Saturday, December 17, 2022

SCI FI TECH

Why burning plasma could be the next milestone in nuclear fusion research

Bob McDonald's blog: Researchers hope there are many more fusion milestones to come

Bright blue laser beams converge on a target
The National Ignition Facility at Lawrence Livermore National Laboratory in the U.S. uses 192 lasers focused on a tiny pellet of hydrogen to produce the pressures and temperatures for a fusion reaction. (LLNL)

Many achievements in science are called breakthroughs. The announcement this week that scientists at the National Ignition Facility (NIF) of Lawrence Livermore Laboratory in the U.S. achieved a breakthrough nuclear fusion reaction, literally was one.

It was a major step forward in fusion research. The next step is to keep the reaction going longer.

"Breakthrough" is the term used in fusion science for the point at which the energy produced from a fusion reaction was more than the energy needed to run it. However, the NIF's technique of using 192 laser beams to implode a tiny nuclear fuel pellet for a fraction of a second, like an enormous flashbulb, is not likely the method that will be used to generate clean energy in the future.

This isn't surprising, really, as the NIF facility wasn't designed to test energy generation. Its primary function is to do research related to thermonuclear weapons and materials.

The lab can only generate one of its laser-driven fusion flashes every few days or so. If we want to generate electricity, we need the equivalent of a spotlight that shines constantly which requires a different technology called magnetic confinement using a design known as a tokamak

Curved metal walls with various protrusions on them
The inside of the training mock-up of the Joint European Torus (JET) is seen at the UK Atomic Energy Authority in Abingdon, England. (Photo by Leon Neal/Getty Images)

Think of a large circular chamber shaped like a hollow doughnut. Around the outside of the chamber are a set of incredibly powerful superconducting electromagnets that create what is referred to as a magnetic bottle, a ring-shaped magnetic field inside the doughnut.

The next ingredient is hydrogen gas — actually deuterium or tritium, which are hydrogen atoms with extra neutrons. This is heated to the point where its electrons are stripped away and it becomes an electrically charged plasma, which is then injected into the magnetic bottle.

The plasma is then further heated to 150 million degrees C until fusion occurs. Because the plasma is confined by the magnetic fields, it doesn't melt the walls of the chamber.

The concept is to start a fusion reaction then keep it going continuously as a self-sustaining burning plasma so the energy can be used to generate electricity. Burning plasmas have been created in tokamaks such as the Joint European Torus in England. It set a world record in 2021 by creating a fusion reaction that lasted five seconds — but it still took more energy to heat the plasma and drive the fusion reaction than the actual fusion process produced. The fusion fire wouldn't stay lit without external help.

The next step for fusion research lies in Southern France, where the world's largest tokamak is currently under construction. The International Thermonuclear Experimental Reactor, or ITER, is expected to go beyond the break-even point and produce 10 times more energy than it takes to run it.

ITER will be a research reactor that is designed to study the nature of plasmas, how to keep them burning for extended periods of time and study the effects of the reaction on materials used in the walls of the chamber to ensure future fusion reactors — ones that will actually be designed to produce electricity — will operate properly.

ITER's first plasma was scheduled for 2025, but construction and manufacturing delays, as well as the COVID-19 pandemic, have created concern that the deadline will slip. 

Inside the Tokamak Building during the launch of the assembly stage of the International Thermonuclear Experimental Reactor (ITER) in Saint-Paul-les-Durance, southeastern France, on July 28, 2020. (CLEMENT MAHOUDEAU/AFP via Getty Images)

All the apparatus of lasers and magnetic bottles is necessary because atomic nuclei do not easily fuse together unless they are under extreme conditions. The sun does it through its immense mass that produces extreme pressures and temperatures at its core that force hydrogen nuclei to fuse into helium, giving it the energy to shine brightly. Here on Earth those conditions are extremely difficult to duplicate. 

Squeezing a plasma into a confined space and maintaining it at a temperature 10 times hotter than the centre of the sun has been compared to trying to hold onto hot Jell-O with a rubber band. 

ITER the leading candidate for a fusion energy system, but it's not the only one. In the U.S., a tokamak called SPARC, under development, at MIT is expected to achieve the same results on a smaller scale thanks to advances in electromagnet technology. And several private companies have arisen with their own systems and plans, including Vancouver-based General Fusion who plan to contain their fusion reaction in pressurized molten lead.

The ultimate goal is to capture the energy from burning plasmas and turn it into emissions-free electricity without the volume of nuclear waste products that fission reactors produce. Some of the electricity from the reactor will be cycled back to power the electromagnets that contain the plasma so the entire reaction becomes self-sustaining — a miniature star here on Earth.

If ITER or SPARC, or one of the private projects are successful, commercial fusion reactors are hoped to be in operation sometime in the 2030's. But fusion research timelines have been difficult to keep in the past because the task is so difficult.

Meanwhile, the timeline for disastrous climate change is also drawing close. This does invite the question, will fusion power be ready in time to really make a difference?

Fusion energy: What does the recent breakthrough by scientists in California mean?

