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Energy, Resources and the Environment

Words on Wednesday: Farmers’ perceptions of and adaptation strategies to climate change and their determinants: the case of Punjab province, Pakistan

Words on Wednesday aims at promoting interesting/fun/exciting publications on topics related to Energy, Resources and the Environment. If you would like to be featured on WoW, please send us a link of the paper, or your own post, at ERE.Matters@gmail.com.

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Abid, M., Scheffran, J., Schneider, U. A., and Ashfaq, M., 2015. Farmers’ perceptions of and adaptation strategies to climate change and their determinants: the case of Punjab province, Pakistan, Earth Syst. Dynam., 6, 225-243.

Abstract:

Climate change is a global environmental threat to all economic sectors, particularly the agricultural sector. Pakistan is one of the countries negatively affected by climate change due to its high exposure to extreme events and low adaptive capacity. In Pakistan, farmers are the primary stakeholders in agriculture and are more at risk due to climate vulnerability. Based on farm household data from 450 households collected from three districts in three agroecological zones in the Punjab province of Pakistan, this study examines how farmers perceive climate change and how they adapt their farming in response to perceived changes in climate. The results demonstrate that awareness of climate change is widespread throughout the area, and farm households make adjustments to adapt their agriculture in response to climatic change. Overall 58% of the farm households adapted their farming to climate change. Changing crop varieties, changing planting dates, planting of shade trees and changing fertilizers were the main adaptation methods implemented by farm households in the study area. The results from the binary logistic model reveal that education, farm experience, household size, land area, tenancy status, ownership of a tube well, access to market information, information on weather forecasting and agricultural extension services all influence farmers’ choices of adaptation measures. The results also indicate that adaptation to climate change is constrained by several factors such as lack of information, lack of money, resource constraints and shortage of irrigation water in the study area. Findings of the study suggest the need for greater investment in farmer education and improved institutional setup for climate change adaptation to improve farmers’ wellbeing.

Schematic framework of farmers’ adaptation process in Pakistan.

Schematic framework of farmers’ adaptation process in Pakistan.

How a geophysical extreme event dramatically changed fieldwork plans – a personal account of the Gorkha Earthquake

by Viktor Bruckmana and Klaus Katzensteinerb
aCommission for Interdisciplinary Ecological Studies, Austrian Academy of Sciences, Vienna; bInstitute for Forest Ecology, University of Natural Resources and Life Sciences (BOKU), Vienna

Options for Integrated Forest Management in the Gaurishankar Conservation Area is the title of one of our ongoing projects with collaborating partners from Nepal, China and Austria. The Gaurishankar Conservation Area (GCA) covers 2.179 km² and was installed in 2010 by the Government of Nepal. It is located in Eastern Nepal bordering with Mt. Everest National Park in the East, Langtang National Park in the West and Tibet Autonomous Region of China in the North. Of the total area of GCA, 35% is covered by forest. The elevation ranges between 1000 and 7000m a.s.l., which leads to a complex ecosystem with 16 major vegetation types and high floral and faunal diversity. The region is home to approximately 60.000 people. Due to a long and complex settlement history, different ethnic and religious groups contribute to the outstanding cultural diversity of GCA. In addition, the entire region is rich in water resources and the catchment area of a number of rivers which are the source of some major ongoing and projected hydro-power projects.

Map of Gaurishankar Conservation area (GCA) including respective Village Development Committees (VDC’s) and localities within the Tamakoshi River valley that are mentioned in this post.

Map of Gaurishankar Conservation area (GCA) including respective Village Development Committees (VDC’s) and localities within the Tamakoshi River valley that are mentioned in this post (by NTNC, the National Trust for Nature Conservation, Lalitpur, Nepal).

Study aims

The aim of our proposed study was to assess land use and forest resources management in one of the remotest parts of the recently installed conservation area. Therefore, we suggested a 2-step approach. In the first step a participatory rural appraisal (individual and group interviews and group discussions on land use and livelihood, including mapping of resources and activities) gives background information on human-ecosystem interactions. In the second step we intended to set up a number of monitoring plots according to local conditions and the results from discussions and mapping of activities in terms of land use. Our aim was to involve stakeholders from the beginning since the results should be useful for these communities and not only for the sake of science. As such, the entire project concept fits very well to the EGU, Division Energy, Resources and the Environment because it is a nice example of interdisciplinary efforts in order to understand local systems of energy, resources and the implications on the environment.

