PCRWR plans to expand scope of SMS service for farmers

on 28/11/2018

Pakistan Council for Research and Water Resources (PCRWR) has planned to expand the scope of `Irrigation Advisory SMS Service for the Farmers’ by increase the number of registered farmers from existing 20,000 up to 1, 00,000 soon. The service was launched on April 18, 2016, as an outcome of international collaboration extended by the University of Washington and NASA with an aim to help reduce overwatering and enhance crop yields for Pakistani farmers. The University of Washington is providing real-time daily Potential Evapotranspiration and precipitation for entire Pakistan using NASA’s remotely sensed data. PCRWR determined crop coefficients (Kc) for different crops in different agro-climatic zones of Pakistan. “PCRWR has planned to extend its Irrigation Advisory Service to 1, 00,000 farmers now while in the long run, the council envisions extending it to all farmers of irrigated areas through international and national coordination”, Chairman PCRWR, Dr. Muhammad Aslam Tahir stated this while talking to APP.

The service has already been informing the farmers of 41 districts (irrigated areas) about their net weekly irrigation requirements, considering Evapotranspiration (ET) and precipitation. Dr. Aslam said around 90 percent of the water is consumed in the agriculture sector of the country and most of it is wasted due to improper utilization.

The objective behind initiating this service was to conserve this water by educating farmers about actual water requirement for their crops.

The farmers, through this service, get weekly information on how much water their crop is needed and if there is chances of any rain or not during the next week.

Kashmiri expatriates sign dev MoU with MDA

on 28/11/2018

Kashmiri expatriates-owned private entrepreneur and Mirpur Development Authority [MDA] signed a memorandum of understanding [MOU] for the construction of three crossing bridges for pedestrians at the busiest central Allama Iqbal Road – besides installation of traffic signals at major streets of this ancestral city of over a million of UK-based Kashmiri expatriates.

M/s AJ Building Mart will bear all the expenditures to over Rs30 million for both of the projects from its own resources without relying on any financial requirement from the Mirpur Development Authority [MDA], which is already passing through financial crunch due to the paucity of required funds from its own resources.

MDA DG Ch Ejaz Raza and MD AJ Builders Mart Ajmal Hussain signed the MoU for the construction of three Pedestrian Steel Bridges in front of MUST varsity campus, Divisional Headquarters Hospital and at Central Naangi shopping on main Allama Iqbal Road besides installation of traffic signals at Azad Megamart Chowk, Quaid-e-Azam chowk and at various sites on Mian Muhammad Road, Allama Iqbal Road and other busy streets of the city.

Under the MoU, the AJ Builders Mart would construct traffic signals at six different sites besides construction of three crossing bridges for pedestrians at Allama Iqbal Road.

Traffic signals would be installed in the stipulated timeframe of one year whereas the bridges would be constructed in a two-year period.

Unveiling salient features of the project and details of the MoU, Director Planning and Horticulture MDA Mirza Kaleem Jiraal said that under the MoU, the “MDA” seized and possessed the specified land where six (6) traffic Signals and three (3) pedestrian crossing bridges, to be built and installed at the above sites.

The MDA has agreed to lease the aforesaid “PREMISES” to the “LESSOR” for the purposes of management and exclusive marketing rights with effect from the date of signing this agreement on the following terms and conditions, he added.

First ever revision of Islamabad master plan

on 28/11/2018

A commission led by a civil servant will be appointed within six months.

Islamabad’s master plan is being revised for the first time in its 58-year history. The task would be given to an independent commission, it is decided.

Prime Minister Imran Khan’s orders for the first ever revision of the capital’s master plan poured in during his meeting with the Capital Development Authority (CDA).

The commission would be formed within next three to six months, Minister of State for Interior Shehryar Afridi said. A civil servant would head the commission.

The requirements of the city’s population have multiplied over the years specifically with regard to education, health, the environment, infrastructure, and water.

A document which will be prepared is conceived to be looking at the requirements of Islamabad with 2 million people.

Islamabad’s master plan was prepared by the Greek firm Doxiadis in 1960, which also suggested revising the plan every 20 years.

Successive governments, however, did not make any serious attempt to revise the plan, resulting in a lack of civic planning and haphazard construction.

The CDA has also failed to implement its by-laws beyond the capital’s urban areas, leaving Islamabad`s 32 rural union councils unattended.

These rural areas are now dotted with unauthorized commercial and residential buildings particularly zone III, where the existing master plan does not allow construction.

Prime Minister Imran Khan’s private residence in Banigala is also unauthorized. Under orders from the Supreme Court, the CDA is now moving ahead with fining such construction, including Khan’s home, and then regularizing them following the proper procedure.