The announcement earlier this week that researchers had successfully created more energy from nuclear fusion than the laser energy used to drive it seemed significant - so what good is it, anyway? Dr Pádraig MacCárthaigh of UCC explains

Nuclear fusion is the process by which hydrogen and other light nuclei fuse together to form a larger daughter nucleus whose mass is slightly less than the sum of the parent nuclei masses. This “missing mass”, M, appears in the form of a large release of kinetic energy, ie energy of motion, via Einstein’s equation E = Mc2 where c is the speed of light. 

Fusion is the energy source that powers all stars, including our Sun, and hence is essential for sustaining life on Earth.

Energy-producing fusion reactions are predicted under very specific conditions on Earth, and since 1958, when earlier defense-related research carried out in the US, the USSR and the UK was declassified, the peaceful use of fusion power has been a long-term research topic in many countries, including Ireland where links with major European laboratories were established from the 1970s onwards, notably by the former Head of Department of Electrical Engineering at UCC, Professor Michael Sexton. 

The ultimate goal of this research is to construct fusion reactors that would provide electric generation capacity to ensure a stable supply in a post-fossil fuel world where most power will be generated by inherently volatile renewable energy sources.

Safer

The splitting of very heavy nuclei, such as uranium, which is far easier to achieve than fusion, also releases energy, and this is the basis for conventional nuclear fission reactors with their attendant issues of reactor safety and long-lived, highly concentrated radioactive waste products. A fusion reactor, by contrast, would have no similar safety concerns and relatively little waste generation. 

The consequences of a loss of control over a fission reactor, as happened at Chernobyl in 1986 and Fukushima in 2011, are disastrous. A loss of control in a fusion reactor, far from leading to meltdown and/or a nuclear explosion, would merely cause the reactions to quench abruptly, with the only consequence being a temporary loss of power generation capacity.

In the quest for fusion-based electric power generation, the most easily achieved fusion reaction, involving two heavy hydrogen isotopes, deuterium (D) and tritium (T), produces no immediate radioactive waste. Most of the fusion energy is carried by energetic neutrons, however, and these induce a low level of radioactivity over time in the surrounding structures, but it is far less concentrated than fission waste products, and decays on far shorter timescales (a hundred years versus many tens of thousands of years).

Fusion research

There are two major lines of research in fusion energy, one involving the use of strong magnetic fields to confine charged hydrogen gas nuclei and freely roaming electrons at extreme temperatures long enough for the nulcei to collide and fuse. This is termed Magnetic Confinement Fusion (MCF) and is considered to be the most likely path to a functioning fusion energy plant.

In the other main line of research, a large number of high-power lasers ‘zap’ a frozen spherical pellet of deuterium and tritium causing the surface layer of the pellet to explosively disintegrate outwards. 

The recoil from the surface layer explosion causes the cold interior of the pellet to collapse in on itself, causing its density to rise to hundreds of times that of ordinary matter, and the associated kinetic energy causes the imploding material to reach extreme temperatures of a hundred million degrees celsius. 

Under these extreme conditions, fusion reactions occur spontaneously on an extremely short timescale of a picosecond, or one million-millionth of a second. The very brief time it takes for the rapid inward motion of the pellet matter to stop and reverse direction gives this line of research its name: Inertial Confinement Fusion (ICF).

Finally, the enormous mass of the Sun and stars enables fusion energy generation by gravitational confinement, a mechanism which is not available to laboratory researchers.

Since 1958, fusion energy research has focused on trying to demonstrate that a net energy-producing fusion reaction on Earth is possible in practice. Initial results were far from promising, with output fusion energy around 0.01% of input energy. 

Advances since then have progressed slowly but steadily, culminating in the achievement of 60% output fusion energy for several seconds in 1997 at the Joint European Torus, the largest operating MCF fusion experiment in the world, which is located outside Oxford and to which a number of Irish scientists and engineers have made significant contributions.

'Break even'

Further progress in achieving ‘break even’, where fusion energy output equals or exceeds the input energy has been slow in the intervening period. That is, until the recent ground-breaking announcement by the National Ignition Facility (NIF) at California’s Lawrence Livermore Laboratory, the globally leading centre for ICF research, that a fusion reaction in the laboratory generated excess fusion energy for the first time. 

Slightly over two megajoules (MJ) of energy were absorbed by the pellet (an admittedly small fraction of the 300 MJ required to fire the 192 lasers that were directed into a small, hollow gold cylinder containing the pellet) and more than 3 MJ were detected from the fusion reactions that followed the pellet implosion, so that the fusion reactions generated 50% more energy than was absorbed by the pellet.

From an engineering perspective, the energy efficency was a mere 1% (3 MJ output for 302 MJ input), but this is to miss the true significance of this major scientific breakthrough.  

The recent breakthrough on nuclear fusion at the Lawrence Livermore National Laboratory in Livermore, California, could be compared to the demonstration of the first electric motor by the great English experimental physicist Michael Faraday in 1821. Picture: Damien Jemison / Lawrence Livermore National Laboratory via AP
The recent breakthrough on nuclear fusion at the Lawrence Livermore National Laboratory in Livermore, California, could be compared to the demonstration of the first electric motor by the great English experimental physicist Michael Faraday in 1821. Picture: Damien Jemison / Lawrence Livermore National Laboratory via AP

It could be compared to the demonstration of the first electric motor by the great English experimental physicist Michael Faraday in 1821. When asked by a politician “What good is it?”, Faraday reputedly replied “What good is a new-born baby?” (A more cynical version of this anecdote goes “Soon you will be able to tax it”)

Enormous decades-long challenges still face both MCF and ICF research before the prospect of a fusion power plant is realised, if ever. Of the two constituents of the D-T (deuterium-tritium) reaction, deuterium is plentifully available in the form of heavy water which can be easily extracted from sea water. 

