Sugarcane is a versatile crop with significant potential for
carbon sequestration in both soil and plants. This study assessed the carbon
sequestration in planted sugarcane and rhizospheric soil under various nutrient
management practices. According to the IPCC, rising global temperatures due to
GHG emissions are a primary cause of global warming. To stabilize global
temperatures, it is essential to mitigate anthropogenic CO2 emissions and
enhance the sequestration of surplus atmospheric CO2 in plants and soil.
Sugarcane cultivation plays a crucial role in this process, as it is a C4 plant
with high efficiency in utilizing CO2 during photosynthesis. One approach to
enhance CO2 capture is through improved nutrient management practices, which
can increase chlorophyll synthesis and nitrogen efficiency in sugarcane.
Different treatment compositions can enhance photosynthesis, leading to greater
CO2 capture. Consequently, sugarcane crops and their rhizospheric soils act as
important carbon sinks, contributing to atmospheric decarbonization and global
cooling.
Soil Properties and Carbon Storage: The study results indicated
that soil physical and chemical properties varied significantly among
treatments due to the application of different organic amendments. Soil organic
carbon (SOC) was analyzed and ranged from 0.47% to 0.67%. The different organic
amendment treatments notably improved soil bulk density, porosity, and carbon
storage.
Plant Carbon Storage: Carbon stocks in various sugarcane plant
parts, including roots, shoots, and leaves, were significantly different across
treatments. The highest carbon stock was found in leaves (877.08 kg ha-¹) under
T6, followed by roots (668.74 kg ha-¹) in T2, and shoots (422.77 kg ha-¹) in
T5. This indicates that leaves stored 30.41% and 107.58% more carbon than roots
and shoots, respectively, while roots stored 58.18% more carbon than shoots.
The total carbon storage in sugarcane biomass, including aboveground and
belowground parts, varied significantly across treatments. The mean carbon
storage in aboveground parts (leaves and stalks) was significantly higher
(1239.65 kg ha-¹) than in underground parts (roots) at 621.73 kg ha-¹. These
findings demonstrate that sugarcane farming practices can effectively enhance
carbon sequestration, contributing to climate change mitigation. The sugarcane
crop and rhizospheric soils act as important carbon sinks in the
decarbonisation of the atmosphere, ultimately reducing carbon levels and
causing global cooling.
Author
(s) Details
Ajeet
Kumar
Department of Soil Science, Sugarcane Research Institute, Dr.
Rajendra Prasad Central Agricultural University, Pusa (Samastipur)-848125,
Bihar, India.
Sunita
Kumari Meena
Department of Soil Science, Sugarcane Research Institute, Dr.
Rajendra Prasad Central Agricultural University, Pusa (Samastipur)-848125,
Bihar, India.
Sanjay
Kumar Singh
Department of Soil Science, Tirhut College of Agriculture, Dholi,
Muzaffarpur, India.
S. K.
Sinha
Regional Research Station, Madhopur, West Champaran, Bihar-845454,
India.
Amrita
Kumari
Bihar Agricultural University, Sabour, Bhagalpur-813210, India.
A. K.
Singh
Department of Soil Science, Sugarcane Research Institute, Dr.
Rajendra Prasad Central Agricultural University, Pusa (Samastipur)-848125,
Bihar, India.
Please see the book here:- https://doi.org/10.9734/bpi/raeges/v9/1425
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