Scientists theorize new originated story for Earth’s water

Earth’s water may have originated from both asteroidal material and gas left over from the formation of the Sun, according to new research. The new finding could give scientists important insights about the development of other planets and their potential to support life.

In a new study in the Journal of Geophysical Research: Planets, a journal of the American Geophysical Union, researchers propose a new theory to address the long-standing mystery of where Earth’s water came from and how it got here.

The new study challenges widely-accepted ideas about hydrogen in Earth’s water by suggesting the element partially came from clouds of dust and gas remaining after the Sun’s formation, called the solar nebula.

To identify sources of water on Earth, scientists have searched for sources of hydrogen rather than oxygen, because the latter component of water is much more abundant in the solar system.

Many scientists have historically supported a theory that all of Earth’s water came from asteroids because of similarities between ocean water and water found on asteroids. The ratio of deuterium, a heavier hydrogen isotope, to normal hydrogen serves as a unique chemical signature of water sources. In the case of Earth’s oceans, the deuterium-to-hydrogen ratio is close to what is found in asteroids.

But the ocean may not be telling the entire story of Earth’s hydrogen, according to the study’s authors.

“It’s a bit of a blind spot in the community,” said Steven Desch, a professor of astrophysics in the School of Earth and Space Exploration at Arizona State University in Tempe, Arizona and co-author of the new study, led by Peter Buseck, Regents’ Professor in the School of Earth and Space Exploration and School of Molecular Sciences at Arizona State University. “When people measure the [deuterium-to-hydrogen] ratio in ocean water and they see that it is pretty close to what we see in asteroids, it was always easy to believe it all came from asteroids.”

More recent research suggests hydrogen in Earth’s oceans does not represent hydrogen throughout the entire planet, the study’s authors said. Samples of hydrogen from deep inside the Earth, close to the boundary between the core and mantle, have notably less deuterium, indicating this hydrogen may not have come from asteroids. Noble gases helium and neon, with isotopic signatures inherited from the solar nebula, have also been found in the Earth’s mantle.

In the new study, researchers developed a new theoretical model of Earth’s formation to explain these differences between hydrogen in Earth’s oceans and at the core-mantle boundary as well as the presence of noble gases deep inside the planet.

Modeling Earth’s beginning

According to their new model, several billion years ago, large waterlogged asteroids began developing into planets while the solar nebula still swirled around the Sun. These asteroids, known as planetary embryos, collided and grew rapidly. Eventually, a collision introduced enough energy to melt the surface of the largest embryo into an ocean of magma. This largest embryo would eventually become Earth.

Gases from the solar nebula, including hydrogen and noble gases, were drawn in by the large, magma-covered embryo to form an early atmosphere. Nebular hydrogen, which contains less deuterium and is lighter than asteroidal hydrogen, dissolved into the molten iron of the magma ocean.

Through a process called isotopic fractionation, hydrogen was pulled towards the young Earth’s center. Hydrogen, which is attracted to iron, was delivered to the core by the metal, while much of the heavier isotope, deuterium, remained in the magma which eventually cooled and became the mantle, according to the study’s authors. Impacts from smaller embryos and other objects then continued to add water and overall mass until Earth reached its final size.

This new model would leave Earth with noble gases deep inside its mantle and a lower deuterium-to-hydrogen ratio in its core than in its mantle and oceans.

The authors used the model to estimate how much hydrogen came from each source. They concluded most was asteroidal in origin, but some of Earth’s water did come from the solar nebula.

“For every 100 molecules of Earth’s water, there are one or two coming from solar nebula,” said Jun Wu, assistant research professor in the School of Molecular Sciences and School of Earth and Space Exploration at Arizona State University and lead author of the study.

An insightful model

The study also offers scientists new perspectives about the development of other planets and their potential to support life, the authors said. Earth-like planets in other solar systems may not all have access to asteroids loaded with water. The new study suggests these exoplanets could have obtained water through their system’s own solar nebula.

“This model suggests that the inevitable formation of water would likely occur on any sufficiently large rocky exoplanets in extrasolar systems,” Wu said. “I think this is very exciting.”

Anat Shahar, a geochemist at the Carnegie Institution for Science, who was not involved with the study, noted the hydrogen fractionation factor, which describes how the deuterium-to-hydrogen ratio changes when the element dissolves in iron, is currently unknown and difficult to measure. For the new study, this property of hydrogen had to be estimated.

The new model, which fits in well with current research, could be tested once experiments reveal the hydrogen fractionation factor, Shahar said.