Tritium, however, is not naturally occurring and must be obtained via transmutation of lithium by capturing the neutrons released in the D-T reaction in a so-called lithium blanket which will surround the reactor. Pertinent experimental tests of this process have yet to be carried out, and it remains to be seen how much of the isotope of lithium is available for tritium breeding. 

Other, more ambitious approaches to fusion energy production include a reaction involving hydrogen and boron which does not emit neutrons, a distinct advantage over D-T. Another plus is that its plentiful reserves in the Earth’s crust are estimated to be sufficient to power the planet for 3,000 years. The caveat is that boronic fusion is much more difficult to achieve than D-T fusion.

In summary, the breakthrough at NIF is a landmark advance in the pursuit of the holy grail of a safe, clean and reliable carbon-free source of power generation. It can’t come soon enough to slow down, and ultimately arrest, the ominous and accelerating rate of climate change caused by carbon emissions that result from the unabated consumption of fossil fuels.


  • Dr Pádraig McCárthaigh has been active in fusion energy research in the Department (now School) of Physics, UCC, since the early 1990s and has a long-term involvement with the Max Planck Institute for Plasma Physics in Munich.




Will nuclear fusion be the clean energy of 

our future?

US Department of Energy officials have announced that scientists have made a historic breakthrough.

US Department of Energy (DoE) officials recently announced that US researchers had achieved a milestone breakthrough in nuclear fusion, having for the first time produced more energy than was used to power the experiment.
Scientists were able to use fusion to produce more energy than was used to power the lasers they used.

The nuclear fusion net energy gain is considered to be a major milestone in energy science and in the attempt to develop a source of limitless, clean energy. The process occurs when two or more atoms are fused together. While this has already been achieved by researchers, what is novel about the latest development is that they were able to fuse the atoms using less energy than was produced.

The experiment required a massive 2.05 megajoules of energy to power lasers aimed at the target, but the result was 3.15 megajoules of energy output. This meant that they were able to generate 50 percent more energy than they used to power the reaction. This is a meaningful energy gain.

“This monumental scientific breakthrough is a milestone for the future of clean energy,” said a statement from US Senator Alex Padilla (D-CA).

The nuclear fusion achievement was made by Lawrence Livermore National Laboratory scientists.

The research team were from the Lawrence Livermore National Laboratory’s National Ignition Facility in California. The achievement was made on December 5, 2022 and announced this week. The facility used is about the size of a sports stadium, and the team used 192 very high-powered lasers to produce the reaction.

The breakthrough was a “milestone,” said Energy Secretary Jennifer Granholm. “Ignition allows us to replicate, for the first time, certain conditions that are only found in the stars and sun,” she said. “This milestone moves us one significant step closer to the possibility of zero-carbon, abundant fusion energy powering our society.”

According to Granholm, the Livermore scientists and other labs are moving the US forward in an effort to achieve clean energy without the requirement for nuclear testing as a nuclear deterrent.

“This is what it looks like for America to lead, and we’re just getting started,” explained Granholm. “If we can advance fusion energy, we could use it to produce clean electricity, transportation fuels, power, heavy industry and so much more.”

That said, it’s important to recognize that this is only the very earliest step in nuclear fusion as an energy source. It is a critical step but doesn’t mean that it will be available in the short term. Progress with renewable power and hydrogen fuel, among other sources of clean energy, remain critical even if the future of clean, sustainable energy is nuclear fusion.

The director of Lawrence Livermore National Laboratory Kim Budil called the breakthrough a “fundamental building block” to one day using this technology as a form of powering electricity. That said, in her estimations, “a few decades” of work are still needed before it will be available for commercial use.

“I think it’s moving into the foreground and probably with concerted effort and investment, a few decades of research on the underlying technologies could put us in a position to build a power plant,” said Budil. “With real investment and real focus, that timescale can move closer.”

Fusion Explained: Why the Big, New Milestone Doesn't Mean Green Power -- Yet

Get up to speed on this potentially revolutionary power source.


Stephen Shankland
Dec. 16, 2022

A technician adjusts an optic inside the preamplifier support structure at Lawrence Livermore's National Ignition Facility.

Lawrence Livermore National Laboratory/Damien Jemison

Scientists at Lawrence Livermore National Laboratory passed a major fusion milestone in December, igniting a fusion reaction that for a fleeting moment produced more energy than was used to trigger it.

The achievement is the high-water mark for fusion research, a field that produced thermonuclear weapons more than 70 years ago but still no reactor that could generate electrical power. The scientific and engineering challenges of controlled fusion are formidable.

But what does the experiment at LLNL's National Ignition Facility, aka NIF, mean for science and for the dream of a new energy source that'll power our homes and cars without releasing any of the carbon dioxide?