Methods and approach

Participants of the project kick-off workshop in Kathmandu (by Prof. Dr. Klaus Katzensteiner)

Participants of the project kick-off workshop in Kathmandu (by Prof. Dr. Klaus Katzensteiner).

Our participatory approach started with a workshop in Kathmandu on 22nd of April 2015, where we invited important stakeholders from various governmental and institutional bodies to introduce the project and the respective aims. It was important to us to get a good overview on the impacts of land use restrictions and guidelines on the local communities since the establishment of GCA, as this would be the baseline assessment for our activities.

In a next step, we prepared a set of questions, including demographic and societal indicators as well as information about current land use, consequences of ongoing hydropower projects and to a certain extent future perspectives. On 23rd and 24th of April, we conducted a range of semi-structured group and individual interviews based on the prepared set of questions.

We conducted a set of semi-structured interviews in order to assess land management practices and the impact of new management policies since the Gaurishankar Conservation Area was set up in 2010 (by Dr. Viktor Bruckman)

We conducted a set of semi-structured interviews in order to assess land management practices and the impact of new management policies since the Gaurishankar Conservation Area was set up in 2010 (by Dr. Viktor Bruckman).

Baseline assessment

It turned out that large impact on societies, as well as land use is expected from the Upper Tamakoshi Hydropower Project (UTHP), representing the largest hydropower plant in Nepal with a capacity of 456MW. The construction site of the dam is located in the village of Lamabagar, approximately 7 km from the Tibetan border. In order to facilitate access to the construction site, a road was build and it has already considerable impacts. Formerly remote settlements are now connected to the road network and improvements in the sectors health, education and business opportunities were reported [1].

Agriculture on terraces and small-scale stock farming dominates in lower elevations. Litter is collected in forests and composted together with manure which serves then as natural fertilizer for agriculture.

The impressive Gaurishankar, on the Nepal-Chinese border is 7.134m high and serves as eponym for the respective conservation area. Typical land use practices are shown in the foreground with terrace farming and trees used as a source of fodder. Together it represents a kind of agroforestry (by Dr. Viktor Bruckman)

The impressive Gaurishankar, on the Nepal-Chinese border is 7.134m high and serves as eponym for the respective conservation area. Typical land use practices are shown in the foreground with terrace farming and trees used as a source of fodder. Together it represents a kind of agroforestry (by Dr. Viktor Bruckman).

Animal husbandry with Yaks and Chauri (hybrids between Yaks and local cattle) or goats dominates in higher altitudes where agriculture is unable to produce enough goods for survival. The practice of lopping (cutting green twigs and branches of trees as animal fodder), especially on Quercus species is a common practice throughout the entire region. In lower altitudes, one may find nice examples of agroforestry, i.e. the coexistence of fodder trees that are being regularly lopped and agricultural terraces. Life is difficult in these remote areas, the Gaurishankar Conservation Area Management Plan states that the average time of food security per year from own farm production ranges from 3.4 to 8.7 months [2] in different Village Development Committees (VDC’s, smallest political units in Nepal; Gaurishankar Conservation Area consists of 22 VDC’s). This means that the families rely on additional income in order to purchase food items for the duration of 3.3-8.6 months per year in the worst case.

Freshly collected Yartsa Gunbu (Ophiocordyceps sinensis) may provide between 30 and up to 70% of the annual family income (by Dr. Viktor Bruckman).

Freshly collected Yartsa Gunbu (Ophiocordyceps sinensis) may provide between 30 and up to 70% of the annual family income (by Dr. Viktor Bruckman).

