Thursday, 10 July 2014

Rice fields as carbon sinks Author: Latha Jishnu Jul 15, 2014 | Down to Earth

Originally published here. The Link:

http://www.downtoearth.org.in/content/lowland-rice-carbon-sink

A study by Indian scientists finds lowland flooded rice ecosystems can store vast amounts of carbon but the jury is still out on whether these can be called carbon sinks.

Since October 2009, a strange contraption-all metal pipes, wires and sensors-sat smack in the middle of the Central Rice Research Institute (crri) near Cuttack in Odisha, inviting the dedicated attention of a handful of scientists there. Fenced in by an iron mesh, the device was planted in the midst of lush green rice fields on the 1-hectare campus-and it played a key role in helping researchers at the country’s premier rice institute to arrive at a different understanding of what this important food crop is doing, or not doing, to our planet by way of greenhouse gas (GHG) emissions.

The apparatus that was employed by crri scientists is called the eddy covariance (EC) system and is widely favoured by scientists across the world to measure the exchange of carbon dioxide, water vapour, methane, various other gases, and energy between the surface of earth and the atmosphere in different ecosystems. Advanced versions are increasingly being used by rice scientists to arrive at a fairer measure of emissions in rice ecosystems which have for long been targeted as major villains in pushing up agricultural GHGs.

For Pratap Bhattacharyya, senior crop scientist at crri, the EC technique has been instrumental in formulating his thesis that rice is actually a carbon sink. In a paper published in May this year in the internationally peer-reviewed journal Agriculture, Ecosystems and Environment, the scientist says considering that 80 per cent of rice in Asia is grown in flooded conditions, it was essential to determine whether such a system is behaving as net carbon sink, that is, absorbing carbon or adding to its depletion.

After a year-long field study undertaken in 2012-13 to investigate the carbon dioxide (CO2) and methane (CH4) exchange in relation to ecosystem carbon balance, the paper states clearly that lowland flooded rice ecosystem has the capacity to store carbon in the soil and can behave as net carbon sink. CO2 and CH4 are the two major GHGs that contribute to global warming by trapping heat on the surface of the earth.

This finding goes against the conventional view that tropical rice fields are major contributors to agriculture GHGs. The latest working group report of the Intergovernmental Panel on Climate Change (IPCC) squarely blames rice for climate change, saying that rice paddies account for as much as 11 per cent of man-made methane emissions. This is estimated at 493-723 million tonnes of CO2 equivalent a year and major rice-growing countries such as India and China have been under pressure at climate change negotiations to include agriculture emissions in their total GHGs with rice cited as the chief culprit.

However, the crri research team, which includes principal scientist A K Nayak, arrived at its contrarian view by toting up the net gain/loss of carbon and then calculating the carbon lost from the system through dissolution in water, erosion, harvesting and bacterial production of methane to arrive at the “net carbon balance”. They say that a hectare of lowland ecosystem has the potential to store as much as 910 kg of carbon during the wet season while in the dry season, it can hold up to 590 kg.

In an interview to Down To Earth, Bhattacharyya explains why he arrived at this hypothesis. His team observed that geographically lowland rice-growing areas are confined to the coastal states having high annual rainfall. The lowland rice cultivation is usually a bunded system in which the field bund height ranges from 50 cm to 100 cm. Typically the rice fields act as perfect water harvesting structures and help in reducing the run-off loss and enhance the groundwater recharge, thereby helping to prevent the salt water intrusion into aquifers in coastal areas. In the absence of these rice fields and bunded structures, the water would have been lost to sea and contributed to decline in groundwater, he contends.

“In the absence of rice fields there would have been much higher expenditure for rainwater harvesting and artificial recharge of aquifer along with the use of electricity and petroleum needed for extracting water from a still deeper layer of aquifer which would have further contributed to climate change.” But not all scientists subscribe to the view that “Tropical lowland rice ecosystem is a net carbon sink” as the Bhattacharyya paper is titled. Reiner Wassmann, coordinator of climate change research at the International Rice Research Institute (IRRI) in Los Baños, Philippines, for instance, has a problem with such a broad claim.

In a response to queries from Down To Earth, Wassmann points out: “The paper assesses the carbon mass balance and not the balance of GHGs. CH4 has a global warming potential (gwp) that is 25 times higher than that of CO2. In some other studies, the gwp of CH4 is given as 21 times, but this does not change the overall picture. Even though the authors of this study could have easily computed the GHG balance, they have preferred to limit their assessment to the carbon mass balance.”