In short, it's a big deal and fine to applaud, but it doesn't mean a green energy revolution is imminent. It'll still be years before fusion power progress bears fruit — likely a decade or so — and it's still not clear if fusion will ever be cheap enough to radically transform our power grid. Continuing today's investments in solar and wind is critical to combating climate change. Here's a look at what's happened and what's still to come.

What is fusion?



The National Ignition Facility uses infrared and ultraviolet laser light to produce X-rays in a chamber with a peppercorn-sized fusion fuel pellet.Lawrence Livermore National Laboratory

Fusion occurs when two lighter elements like hydrogen or helium merge into a single, heavier element. This nuclear reaction releases a lot of energy, as exhibited by the biggest fusion furnace around, the sun.

It's harder to get fusion to occur on Earth, though, because atomic nuclei are positively charged and therefore repel each other. The sun's enormous mass produces tremendous pressure that overcomes that repulsion, but on Earth, other forces are required.

There are two general approaches to fusion: inertial and magnetic confinement. Inertial confinement usually uses lasers to zap a pellet with a lot of power, triggering an explosion that compresses the fusion fuel. That's the method NIF uses.

The other approach uses magnetic fields. It's more widespread among companies trying to commercialize fusion energy.

What did the experiment at NIF accomplish?

It crossed a critical threshold for fusion where the energy that the fusion reaction generated — 3.15 million joules — exceeded the 2.05 megajoules the lasers pumped out to trigger the reaction. Fusion researchers denote the ratio of output energy to input energy with the letter Q, and this is the first time a fusion reaction surpassed Q = 1.

Fusion reactors will have to reach a threshold of Q = 10 before energy generation is practical. That's what everybody is aiming for, including another massive government-funded project called ITER in France. And fusion reactors will have to reach Q = 10 much more frequently than NIF can.

In some ways, it's an academic milestone, one fusion experiments have nudged toward for decades. But given fusion's reputation for not ever getting there, it's an important proof of what's possible. Think a little bit more carefully before you repeat that oft-quoted snarky remark that fusion is the energy source of the future and always will be.
What does the NIF experiment mean for green power?

Not a huge amount, for a few reasons. For one thing, most commercial fusion energy projects are using various forms of magnetic confinement, not NIF's laser-based approach, so the engineering challenges are different. For another, NIF is a gargantuan, $3.5 billion national lab project funded to research nuclear weapons, not a project designed to produce reliable energy for the grid at the most competitive cost.

"Don't expect future fusion plants to look anything like NIF," said Princeton physicist Wilson Ricks in a tweet. Huge inefficiencies in NIF's lasers and in the conversion of fusion heat to electrical power mean its design is inherently impractical. In comparison, "magnetic confinement fusion holds some real promise," he tweeted.

Lowering fusion's cost is critical to its success since it'll have to compete against zero-carbon alternatives like today's fission-based nuclear reactors that can generate a steady supply of power and renewables like wind and solar that are cheaper but intermittent.

"Fusion's first competitor is fission," Ricks and other researchers at the Princeton Plasma Physics Laboratory concluded in an October research paper, not yet peer reviewed, that assesses fusion's prospects on the electrical grid. They expect that if fusion's high costs can come down enough, it could replace the need for future fission plants, and if lowered further, could compete against the combination of solar and energy storage.

NIF is a big, complicated site. If fusion power plants can be built in cheaper, smaller units that are more like something coming off a factory line, production costs should decrease. That's thanks to a phenomenon called Wright's Law, the experience curve or the learning curve, which has steadily lowered costs for solar and wind. The bigger and more customized a fusion plant is, the less costs will drop and the less competitive fusion will be.

Are there at least some less direct benefits from NIF's results?

Yes. Scientists could benefit somewhat from the NIF experiment by updating fusion physics models to account for the fact that it's supplying its own heat instead of relying on external sources, said Andrew Holland, chief executive of the Fusion Industry Association, an advocacy group for the industry.

And the attention could help, too, especially given longrunning skepticism about fusion energy.

TAE Technologies CEO Michl Binderbauer called NIF's result "a huge stepping stone into the dawn of the fusion age," and said it's an important illustration that fusion energy really is plausible.

Investors have noticed, too. Downloads of the Fusion Industry Association's annual report, which details the $4.8 billion in venture capital investments in fusion energy startups, increased tenfold since the NIF achievement was announced, Holland said. Many of those requesting it are from investment firms, he added.
How does fusion work at NIF?

NIF triggers fusion using 192 powerful infrared lasers with a combined energy level of 4 megajoules — about the same as a two-ton truck traveling at 100mph. That's converted first into 2 megajoules of ultraviolet light, then into X-rays that strike a peppercorn sized pellet of fusion fuel.

The intense X-rays cause the outer layer of the pellet to blow off explosively, compressing the pellet interior and triggering fusion. The heat from that fusion sustains the reaction until it runs out of fuel or becomes lopsided and falters.


The National Ignition Facility at Lawrence Livermore National Laboratory is the size of three football fields.
Lawrence Livermore National Laboratory

Nuclei? Hydrogen? Catch me up on atomic physics, please

Sure! Here's a quick refresher.