Forests in the remote parts of the valley upstream of Lamabagar are more or less intact, and management seems to be relatively sustainable over the course of a few centuries, with the main non-timber forest products (NTFP’s) such as animal fodder from lopping, collection of litter, herbaceous plant species and medical plants as well as fuelwood and to some extent also construction wood. The upper tree line in this valley lies between 3600-3700m. Male family members usually seek for income opportunities in the capital, Kathmandu or further away in countries such as India, Qatar or Malaysia, while female members take care about agriculture and animal breeding. A unique source of income especially in this region is the collection of Yartsa Gunbu, the fruiting body of a fungus (Ophiocordyceps sinensis), parasitizing on the larvae moths on alpine pastures above the tree line. Approximately 30-60% of the annual family income may be earned from selling Yartsa Gunbu, which is especially demanded in Chinese traditional medicine as it is believed to cure cancer. Yartsa Gunbu is usually collected by teenagers and they typically spend a few days in the mountains at once. According to them, between 1500 and 4000 of them were in the mountains at the time we arrived Lamabagar as Yartsa Gunbu is only collected in certain seasons.

Lamabagar (2000m a.s.l.) lies on the flat riverbed of the Upper Tamakoshi River, which developed as a consequence of a massive landslide (probably earthquake-induced) in the past (by Dr. Viktor Bruckman).

Lamabagar (2000m a.s.l.) lies on the flat riverbed of the Upper Tamakoshi River, which developed as a consequence of a massive landslide (probably earthquake-induced) in the past (by Dr. Viktor Bruckman).

Lamabagar is located at 2000m a.s.l. and the starting point of our expedition since the road ends at the hydropower dam construction site. After having a good background impression of the current situation, we were prepared to leave from Lamabagar on the Morning of 25th of April. Our plan was to reach the Lapchi Monastery on 27th, while continuing interviews in the smaller settlements on the way. Lapchi Monastery is situated at the border to Tibet at around 3800m a.s.l. and it is one of the most important spiritual places in the entire Tibetian region [3]. We would have marked potential sites for setting up monitoring plots while proceeding towards Lapchi. On the way back and after discussing potential sites, we would have established some of the plots to conduct a biomass and species inventory according to a pre-defined protocol. In addition, we would have described soil profiles and taken samples for the determination of organic carbon stocks.

Fieldwork starts with hiking

The morning of 25th of April was not very convincing to start an exhausting hike since it was raining. However, at least it would not be as hot and therefore we would be able to proceed faster than initially expected. Our three porters came to our accommodation in the morning. We handed them over most of the scientific equipment and some of our food supplies. The larger share of our supplies was sent to the Lapchi Monastery by helicopter previously, and local porters were asked to carry those items to the settlements downstream. So we would have our food at each station where we planned to stay during our expedition. The porters asked us to hand them over more load as they are trained to easily carry 30kg or more. I decided to give them some of my bulky items, e.g. sleeping bag or mattress. The portable water filter, although relatively heavy, was with me since I was only carrying one liter of drinking water with me, certainly not enough for a whole day trek. The porters decided to take a breakfast and follow us later on as they would easily catch up with us before noon, as they told us. We started to hike towards Lumnang, which would be our destination on this first day. It is a small settlement of around 15 buildings and the last permanent settlement in this valley. All other settlements upstream are temporary and used during summer months (except Lapchi Monastery).

A view towards Lamabagar (downstream) after approx. two hours of hiking. Rhododendron arboretum is in full bloom, making the hike a wonderful experience despite the weather conditions (by Dr. Viktor Bruckman)

A view towards Lamabagar (downstream) after approx. two hours of hiking. Rhododendron arboretum is in full bloom, making the hike a wonderful experience despite the weather conditions (by Dr. Viktor Bruckman).

Although we faced constant drizzling rain, we were overwhelmed by the beauty of this remote region. Steep cliffs of metamorphosed sedimentary series (Tethys Himalaya within the Central Himalayan Domain) were dominating the first few hours of hiking. Unmanaged mixed deciduous forests with high diversity were situated along the streams and on ridges. At around 11:30 AM, we just passed probably the most difficult terrain with a number of steep, difficult and exhausting passages.

The view to the stupa at the river junction marks the entrance to the Lapchi river valley (by Prof. Dr. Klaus Katzensteiner).

The view to the stupa at the river junction marks the entrance to the Lapchi river valley (by Prof. Dr. Klaus Katzensteiner).

