasible option in a land‐scarce country. Nevertheless, rehabilitation of degraded lands to accelerate carbon sequestration is a viable option to offset emission from fired brick industry and other anthropogenic activities.…”

Section: Summary Statistics For Soil Organic Carbon (%) Distribution mentioning

confidence: 99%

“…Agroforestry practices such as the fertilizer tree (fast‐growing nitrogen‐fixing) systems have been known to improve SOC build‐up in depleted soils . The soil carbon sequestration potential (0.5–0.8 Mg C ha −1 yr −1 ) of traditional agroforestry systems in India is higher than that of agricultural systems such as rice‐paddy and comparable to that of single‐species tree‐crop systems of rubber, areca, and coconut . Promotion of agroforestry ( Piper betle agroforestry) and plantations (e.g., rubber, bamboo, etc.)…”

Section: Summary Statistics For Soil Organic Carbon (%) Distribution mentioning

confidence: 99%

“…Promotion of agroforestry ( Piper betle agroforestry) and plantations (e.g., rubber, bamboo, etc.) in those lands may significantly improve SOC stock in depleted soils in India . Rehabilitating abandoned brick kilns through bamboo plantation development in villages of Kotwa and Rahimabad of Allahabad, India over a time period of seven years (1996–2003) enhanced SOC sequestration from almost 0 (in 1996) to 0.7 (in 2003) Mg ha −1 yr −1 in the surface soil .…”

Section: Summary Statistics For Soil Organic Carbon (%) Distribution mentioning

confidence: 99%

See 1 more Smart Citation

Fired Bricks: CO₂ Emission and Food Insecurity

2018

Self Cite

View full text Add to dashboard Cite

Fired bricks are used for construction purposes over the millennia, going back to the Indus Valley Civilization. The traditional brick‐making process involves removal of agriculturally productive topsoil rich in clay and soil organic matter contents. In addition to the removal of the fertile topsoil and accelerated degradation by other processes, the traditional clay brick making process also emits CO 2 and other gases into the atmosphere. Therefore, the present study aims to assess the impact of brick making in India on: (i) the magnitude of annual CO 2 emission and (ii) the loss of agricultural production. Currently, 0.7 Mha (million hectare) of agricultural land is under brick kilns that produce ≈250 billion bricks annually. It is estimated that soil organic carbon lost through the firing process of 250 billion bricks is 5.58–6.12 Tg (teragram) (20.48–22.46 Tg CO 2 ), and in conjunction with clay burning and coal combustion the process releases 40.65–42.64 Tg CO 2 into the atmosphere per annum. Brick kiln also impacts quality of the exposed subsoil, and may also reduce 60–90% agronomic yield. Therefore, brick making from topsoil exacerbates food and nutritional insecurity by degrading soil quality, and increases risks of climate change through increase in gaseous emissions.

show abstract

“…SOM contains soil organic carbon (C) and nutrients (including nitrogen [N] and phosphorus [P]) and is recognized as a key indicator of soil health and productivity in agricultural systems (Dungait et al, ). The turnover of SOM and release of nutrients is mediated by the soil microbial community (e.g., bacteria and fungi including mycorrhiza) that also play a role in soil stabilization through the formation of soil aggregates, through the process of ‘soil self‐organization’ (Young & Crawford, ), increasing the potential for successful vegetation colonization and succession by improving soil quality, that is, nutrient and water retention and supply and diffusion of gases through soil pores (Brahma et al, ).…”

Section: Introductionmentioning

confidence: 99%

Soil enzyme activity and stoichiometry along a gradient of vegetation restoration at the Karst Critical Zone Observatory in Southwest China

et al. 2019

View full text Add to dashboard Cite

The “Grain for Green Programme” was implemented in the 1990s as a solution to the extreme degradation of karst landscapes that cover one‐third of China, largely caused by decades of poorly managed intensive agriculture. The recovery of soil functions is key to the success of ecosystem regeneration of abandoned croplands where the carbon (C) and nutrient cycles have been severely perturbed by cultivation. However, an ecological ‘tipping point’ beyond which soil functions are unrecoverable in manageable timescales may have been passed in the fragile, subtropical karst ecosystem. The aim of this study was to use the activity of key enzymes for C, nitrogen (N), and phosphorus (P) acquisition in the soil as a proxy for the biological response to vegetation restoration after agricultural abandonment in a severely degraded karst catchment at the Karst Critical Zone Observatory in Guizhou Province. In 2016, a space‐for‐time approach was used to establish a chronosequence of vegetation recovery: sloping cropland < recently abandoned sloping cropland < shrubland < secondary (regenerated) forest < primary (natural) forest. Soils were sampled from the surface to the bedrock (up to 80‐cm depth) in each recovery phase. The activity of all enzymes in the top 0 to 30‐cm depth increased after abandonment and was positively correlated with soil nutrient and water contents. Nitrogen deficiencies were indicated by the reduced ratios of C‐ relative to N‐hydrolase activity and the increased ratios of N‐ relative to P‐hydrolase activity in the abandoned croplands and shrublands. Phosphorus deficiencies were indicated by the reduced ratios of N‐ relative to P‐hydrolase activity and C‐ relative to P‐hydrolase activity in the soils of the shrubland and secondary forest compared with the primary forest. Our results revealed that near‐to‐natural biological soil function was recoverable as vegetation naturally restored and suggested that the rate of recovery may be accelerated by managed nutrient amendments during the early stages after abandonment. This new information may help to inform the managed regeneration of degraded agricultural land in nutrient‐poor, subtropical environments.

show abstract

Ecosystem carbon sequestration through restoration of degraded lands in Northeast India

Cited by 71 publications

References 68 publications

Land cover transitions and changing climate conditions in the Polish Carpathians: Assessment and management implications

Land cover transitions and changing climate conditions in the Polish Carpathians: Assessment and management implications

Fired Bricks: CO₂ Emission and Food Insecurity

Soil enzyme activity and stoichiometry along a gradient of vegetation restoration at the Karst Critical Zone Observatory in Southwest China

Contact Info

Product

Resources

About

Ecosystem carbon sequestration through restoration of degraded lands in Northeast India

Cited by 71 publications

References 68 publications

Land cover transitions and changing climate conditions in the Polish Carpathians: Assessment and management implications

Land cover transitions and changing climate conditions in the Polish Carpathians: Assessment and management implications

Fired Bricks: CO2 Emission and Food Insecurity

Soil enzyme activity and stoichiometry along a gradient of vegetation restoration at the Karst Critical Zone Observatory in Southwest China

Contact Info

Product

Resources

About

Fired Bricks: CO₂ Emission and Food Insecurity