Interestingly, Wassmann, in a paper written with fellow IRRI scientist Maricar Alberto, has also reported net CO2 uptake along with CH4 emissions using the same EC measurement technique. In the paper “Measuring methane flux from irrigated rice fields by eddy covariance method using open-path gas analyzer” published in the journal Field Crops Research in April this year, Wassmann says intermittent irrigation during the vegetative stage was an effective water management strategy to lower the seasonal CH4 emissions. The researchers used the newly developed LI-7700 open-path methane analyser to measure CH4 fluxes from irrigated rice fields.

The study abstract concludes that the irrigated rice field is a carbon sink, but in their analysis of Bhattacharyya’s findings, Wassmann and Alberto point out their paper “does not make any generalised statement” as the crri scientists do on tropical lowland ecosystems. This may be a confusing response since both papers have similarities, but Wassmann is clear on one point. “I don’t think that we have to re-assess the overall perception of rice fields as sources of methane, and thus a net source of GHGs.” He says that rice fields can take up carbon for some time which may compensate for CH4 emission in given seasons, rendering this field a temporal sink of GHGs. “But if we assume that carbon uptake is a long-term process, one has to ask where all this carbon would actually end up? The only conceivable ecosystem compartment for long-term storage of carbon is the soil as the vegetation carbon pool is in a steady turnover,” says Wassmann.

His contention is that accumulation of carbon in soils is a finite process that cannot go on forever, except in peat soils, which are very distinct from rice soils. “Some rice soils have been cultivated under flooded conditions for centuries-and the soil organic carbon in these soils is not much higher than in soils that have been converted to flooded rice in relatively recent time,” says Wassmann. Any change in the cropping system, such as, moving from an upland crop to flooded rice, will sequester carbon only till a new equilibrium in soil organic matter is reached.

In response, Bhattacharyya points out that the crri paper did not state that lowland rice ecology is a CH4 sink. “We converted all possible input and output of carbon (including CH4) and used advanced EC method to estimate net exchange. Considering all the components of carbon balance on system basis, this ecology had a good potential to store considerable amounts of carbon,” says he.

This means the final word is yet to be declared on whether such rice fields are, indeed, carbon sinks.

Build a national database on GHGs

Pratap Bhattacharyya and his colleagues at the Central Rice Research Institute in Odisha have stirred up a controversy with their findings that tropical lowland rice ecosystems are net carbon sinks, a view that contradicts the mainstream view of rice cultivation as a major contributor to greenhouse gases. In an interview to Latha Jishnu, Bhattacharyya, senior scientist, who is now at the University of Georgia in the US, explains, along with fellow researcher A K Nayak, principal scientist, why their just published paper could change the way rice is perceived in the debate on climate change.

What made you look at the issue of greenhouse gases (GHGs) from rice from a different perspective?

Rice is the major food crop in Asia and about 80 per cent of it is grown under flooded conditions. It is grown in different environments, different conditions and different management practices which affect the rates of two potent GHGs: carbon dioxide (CO2) and methane (CH4) emissions. Hence rice is often considered a causative factor and culprit for climate change. To determine the reality of this in the Indian perspective, we conducted a year-long experiment at the CRRI experimental farm during wet season 2012 and dry season 2012-2013 using eddy covariance (EC) technique. The EC technique is a standard micrometeorological method to monitor and determine real time fluxes and net balance of CO2 and CH4 between the terrestrial ecosystem and the atmosphere.

What did this system tell you about rice?
It is clear that lowland rice is a source of methane (in kg/hectare scale) but the CO2 exchange is negative and quite larger in scale than methane.

Therefore, our approach was to see if we convert all input and output, including CH4 and CO2, in carbon terms and ecosystem basis in lowland rice whether the system behaves as a source of GHGs or a carbon sink. Considering the net ecosystem production (with rhizodeposition, algal biomass, root, stubble and compost added) along with the carbon input and removal, tropical lowland rice acts as net carbon sink, both seasonally and annually.

What are the implications of your findings for India?
The findings should stimulate a thinking process whether there can be zoning of rice areas that are favourable from climate change point of view and these areas should be nurtured. Understanding the processes and components of net ecosystem carbon budget in lowland flooded rice paddy is essential to know whether the system is behaving as net carbon sink or carbon source.