On the top of this, we were able to see a stupa that was built at the junction of Lapchi River and another stream from Tibet. From this point, the joint stream is called Tamakoshi River. We took a short rest at this magnificent place before descending to the entrance of the Lapchi River valley, characterized by steep cliffs of 300-400m on the Eastern side of the river and a densely forested slope on the western side, where the trail is located approx. 10-50m from the river. The weather started to change gradually as rain stopped and there were a few glimpses of sunlight.

The moment when everything changed completely

Rockfall from the opposite cliffs made our location a highly dangerous place (by Prof. Dr. Klaus Katzensteiner)

Rockfall from the opposite cliffs made our location a highly dangerous place (by Prof. Dr. Klaus Katzensteiner).

At 12:05 local time, the peaceful appearance suddenly stopped, as the ground beneath our feet, shrubs and bushes started to literally vibrate around us and the remaining water from the surrounding trees poured on us just like a strong rainfall event. After several seconds, vibrating turned into shaking and first rocks of the size of a football came down the slope on our side. After realizing it is actually an earthquake, we (I was together with my Nepalese colleague Prof. Mohan Devkota at this time, his student Puskar was somewhere about 50m ahead and Prof. Katzensteiner from BOKU University was in front) looked for a safe place while more and larger rocks came down. While hiding behind a tree which would hopefully protect us from rockfall and praying for the end of this nightmare, it turned out to be even worse. With amazingly loud sounds, similar to detonations, we realized that large pieces of rock and landslides came down at certain locations from the cliffs opposite of the river. These large rocks (with a size equal to small houses) smashed into the river, immediately braking up to several smaller pieces. These spread in all directions, felling entire trees on their destructive way.

 Seconds after the main tremor was over, everything was changed. The river color turned brown, dust and Sulphur smell was in the air and the path was destroyed by small landslides or rocks (by Prof. Dr. Klaus Katzensteiner).

Seconds after the main tremor was over, everything was changed. The river color turned brown, dust and Sulphur smell was in the air and the path was destroyed by small landslides or rocks (by Prof. Dr. Klaus Katzensteiner).

As this happened directly on our opposite and all around us was dust, falling trees and incredible noise, I was almost certain that this would be the last impressions of my life. But both of us were lucky, we survived this without a single scratch. Still hard to realize what just happened, we were immediately looking for our colleagues, but found only Prof. Katzensteiner, who was standing underneath an overhanging rock to protect himself from rockfall which still occurred as a consequence of constant aftershocks. He told that a Lama (monk) must have come down towards our direction and may be with the student who was among us during this event. However, there was no trace of them, despite loudly calling for them. A large rock of the size of a truck was lying right on the trail and we were all hoping that they were not buried under it. We were waiting a few minutes under this rock, as it was still too dangerous to look after our colleagues. Fortunately they came along the way, apparently not injured, after another five minutes or so. It turned out that they were running uphill when the rocks came down from the cliffs, in order to escape from the rock bullets from the river. The lama saved our student’s life as it turned out as he was almost hit by a large rock, which destroyed his water bottle that was attached to his back bag.

Luck in an unlucky situation

The lama guided us to a holy cave that was washed out by the river and which was only a few hundred meters away from the place where the earthquake hit us. But we started to become worried about landslides that might have blocked the river upstream and the destructive consequences of a potential flash flood. Therefore, we carefully observed the water level of the river that changed its color to dark brown in the meantime. After one hour or so we decided to leave the valley immediately, together with the lama, who knows the terrain very well. However, once we reached the point where we entered Lapchi valley at the river junction, we realized that the trail was gone due to a massive landslide and there was no opportunity to bypass this trail, even not with our experienced guide. Therefore he recommended hiking upstream to a meditation center where around 20 lamas meditate in tents underneath the (slightly overhanging) cliffs.

The retreat where lamas provided us with food and shelter (by Prof. Dr. Klaus Katzensteiner).

The retreat where lamas provided us with food and shelter (by Prof. Dr. Klaus Katzensteiner).