Everything on Earth is made of tiny atoms, each consisting of a central nucleus and a cloud of negatively charged electrons. The nucleus is made of neutrons and positively charged protons. The more protons in the nucleus, the heavier the element is.

Hydrogen usually has one proton and one electron. An unusual variety called deuterium has a neutron, too, and using nuclear reactors or fusion reactors, you can make a third variety called tritium with two neutrons.

Chemical reactions, like iron rusting or wood burning, occur when those positive and electrical charges cause atoms to interact. In comparison, nuclear reactions occur when the nuclei of atoms split apart or join together. Here on Earth, it's harder to marshal the required forces to get nuclear reactions to take place, which is why it's easier to make a steam engine than a nuclear bomb.

When you heat atoms up enough, they get so energetic that the electrons are stripped loose. The resulting cloud of negatively charged electrons and positively charged nuclei is called a plasma, a more exotic state of matter than the solids, liquids and gases that we're used to at room temperature here on Earth.

The sun is made of plasma, and fusion reactors need it, too, to get those hydrogen nuclei to bounce around energetically enough. A convenient property of plasmas is that their electrically charged particles can be manipulated with magnetic fields. That's crucial to many fusion reactor designs.
What do you use for fusion fuel?

NIF and most other fusion projects use the two heavy versions of hydrogen, deuterium and tritium, called DT fuel. But there are other options, including hydrogen-boron and deuterium-helium-3, a form of helium with only one neutron instead of the more common two.

To get deuterium and tritium to fuse, you need to heat a plasma up to a whopping temperature of about 100 million degrees Celsius (180 million degrees Fahrenheit). Other reactions are even higher, for example about a billion degrees for hydrogen-boron fusion.

Deuterium can be filtered out of ordinary water, but tritium, which decays away radioactively over a few years, is harder to come by. It can be manufactured in nuclear reactors and, in principle, in future fusion reactors, too. Managing tritium is complex, though, because it's used to boost nuclear weapon explosions and thus is carefully controlled.

How do you turn that fusion reaction into power?

The deuterium-tritium fusion reaction produces fast-moving solo neutrons. Their kinetic energy can be captured in a "blanket" of liquid that surrounds the fusion reactor chamber and heats up as the neutrons collide.

That heat is then transferred to water that boils and powers conventional steam turbines. That technology is well understood, but nobody has yet connected it to a fusion reactor. Indeed the first generation of fusion power reactors being built today are designed to exceed Q=1, but not to capture power. That'll wait for the pilot plants that are expected to arrive in the next wave of development.
How is fusion different from fission?

Fission, which powers today's nuclear reactors, is the opposite of fusion. In fission, heavy elements like uranium split apart into lighter elements, releasing energy in the process.

Humans have been able to achieve fusion for decades with thermonuclear weapons. These designs slam material like uranium or plutonium together to trigger a fission explosion, and that provides the tremendous energy needed to initiate the secondary and more powerful fusion reaction.

In bombs, the process occurs in a fraction of a second, but for energy production, fusion must be controlled and sustained.

Do fusion reactors create radioactive waste?


Yes, generally, but it's not nearly as troublesome as with fission reactors. For one thing, most of the radioactive emissions are short-lived alpha particles — helium nuclei with a pair of protons and a pair of neutrons — that are easily blocked. The fast-moving neutrons can collide with other materials and create other radioactive materials.

Fusion reactors' neutron output generally will degrade components, requiring periodic replacement that could require downtime lasting perhaps a few months every few years. It's vastly easier to handle than the high-level nuclear waste of fission power plants, though.

Hydrogen-boron fusion is harder to achieve than deuterium-tritium fusion, but part of its appeal is that it doesn't produce any neutrons and attendant radioactive materials. The most prominent company pursuing this approach is TAE Technologies.
What are the safety risks of fusion power?

Fusion power plants don't have the meltdown risks that have caused problems with fission reactors like the Fukushima and Chernobyl sites. When a fusion reaction goes awry, it just fizzles out.

But there still are significant operational issues that you'll see at major industrial sites, including a lot of electrical power and high-pressure steam. In other words, the big problems are more like those you'd find at an industrial site than at one of today's fission nuclear power plants.

So there are real advantages to fusion. NIF helps show that there's a future for fusion energy. But there's still a very long way to go.
ZIONIST PATERNALISM
Netanyahu says he may offer Palestinians self-rule but no sovereignty

Prime Minister-designate defends far-right parties which will join his coalition government

Abdelraouf Arna'out |16.12.2022


JERUSALEM

Israeli Prime Minister-designate Benjamin Netanyahu said the peace he plans to seek with Palestinians would offer them powers to rule themselves, with security matters in the hands of Israel.

"The only peace that will hold is one that we can defend," Netanyahu said on Thursday in an interview with the US' National Public Radio.

"Palestinians have all the powers to govern themselves, but none of the powers to threaten our life, which means that security, in whatever political arrangements we'll have, realistically will have to remain in Israel's hands," he added.

As prime minister at the time, Netanyahu recounted that in a 2014 visit, then-US Vice President Joe Biden told him that such an offer would not give the Palestinians "complete sovereignty."

He replied: "You're right, Joe, but that's the only one that will last."