This should also hold good for other major cropping systems in India like ricewheat, rice-maize and wheat-soybean. We should build a national database on GHG emissions in particular and estimation of global warming potential (GWP) based on ecology and cropping systems.

8 July 2014. Posted by Sajim Manacaud
Thanks to the findings of crri.

Carbon Sink or Carbon Source; the crri, irri etc should suggest more strict environmental regulations to favor/ support/ protect the paddy fields.

Should not forget their high potential in water harvest!

Promote small farms/ farming in the country to support the local food requirements.

It is not required to produce the grains in Punjab and ship all the way to Kerala if the same grain can be produced locally in Kerala.

Our local self government bodies should be more innovative in supporting the local farmers and small farms.

8 July 2014. Posted by Archana Mathur
But how much% methane emmission is GHG from rice fields?
I want to someone to carry out scientific check on the methane release by cows on farms too.


 


Friday, 4 July 2014

Make India drought-proof : Sunita Narain

The editorial of Down to Earth. July 15, 2014, a must read for all. Here is the link:

FEAS will work on this area in near future. Here you may get the full editorial and the comments.

Make India drought-proof
Author: Sunita Narain
Jul 15, 2014 | From the print edition


METEOROLOGISTS ARE still not sure of the timing and intensity of El Niño. But it is clear that this monsoon will not be normal and there is a serious possibility that some parts of the country will be hit by drought and crop failure. The question is why we remain so unprepared to deal with crippling water shortages year after year. Why have all our efforts to drought-proof India failed?

What should we do now?

We have been gravely remiss about water management. I say this because we had no excuse not to act. The past 10 years have been good rainfall years. This is the bounty that governments had no right to squander away. It was in these 10 years that everything could have been done to harvest rain, to recharge groundwater, to build rural ponds and tanks and to improve the efficiency of water use. There is no excuse because the problems are known and the solutions have been tested, just not applied and worked upon.

Why do I say this? It was in the late 1990s that India saw its last crippling drought—rain failures for long years and over vast stretches. It was also in this period that innovations were made by different state governments to drought proof their regions. Andhra Pradesh launched the Neeru Meeru water conservation programme, Madhya Pradesh had the Ek Panch Ek Talab (one panchayat, one tank) programme and Gujarat the Sardar Patel Participatory Water Conservation programme to build thousands of check dams to harness rainwater. Tamil Nadu took the rainwater harvesting campaign to practically every house in Chennai.

In all these states, the key learning was that governments could no longer rely solely on surface water irrigation systems for drought management. It was clear by then that not only was groundwater the major source of irrigation, but also the bulk of cropped area remained rainfed. Rain provided relief and rescue for most of India’s agricultural area. Either because it was the only source of irrigation or because it was the source of groundwater recharge. So, instead of fighting this fact, governments learnt to build a new water future based on harvesting rain. Catch water was the slogan of that period.

In the subsequent decade of relative rainfall sufficiency, the opportunity was to build the water security network— not drought relief but relief from drought. Till mid-2000, water conservation was an agenda for the government. It was in this period that the National Rainfed Area Authority was set up; the watershed management programme was revamped; a new programme for repair, renovation and restoration of water bodies was launched and groundwater recharge was prioritised. The Mahatma Gandhi National Rural Employment Guarantee Act (MGNREGA) had the stated aim to conserve soil and water by building of tanks, ponds and check dams across the country.

Even as mission water conservation was launched, there was no drive to implement the programmes. Water conservation structures built under these programmes were either not completed or not designed to work. Today half-made, poorly designed and even more poorly maintained water assets litter the countryside. This expenditure should have drought-proofed the country. Then, the rainfed area and watershed projects got embroiled in bureaucratic tangles and turf wars. These programmes could not even fix the basic responsibility of who would regenerate and protect the watershed. In most cases this land is under the control of the forest department. It is time we got this right. MGNREGA needs to be drastically reworked so that it focuses on development first. The stress should be on finishing the village water security and development plan. Panchayat functionaries must be responsible for the quality of work and payment must be made accordingly. Other programmes that augment, conserve and efficiently use and reuse water should be energised.

We will not get many more chances to get the art of water management right. It is time to do or die. It is time we understood this.

Comments on the above article/editorial

A very timely Editorial as country faces possibility of deficient rainfall and may be even drought in some parts. Editorial rightly highlights the need of having water conservation implemented for making the country drought proof as deficient rainfall is not happening for the first time or nor it will be the last. Deficient rainfall/Droughts are part of natural variablity. In fact even in last ten years there had been three 2002, 2004 and 2009 pretty bad monsoon years. But all of us have very short menories and we become complacent after couple of good monsoon years.