This place is about 2 hours hiking from Lumnang, the village where we intended to stay. The trail was partly destroyed by landslides so we had to somehow cross rather dangerous sections (while there were constant aftershocks), but finally we were able to reache the meditation place or retreat. The lamas kindly offered us milk tea and food, and in addition a place to sleep. What an incredible luck in our situation! We had no supplies with us and only relatively light equipment, no sleeping bags, mats etc.. The lamas told us that if we are lucky, we might be able to get a mobile signal at a certain location in the mountains, but local conditions allow a successful contact usually only in the morning at around 10:00 AM. We tried to call in the following morning and were successful, just a few seconds, but we were able to communicate the most important information that we are all safe, but we need a helicopter as we are unable to leave the valley. At this time, we did not know that this would be actually the only time when we were able to contact the outside world; we never again got a signal in the coming days, despite our desperate attempts. While we were not sure if and when we would be rescued (an old radio enabled us to receive AM stations from India, where we learned that this was a major incident), we were worried about our families since they probably didn’t know about our situation.

The footpath was completely destroyed and stones still falling down every now and then as a consequence of multiple aftershocks and the loose bedrock material in this region (by Assoc. Prof. Dr. Mohan Devkota).

The footpath was completely destroyed and stones still falling down every now and then as a consequence of multiple aftershocks and the loose bedrock material in this region (by Assoc. Prof. Dr. Mohan Devkota).

In fact, everyone was involved in planning our rescue mission, from our families to officials of our respective institutions, ministries, embassies to the local military camps. We just did not know what was going on. We were finally rescued after five days as a helicopter came into the valley and we quickly went to the next helipad (which was approx. 1 hour hiking from the place where we stayed). The helicopter was waiting there and brought us to the army camp in Charikot and returned one more time to provide the villagers from Lumnang (which is completely destroyed according to a number of reports from the lamas and inhabitants) with medicine and basic food items.

Tragic consequences

After five days, we were finally rescued by the helicopter and the nightmare was finally over for us. However, it still continues until today for the villagers who have lost their homes and many of them also family members and relatives (by Dr. Viktor Bruckman).

After five days, we were finally rescued by a helicopter and the nightmare was finally over for us. However, it still continues until today for the villagers who have lost their homes and many of them also family members and relatives (by Dr. Viktor Bruckman).

On the way out, we realized that landslides had wiped off large sections of the trail and there would have been only minor chances to escape from this valley for us. Approximately 80% of all building structures were destroyed. Later we unfortunately learned that one of our porters was killed by a landslide and another one was seriously injured. Only one of them managed to safely return to Lamabagar. Several groups of people (one group was heading towards Lapchi, we overtook them early in the morning, and another group of hydropower experts was heading towards Lamabagar) are still missing. Locals reported that there were many dead bodies on the river banks of Tamakoshi River upstream of Lamabagar, and 300 people collecting Yasarguma are still missing [4]. There were also a number of fatalities in Lumnang as reported by the lamas but the fact that the quake hit Nepal during daytime probably saved many lives as most of the people were staying outside.

Finally we have survived. However, our deepest condolences are with the family of the porter that has lost his life during our expedition (by Prof. Dr. Klaus Katzensteiner).

Finally we have survived. However, our deepest condolences are with the family of the porter that has lost his life during our expedition (by Prof. Dr. Klaus Katzensteiner).

Geophysical background

The April 25th Gorkha Earthquake was the largest one in the region since the Bihar quake in 1934. It measured 7.8 on the moment magnitude scale (i.e. the Richter scale) and the epicenter was located around 70km west of Kathmandu at approximately 15km depth [5]. In addition to the shallow quake, massive displacements occurred as observed by ESA’s Sentinel satellites [6] and there is evidence that Mt. Everest is shorter by about 2.5 cm since the earthquake [7]. Moreover, the earthquake was so intense that NASA was able to observe a disruption of the distribution of electrons in the ionosphere [8]. Despite the fact that nobody of us expected an earthquake, it was not really a surprise as a number of scientists, including Roger Bilham of University of Colorado, warned that crustal stresses are building up in Nepal [9].

On May 12th, 2015 days after all of us were back at home with our families, another intensive earthquake was recorded in Nepal, again as a consequence of thrust faulting. The USGS reported that the epicenter was just a few km away from the area where we were about to start our fieldwork [10]. It occurred along the same Main Himalayan Thrust where the initial earthquake happened only days before and is therefore considered as a large aftershock (M 7.3). Since then, we are unable to contact anybody in Lamabagar as the communication system has been apparently destroyed. The powerful aftershock caused further damages; virtually all remaining buildings collapsed.