Peace negotiations between the Palestinians and Israelis collapsed in April 2014 as Tel Aviv refused to stop settlement building and release Palestinian detainees imprisoned before 1993.

On the issue of the government he plans to form, Netanyahu defended the far-right parties that are expected to be part of his administration after their support carried him to victory in last month's elections.

For Itamar Ben-Gvir, head of far-right Jewish Strength party, Netanyahu said he had "modified" many of his views in recent years.

Palestinians warn of that Netanyahu's government will one of the most radical in recent Israeli history, expanding settlement construction across the occupied West Bank and allowing violations of the Al-Aqsa Mosque in occupied East Jerusalem.

* Writing by Ahmed Asmar
IDF soldiers shot at Israelis after mistaking them for Palestinian rioters

The incident, which was in violation of the IDF's open-fire rules of engagement, is being investigated by the Israeli military.

By JERUSALEM POST STAFF
Updated: DECEMBER 17, 2022 

Israeli soldiers guard in a bus station at the entrance to the Israeli settlement of Ofra, where a Palestinian man tried to ram Israeli security forces who stopped him for inspection, October 4, 2022.
(photo credit: FLASH90)

IDF soldiers shot at security officials from the West Bank settlement of Ofra earlier this week after mistaking them for Palestinian rock throwers, the Israeli military confirmed following a KAN News report on Friday night.

The soldiers reportedly received a report of Palestinians hurling stones at oncoming Israeli vehicles on Highway 60. After arriving at the scene, one soldier located two individuals standing on the side of the road.

The soldier, who assumed the two were Palestinian rioters, asked permission to open fire but received no response, according to the report, and opened fire after a number of minutes. The soldier's commander also approached the two and fired a number of shots into the air.

Is there more to Iran's 'strategic' decision to enrich uranium?

After clarification, it was revealed that the two people were in fact security officials from the West Bank settlement.

IDF SOLDIERS operate in Hebron, this week: Israel must ensure that the West Bank is not militarized over the long term with its own forces, says the writer 
(credit: WISAM HASHLAMOUN/FLASH90)

Ofra incident investigated by IDF's Central Command

The incident, which was in violation of the IDF's open-fire rules of engagement, is being investigated by the Israeli military's Central Command, it said in response to KAN's report. Fortunately, no injuries were reported.

Ofra has been the target of a number of planned attacks by Palestinian gunmen in the past two weeks. Earlier in December, shots were fired at an IDF post near the settlement and, in a separate incident, at a bus carrying Israelis near the settlement.

A Palestinian terrorist also fired at an IDF outpost in the area last week and was killed by Israeli forces who returned fire.

Nineteen Palestinians, including children, were shot and killed by Israeli soldiers since November 22 - UN

JERUSALEM, Saturday, December 17, 2022 (WAFA) – Israeli soldiers shot and killed 19 Palestinians, including three children, in different incidents in the occupied territories between November 22 and December 11, making 2022 the deadliest year for Palestinians in the West Bank since 2005, according to the biweekly report on the protection of civilians published by the United Nations Office for the Coordination of Humanitarian Affairs (OCHA) in the occupied Palestinian territory.

It said that a 16-year-old Palestinian boy was killed on November 22 after Israeli settlers broke into Joseph’s Tomb site in Nablus City. Another child, 16, was killed near Aboud village, northwest of Ramallah, on December 8, and a 15-year-old girl, was killed in Jenin on December 11.

Meanwhile, on 29 November, two Palestinian brothers were killed by live ammunition in Kafr Ein village near Ramallah and on 2 December a Palestinian man was killed in cold blood by an Israeli Border Police officer in Huwwara town, south of Nablus. One Palestinian has also died of wounds sustained earlier. The others were killed during clashes, some of them innocent bystanders, or in attacks.

According to the Palestinian Ministry of Health, Israel killed 166 Palestinians since the start of the year (11 of them killed since the start of December), including 39 children and eight females (three children under 18 years, one 68 years, another 51 years, and three 45, 31 and 24 years of age).

Israeli forces also set up closures around one town and blocked the main entrances of four villages, disrupting access of thousands of Palestinians to livelihoods and services during the reporting period from November 22 through December 5, said OCHA.

During this period, added the OCHA report, the Israeli authorities demolished, confiscated, or forced people to demolish 58 structures, including 10 residential homes and one school, for lacking Israeli-issued building permits. Five of the structures were provided by donors as humanitarian assistance. As a result, 47 Palestinians, including 27 children, were displaced, and the livelihoods of more than 160 others were affected.

It said that 56 of the targeted structures were in Area C, including five structures demolished based on Military Order 1797, which provides only a 96-hour notice and very limited grounds for legally challenging a demolition. In addition, two structures were demolished by their owners in East Jerusalem to avoid the payment of fines to the Israeli authorities.

One donor-funded school was demolished, and another had a demolition order issued against it in Hebron, said OCHA. On 23 November, the Israeli authorities demolished Isfey al-Faqua donor-funded school, which served 21 students from three communities in southern Hebron. Isfey al-Fauqa is one of 13 herding communities comprising about 1,150 people, half of whom are children, in an area designated by the Israeli authorities as ‘Firing Zone 918’ in Masafer Yatta. On 29 November, the Israeli authorities issued a demolition order, with a 96-hour notice, against another donor-funded school in Khashem al Karem (Hebron). On 1 December, legal aid partners secured a court injunction against the demolition, which is valid for 21 days as long as no additional construction takes place at the school during this period.