2 July 2014. Posted by Ajit Tyagi

Yes, I agree we have failed in our water management programming. It does not address recurring draughts-floods have not created capacity on ground to efficiently manage water resources.

2 July 2014. Posted by NK Agarwal, Geo-Consultant & Advisor

Whenever Government takes decision on land allotment, conversion of land for industrial use etc is ID involved? Does IMD have any mathematical simulation model to predict change in climate- if say 100 acres of some forest are cleared, or if some lakes (in Bangalore 200 lakes have vanished and houses / plots formed) etc. I keep writing that having lots of tall multi-storied concrete buildings (which is at 1000 meter above sea level in the center of peninsula- far away for river or sea)- leads to reduction of rain. North west of south east monsoon is only for text books now- as most of the wind flow is from North of Bangalore from the land and not from sea side- hence temperatures go up and no rains. Instead of just raising alarm on post facto basis, IMD must start modelling and predicting adverse effects due to Government policies and warn them ahead. But IMD msut have tonnes of self confidence in its math simulation models.

2 July 2014. Posted by M S DIVEKAR

Good timely editorial. IMD is predicting deficit rainfall, but, it has happened in the last decade in most regions of the country that total amount of rainfall touched the average rainfall, it remained unevenly distribution during the season, which is important for crop production.
As pointed out that in watershed programmes, in few states watershed activities were carried out but the quality, design and technical aspects were not considered. In most places, the work was done for sake of doing and spending the allocated fund from government. Agricultural Engineers with specialization in Soil and Water Conservation Engineering could be of great help in this regard, as they are educated on both water conservation and efficient use. Since last 50 yrs, highly trained man power of this field are underutilized and are serving either in academics or in other diverse fields but not water conservation and management. Only few states are utilizing their services for these activities, however, inefficiency and corruption deep rooted in Indian DNA prevents from doing corruption free work which reflects the quality of work.

3 July 2014. Posted by Prashant Shrivastava

Every year some part or the other faces with drought or floods. With natural rhythm in precipitation – 60 year cycle in the All-India Southwest Monsoon Precipitation – these are covered in more areas. This resulted “political” drought or “political” flood to get funds that rarely reaches the really affected people. Now, everybody is now using El Nino as a culprit.

Of the 126 years (1880 to 2006) 84 years fall under normal – no El Nino or La Nina --; in 18 years El Nino appeared and in 24 years La Nina appeared. Of the 18 El Nino years, 6 years fall under normal or excess rainfall condition; 5 years fall under below normal and 7 years under deficit conditions. In the 30-year below the average cycle parts [1897-1926 & 1957-1986] around 50% of the deficit [< 90% of the average] years coincided with El Nino condition and also the in this period El Nino years also seen with normal rainfall. So, the El Nino impact on Indian rainfall is only a coincidence but not a condition.

This year’s media hype on El Nino and drought in India is only a game by Western MNCs to dump GM food in to India under the pretext of drought – Russia turned it down, China did the same, Africa long back said no to GM food imports and so with around 120 crores population India is the target --. Nobody bothered to look at the real temperature anomaly and advise the government and media, because there are no symptoms of El Nino. So, they say it may develop in July or August or September or December????. Why we should give importance to such observations. Can’t we educate our Indian media and politicians/bureaucrats on this vital misleading issue?

Same is the case with climate change. Media and people in important positions use climate change synonymous to global warming. We attribute all ills to global warming. Though when we study the IPCC’s AR5 in conjunction with the recent report of US Academy of Sciences & British Royal Society, the global warming component associated with the so-called increase of anthropogenic greenhouse gases in to atmosphere is < 0.25 oC [1951 to 2010] and < 0.5 oC by 2100. Even this is high because of urban-heat-island effect is over emphasized with dense met network covering this zone and rural-cold-island effect is under emphasized with sparse met network in this zone – recent studies showed irrigated agriculture bring down the temperature levels. This is reflected clearly in satellite data sets. So, this is not an important issue in agriculture – even IPCC in it’s AR5 report emphasized the importance of natural variations in coming decades.