What we have learned and how it influences our future activities

The question is, of course, what we have learned from this event and what are we going to do next. Certainly we will bring a satellite phone or at least an EPIRB (Emergency Position-Indicating Radio Beacon) with us whenever we are working in remote areas. Apparently we are unable to ignore the facts and continue with our initial project aim. Despite the fact that the area is currently inaccessible on land, we would probably not meet the communities’ needs if we stick to the initial ideas. Therefore we will carefully assess the current situation and subsequently develop a new proposal on how to support these remote villages on a long-term and sustainable basis. One approach can be to develop local forest resources, i.e. construction wood for reconstruction of buildings which are safer against earthquake disaster as compared to current building structures. In addition to this long-term support, we are desperately seeking for immediate support for the families of our porters, especially those of the porter who passed away, leaving behind two daughters and two sons, and the porter who was severely injured.

Please help us to support affected families

For the purpose of collecting donations, we opened an account at the University of Natural Resources and Life Sciences Vienna (BOKU). Funds will be collected in a transparent manner and directly used for supporting the porter’s families and the villagers of Lumnang, who have lost everything and they will most likely not receive help from other sources soon. We will facilitate support through the trustworthy Nepalese project partners (including full documentation) and the Lamas of Lapchi monastery and from the retreat where we were able to stay. Please help us to support this remote region; even a small contribution is very much appreciated. Our direct contacts ensure that 100% of the donations reach the target group.

Here are the account details for wire transfer:

Recipient: Universität für Bodenkultur Wien, Spenden IBAN: AT48 3200 0018 0050 0512 BIC: RLNWATWWXXX Payment reference: 7912000003

Payments via Credit Card are also possible (Master Card and Visa). Should you wish to pay per credit card, please send an e-mail containing your name, address, card number, expiry date and security code (3-digits) to c.hofer@boku.ac.at.

We thank you very much for your contribution!

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References:
  1. Manandhar, R. (2014) Upper Tamakoshi a boon for locals. Retrieved from http://www.ekantipur.com/2014/02/01/national/upper-tamakoshi-a-boon-for-locals/384741.html [28.05.2015]
  2. NTNC (2013) Gaurishankar Conservation Area Management Plan 2013-2017. Narma Consultancy Pvt Ltd in association with Practical Solution Consultancy Pvt Ltd., Kathmandu, Nepal.
  3. Huber, T. (1997) Guidebook to Lapchi. In: Lopez, D.S. Jr. (Ed.) Religions of Tibet in Practice. Princeton Readings in Religions, Princeton University Press, Princeton, New Jersey, pp 120-134.
  4. Kathiwada, R. (2015) 300 Yarchagumba pickers missing in Dolakha. Retrieved from http://www.myrepublica.com/t20/item/20033-300-yarchagumba-pickers-missing-in-dolakha.html [28.05.2015]
  5. Sandiford, M., Rajendran, C.P. and Morell, K. (2015) The science behind the Nepal earthquake. Retrieved from http://theconversation.com/the-science-behind-the-nepal-earthquake-40835 [28.05.2015]
  6. DLR (2015) Update: Disaster relief – DLR provides aerial images of Kathmandu. Retrieved from http://www.dlr.de/dlr/en/desktopdefault.aspx/tabid-10081/151_read-13487/#/gallery/19391 [28.05.2015]
  7. Oskin, B. (2015) Mount Everest Shrank As Nepal Quake Lifted Kathmandu. Retrieved from http://www.livescience.com/50677-nepal-earthquake-radar-satellite-view.html [28.05.2015]
  8. Stallard, B. (2015) Nepal’s Earthquake was So Intense it Changed Both Land and Air, Says NASA. Retrieved from http://www.natureworldnews.com/articles/14489/20150504/nepals-earthquake-intense-changed-both-land-air-nasa.htm [28.05.2015]
  9. Bilham, R. (2004) Earthquakes in India and the Himalaya: tectonics, geodesy and history. Annals of Geophysics 47/2-3, pp839-858.
  10. USGS (2015) USGS Earthquake Hazards Program, M7.3 – 19km SE of Kodari, Nepal. Retrieved from http://earthquake.usgs.gov/earthquakes/eventpage/us20002ejl#general_summary [28.05.2015]

Earth Sciences: ‘Rocks for Jocks’, or hard science?