M.K.

Newspapers Review: Dozens of injuries due to Israeli army crackdown on Palestinian protests focus of dailies

RAMALLAH, Saturday, December 17, 2022 (WAFA) – Dozens of Palestinians were injured yesterday in the Israeli army crackdown on the weekly Friday protests in the occupied territories against the occupation and its settlement enterprise, said the three Palestinian Arabic dailies published today in their main front-page story.

Al-Hayat al-Jadida daily said one person was shot by a live bullet while others were either hit by rubber-coated metal bullets or suffocated from tear gas fired by the soldiers.

Al-Quds daily said settlers, under army protection, opened a road through Palestinian-owned land in the town of Dura in the south of the West Bank to serve their expansionist policies.

The third daily, al-Ayyam, said Palestinians confronted wide-scale settler intrusions on their properties.

It also said that Israeli soldiers forced Palestinians to remove their clothes when passing through a checkpoint in Tel Rumeida neighborhood in the occupied part of the southern West Bank city of Hebron.

The three dailies said the Israeli army turned over yesterday the remains of two young Palestinians its forces killed in cold blood near Ramallah on October 3 and has been holding ever since. In that incident, soldiers opened fire at a car near Jalazon refugee camp without any reason killing two and injuring a third, who was treated at a hospital in Ramallah. The two will be buried today in their hometowns of Birzeit and nearby Jifna.

Al-Quds said the United Nations recognized the right of the Palestinian people to self-determination with 168 members voting in favor of this resolution, six opposed and eight abstained.

Al-Hayat al-Jadida said UN experts have condemned the rise in settler violence and the Israeli army’s excessive use of force against the Palestinian civilians in the occupied territories.

Al-Ayyam said an Israeli settler official has called on the army to wage a military attack on Nablus.

The three dailies also highlighted on their front page the recent protests in Jordan against the rise in prices of fuel with al-Ayyam saying a security man was killed in the protests and two others were injured, while al-Quds said the Jordanian monarch said his government will take strong action against those who use weapons.

The dailies also reported on the developments in the formation of the Israeli government and said the Israeli parliament has approved in first reading law in favor of Smotrich and Deri, who is accused of corruption.

They also highlighted developments in the war in Ukraine.

M.K.

Africa faces its biggest food crisis yet

One in five Africans, a record 278 million people, was already facing hunger in 2021, according to data from the UN  Food and Agriculture Organisation (FAO). It says the situation has worsened.
Friday 16/12/2022
Young girls pull containers of water as they return to their huts from a well in the village of Lomoputh in northern Kenya, May 12, 2022. (AP)
Young girls pull containers of water as they return to their huts from a well in the village of Lomoputh in northern Kenya, May 12, 2022. (AP)

MOGADISHU-

In October, Nadifa Abdi Isak brought her malnourished daughters to hospital in Mogadishu. That day, a nurse said, 42 other children had already been checked into the emergency unit, ravaged by hunger. There were 57 the day before that.

Staff at the Benadir maternity and paediatric hospital said admissions of malnourished children have more than doubled their patient numbers over the past year. They are now treating over 1,000 emergency cases each month.

Half a million children's lives are at risk from a looming famine in Somalia, according to the United Nations which says this more than in any country worldwide this century.

Across Africa, from east to west, people are experiencing a food crisis that is bigger and more complex than the continent has ever seen, say diplomats and humanitarian workers.

One in five Africans, a record 278 million people, was already facing hunger in 2021, according to data from the UN  Food and Agriculture Organisation (FAO). It says the situation has worsened.

The number of East Africans experiencing acute food insecurity, when a lack of food puts lives or livelihoods in immediate danger,  has spiked by 60% in just the last year and by nearly 40% in West Africa, according to the World Food Programme (WFP).

Conflict and climate change are the long-term causes. Heavy debt burdens following the COVID-19 pandemic, rising prices and war in Ukraine have made things much worse as European aid has been sucked away, data and testimony from more than a dozen experts, donors, diplomats, medical staff and men and women in farms and marketplaces across nearly a dozen countries in Africa and beyond show.

Benadir Hospital is coping, said Dr Aweis Olow, head of its paediatric department. But referrals from other clinics are accelerating: "Without a lot of help from the rest of the world, the situation will be out of control."

There are five reasons Africa is suffering from the worst food crisis ever recorded.

Climate change

East Africa has missed four consecutive rainy seasons, the worst drought in 40 years, said Michael Dunford, the WFP's East Africa director.

"The situation has never been as bad from a regional perspective as it is today," he told Reuters.

African countries account for only around three percent of the global emissions deemed responsible for climate change, but suffer more than any other region from its impact.

Of the 20 nations ranked as most vulnerable to climate change, all but four are African, according to the Notre Dame Global Adaptation Index, which measures countries' vulnerability.

Some 22 million people across Ethiopia, Kenya and Somalia face high levels of acute food insecurity due solely to the drought, a number projected to rise to up to 26 million by February if the rains again fail, the WFP said.