So, like our forefathers we must adopt crops & cropping systems based on rainfall. This is not possible high input mono crop system. The second issue is water. We misuse water when it is available and cry when it is not available. We don’t plan. For example under lift irrigation [wells/bore-wells] we suggested to go for less water intensive crops/cropping system but they refuse to adopt this but attribute motives/politics. When we tell them use drip and sprinkler irrigation, they refuse to follow. We must stop them growing throughout the year and ask them to limit to crops and so that the ground water can recharge. So government must develop a strategy that must be implemented and tell them if they don’t follow they will not get subsidy. Like this so many things could be done but it all depends upon the political will and farmers’ interest. We must not forget to bring in the animal husbandry in to this system and thus fodder producing agriculture system.

Dr. S. Jeevananda Reddy

3 July 2014. Posted by Dr. S. Jeevananda Reddy

Dear Sunita ji,

During the previous government ruling many, many Mother trees were uprooted to widen the roads or the said wood was used for homes. Due to lopsided urban development policies capital city centric development models more development was concentrated in and around capital cities.

By mindless migration from villages to metros or cities what we neglected in our country is inability to study the "Nature Technologies" being used in the countries like Japan. Our children should be taught how to maintain cordial relations with nature and how to protect nature and how to improve greenery.

The only way to counter drought like situation is encouraging the people living in villages to implement the nature technologies and asking them to follow the methods based on them. Small farmers must be trained to study, practice and implement the nature technologies.

In another angle, Hindu scriptures mentioned various methods to counter the imbalances in nature. Because spiritually speaking each and every human being is composition of five elements i.e. Akash, vayu, tejas, apus (water) and pridvi (earth). If these five are contaminated outside, the five elements within the human beings will also be contaminated. All A and B grade temples must conduct homas or yagnas or have to do japas for appeasing rain God. It must be a continuous practice, adequate changes have to be made in Endowments Acts of each State.

Not only that even the common people have to meditate for rains and have to recite the mantras relating to Varuna or rain God etc. Those who believe secularism may not accept this method.

This is the time to study the inner essence of Vedic Scriptures like Atharva Veda and related branches to understand the foresight of ancient Seers or Rishis, how they protected the environment and what steps they have taken to counter drought like situation.

Instead of depending on western environmental protection models we have to depend on indigenous models and nature technologies.
 

Thursday, 3 July 2014

Introducing Sree Srijnan Sanyal

 Dear Srijnan,
Thanks for joining FEAS. We are really honoured for your joining in FEAS. Let me introduce you to our members and viewers.

Srijnan Sanyal, residing at Gurgaon, Haryana, is a Senior Corporate executive and expert in Telecom and IT Industry. He has been associated with IT-Telecom revolution in the country since 80s, has pioneered prepaid mobile telephony; popularized Telecom value added services including Mobile Banking, Digital Media distribution and interactive Tele-viewing in our country. In his long corporate career in India and abroad he has led many business transformation initiatives. Srijnan is presently working with a large global IT conglomerate in the Asia-Pacific region.

Srijnan believes the key to sustainable environment in our country lies in creating a sustainable economic environment for the underprivileged community. He is working on a social entrepreneurship model for rural India that addresses the triple bottom-line of commercial sustainability, community sustainability and environmental sustainability. It will undertake economic, educational, cultural and social initiatives for the improvement of the quality of life; promote sustainable growth and harmonized living. It will actively engage to bring the benefits of relevant science and technology available anywhere in the world and employ the principles of modern management to institutionalize its operations and developments.

Introducing Sree Himadri Maitra

Dear Himadri Maitra,

Thanks for joining FEAS. 

Let me introduce you to our members and viewers.
 
Sree Himadri Maitra worked as Block Disaster Management Officer (erstwhile Block Relief Officer), in Relief operation in drought, flash flood and also a Master Trainer in Literacy Programme at Taldangra, Bankura, and at Amta - II, Howrah. He was at Directorate of Disaster Management, Kolkata as Disaster Management Officer (erstwhile Relief Officer) and worked as Relief operation in floods in state, Coordinating air-dropping, Control room duty at the time of disaster, Coordinating delivery of relief materials from airport in Orissa super cyclone, Coordinating delivery of relief materials from Kolkata Port to Andaman after Tsunami, Member of committee formed to prepare Disaster Management Manual. 

He wrote a paper on "Integration of Indigenous Methods of Landslide Risk Reduction into National Disaster Management Framework".

At present he is Sub-Divisional Disaster Management Officer,  Sub-Divisional Office, Bongaon Sub-Division, North 24 Parganas district of West Bengal.




We are honoured for his joining in FEAS.