According to some Republicans in the US, Earth Sciences cannot be regarded as one of the ‘pure sciences’, or hard science. Is Earth Sciences simply Rocks for Jocks, or do the earth sciences actually encompass some fundamental work here? Suggestions have been made that NASA should steer its focus away from Earth Sciences and more onto space exploration and research. If NASA complies, it would most likely mean that will be redirected from Earth Sciences to Planetary Sciences, leaving less budget to study our own planet. A final vote still needs to be made, but what should the outcome be?

“Earth sciences are a fundamental part of science. They constitute hard sciences that help us understand the world we live in and provide a basis for knowledge and understanding of natural hazards, weather forecasting, air quality, and water availability, among other concerns.”

– American Geophysical Union CEO Christine McEntee –

I wholeheartedly agree with Christine McEntee, without Earth Sciences we would definitely not be able to study and better understand some of the most challenging issues society is facing these days: climate change, earthquakes, and energy production, to name a few. Less money automatically will mean less research being done to know more about our own planet. Knowing more about Earth will also help us to understand those other far-away inhabitable planets we are after.

Read the whole article on Science Insider, as well as one of the replies at the AGU Blogoshere. How do you feel about Earth Sciences as a pure science? Do you agree? What research are you doing to help us forward in understanding the Earth (or other planets)? Let us know 🙂

Total Solar Eclipse from the Perspective of Space (by Maximilian Reuter, taken from ImagGeo)

Total Solar Eclipse from the Perspective of Space (by Maximilian Reuter, taken from ImagGeo)

Words on Wednesday: Cobalt, chromium and nickel contents in soils and plants from a serpentinite quarry

Words on Wednesday aims at promoting interesting/fun/exciting publications on topics related to Energy, Resources and the Environment. If you would like to be featured on WoW, please send us a link of the paper, or your own post, at ERE.Matters@gmail.com.

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Lago-Vila, M., Arenas-Lago, D., Rodríguez-Seijo, A., Andrade Couce, M. L., and Vega, F. A., 2015. Cobalt, chromium and nickel contents in soils and plants from a serpentinite quarry, Solid Earth, 6, 323-335.

Abstract:

The former serpentinite quarry of Penas Albas (Moeche, Galicia, NW Spain) left behind a large amount of waste material scattered over the surrounding area, as well as tailing areas. In this area several soils were studied together with the vegetation growing spontaneously over them with the aim of identifying the bioavailability of heavy metals. The potential of spontaneous vegetation for phytoremediation and/or phytostabilization was evaluated. The pH of the soils ranges from neutral to basic, with very low organic matter and nitrogen contents. There are imbalances between exchangeable cations like potassium (K) and calcium (Ca), mainly due to high magnesium (Mg) content that can strongly limit plant production. Moreover, in all of the studied soils there are high levels of cobalt (Co), chromium (Cr) and nickel (Ni) (>70, >1300 and >1300 mg kg-1, respectively). They exceed the intervention limits indicated by soil guideline values. Different soil extractions were performed in order to evaluate bioavailability. CaCl2⋅0.01M is the most effective extraction reagent, although the reagent that best predicts plant availability is a mixture of low molecular weight organic acids. Festuca rubra, L. is the spontaneous plant growing in the soils that accumulates the highest amount of the metals, both in shoot and roots. Festuca also has the highest translocation factor values, although they are only >1 for Cr. The bioconcentration factor is >1 in all of the cases, except in the shoot of Juncus sp. for Co and Ni. The results indicate that Festuca is a phytostabilizer of Co and Ni and an accumulator of Cr, while Juncus sp. is suitable for phytostabilization.

Extraction efficiency. In each soil, bars with different letters indicate significantly different EF values (p <0.05) for each metal. Hanging bars are the standard deviation.

Extraction efficiency. In each soil, bars with different letters
indicate significantly different EF values (p <0.05) for each
metal. Hanging bars are the standard deviation.