“This paper is a very creative alternative to what is an old problem,” Shahar said. “The authors have done a good job of estimating what these different fractionation factors would be without having the experiments.”

Purple bacteria ‘batteries’ turn sewage into clean energy

on 16/11/2018

You’ve flushed something valuable down the toilet today.

Organic compounds in household sewage and industrial wastewater are a rich potential source of energy, bio-plastics and even proteins for animal feed — but with no efficient extraction method, treatment plants discard them as contaminants. Now researchers have found an environmentally-friendly and cost-effective solution.

Published in Frontiers in Energy Research, their study is the first to show that purple phototrophic bacteria (PPB)– which can store energy from light — when supplied with an electric current can recover near to 100% of carbon from any type of organic waste, while generating hydrogen gas for electricity production.

“One of the most important problems of current wastewater treatment plants is high carbon emissions,” says co-author Dr Daniel Puyol of King Juan Carlos University, Spain. “Our light-based bio-refinery process could provide a means to harvest green energy from wastewater, with zero carbon footprint.”

Purple photosynthetic bacteria

When it comes to photosynthesis, green hogs the limelight. But as chlorophyll retreats from autumn foliage, it leaves behind its yellow, orange and red cousins. In fact, photosynthetic pigments come in all sorts of colors — and all sorts of organisms.

Cue PPB. They capture energy from sunlight using a variety of pigments, which turn them shades of orange, red or brown — as well as purple. But it is the versatility of their metabolism, not their color, which makes them so interesting to scientists.

“Purple phototrophic bacteria make an ideal tool for resource recovery from organic waste, thanks to their highly diverse metabolism,” explains Puyol.

The bacteria can use organic molecules and nitrogen gas — instead of CO2 and H2O — to provide carbon, electrons and nitrogen for photosynthesis. This means that they grow faster than alternative phototrophic bacteria and algae, and can generate hydrogen gas, proteins or a type of biodegradable polyester as byproducts of metabolism.

Tuning metabolic output with electricity

Which metabolic product predominates depends on the bacteria’s environmental conditions — like light intensity, temperature, and the types of organics and nutrients available.

“Our group manipulates these conditions to tune the metabolism of purple bacteria to different applications, depending on the organic waste source and market requirements,” says co-author Professor Abraham Esteve-Núñez of University of Alcalá, Spain.

“But what is unique about our approach is the use of an external electric current to optimize the productive output of purple bacteria.

This concept, known as a “bio-electrochemical system,” works because the diverse metabolic pathways in purple bacteria are connected by a common currency: electrons. For example, a supply of electrons is required for capturing light energy, while turning nitrogen into ammonia releases excess electrons, which must be dissipated. By optimizing electron flow within the bacteria, an electric current — provided via positive and negative electrodes, as in a battery — can delimit these processes and maximize the rate of synthesis.

Maximum biofuel, minimum carbon footprint

In their latest study, the group analyzed the optimum conditions for maximizing hydrogen production by a mixture of PPB species. They also tested the effect of a negative current — that is, electrons supplied by metal electrodes in the growth medium — on the metabolic behavior of the bacteria.

Their first key finding was that the nutrient blend that fed the highest rate of hydrogen production also minimized the production of CO2.

This demonstrates that purple bacteria can be used to recover valuable biofuel from organics typically found in wastewater — malic acid and sodium glutamate — with a low carbon footprint,” reports Esteve-Núñez.

Even more striking were the results using electrodes, which demonstrated for the first time that purple bacteria are capable of using electrons from a negative electrode or “cathode” to capture CO2 via photosynthesis.

“Recordings from our bio-electrochemical system showed a clear interaction between the purple bacteria and the electrodes: negative polarization of the electrode caused a detectable consumption of electrons, associated with a reduction in carbon dioxide production.

“This indicates that the purple bacteria were using electrons from the cathode to capture more carbon from organic compounds via photosynthesis, so less is released as CO2.

Towards bio-electrochemical systems for hydrogen production

According to the authors, this was the first reported use of mixed cultures of purple bacteria in a bio-electrochemical system — and the first demonstration of any photo troph shifting metabolism due to interaction with a cathode.

Capturing excess CO2 produced by purple bacteria could be useful not only for reducing carbon emissions, but also for refining bio-gas from organic waste for use as fuel.

However, Puyol admits that the group’s true goal lies further ahead.

“One of the original aims of the study was to increase bio-hydrogen production by donating electrons from the cathode to purple bacteria metabolism. However, it seems that the PPB bacteria prefer to use these electrons for fixing CO2 instead of creating H2.

We recently obtained funding to pursue this aim with further research, and will work on this for the following years. Stay tuned for more metabolic tuning.”