The lack of rainfall has caused crops to fail. In northern Kenya, pastoralists dig deeper and deeper in search of water for their livestock.

Traditional Maasai herders, whose culture revolves around their cows, face the choice of selling them or watching them die.

On the other side of the continent, parts of West Africa have been hit by flooding after the most intense rainfall in 30 years. By mid-October, five million people and one million hectares of farmland were affected, according to the WFP.

In Chad, over 19,000 head of livestock were swept away after rivers broke their banks, while in neighbouring Nigeria, flooding has hit 29 of the 36 states.

In October in Benue state, part of Nigeria's agricultural heartland, farmer Abraham Hon looked out over water stretching to the horizon, covering some 20 hectares of his ruined rice fields.

"You have drought in some places, then you have floods in some places," he said. "That is a real shift."

"SAVING OUR CHILDREN"

Isak's hometown, Dinsoor, is about 370 kilometres from the capital in Somalia's Bay region. In June, she and her husband and children set out on foot, hoping to escape drought. The journey to Mogadishu took 12 days. They brought their savings of around $15 and some milk and food.

They walked. "We fled in the hope of saving our children," she said, seated on a hospital bed with her two girls, Nasib, four and Fardawsa, three and an infant on her back.

A day into the journey, they were ambushed by bandits. The robbers took their money and food, but spared their lives. They kept walking. A stranger gave the children a lift on his donkey cart.

After four days they reached the regional capital, Baidoa, but could not find help there. Someone gave them a lift to Mogadishu. There, they found a spot on government land and built a shelter with other displaced people.

Mohamud Abdi Ahmed, an official for the Garasbaley district where the family set up camp, said there were 50,000 displaced families there.

"Sometimes it's difficult to count them, because more arrive every minute."

Food supplies are distributed during a visit by World Food Programme (WFP) Regional Director Michael Dunford to a camp for the internally-displaced in Adadle, in the Somali Region of Ethiopia, January 22, 2022. (AP)
Food supplies are distributed during a visit by World Food Programme (WFP) Regional Director Michael Dunford to a camp for the internally-displaced in Adadle, in the Somali Region of Ethiopia, January 22, 2022. (AP)

Conflicts 

Conflict has long been a driver of hunger. War forces civilians from their homes, livelihoods, farms and food sources. It also makes it dangerous to deliver assistance.

The number of displaced people in Africa has tripled over the past decade to a record 36 million in 2022, according to UN  data. That represents almost half the displaced people in the world. Most were displaced internally within their own countries by conflict.

Conflicts are worsening across the continent, according to the Armed Conflict Location & Event Data Project (ACLED), a crisis monitoring group.

In 2016, it recorded 3,682 "battles" between armed groups in Africa. There were 7,418 in 2021.

Isak's country, Somalia, has been unstable since a civil war in the early 1990s and today is a patchwork of clan strongholds, government-controlled areas and zones in the grip of al Shabaab, an al Qaeda-linked militant group fighting to impose its own rule based on a strict interpretation of Islamic Sharia law.

A US non-profit, Fund for Peace, ranks global states by how fragile they are. In 2022, 15 African nations occupied the top 20 slots of its rankings.

Whenever Isak had food, her youngest children were given top priority.

"The children were getting weaker for months," she said. She and other mothers say malnourished children swell up and their skin thins. They bruise easily.

Just a week after the family arrived in Mogadishu in June, two of Isak's daughters, six year-old Muna and  seven year-old Hamdi, fell ill one after another.

They were weak and ran fevers, their legs bowed and limbs swelled. They began to cough and struggled to breathe.

People who do not get enough minerals or vitamins can develop iron-deficiency anaemia, which means they do not have enough healthy red blood cells to carry oxygen to tissues throughout the body.

So as children starve, their bodies slowly suffocate.

Dr Olow said such cases are becoming commonplace. Children arriving at Benadir Hospital receive oxygen, emergency feeding and, if needed, blood transfusions. Just three percent die, Olow said.

By the time Isak brought Muna and Hamdi for treatment, it was too late.

"The doctors could not help them, because they were about to die when we reached the hospital," Isak said.

Conflict in Europe

Russia's invasion of Ukraine in February added to Africa's problems.

The crisis distracted wealthy governments' humanitarian agencies for the first half of this year, said a senior Western government official involved in humanitarian response in Africa, who asked not to be named because he was not authorised to speak to the media.

"When Ukraine happened, it sucked all the oxygen out of the room," he said.

As the food crisis deepened earlier this year, the African Development Bank set up an emergency food production fund of $1.5 billion aimed at helping African farmers produce 38 million tonnes of wheat, corn, rice and soybeans.

However needs across Africa's crises have risen by 13% over the past year alone, the data shows. While total donor funding over that time has increased 12%, it currently meets just half of requirements.

European countries in particular have cut aid in Africa. European governments contributed 21% of humanitarian relief aid to African countries in 2022, down 16 percentage points since 2018.

Some countries such as the United States have since boosted humanitarian assistance budgets, but the shortfalls remain, a Reuters analysis of UN  data shows.

Four of the five African countries receiving the most humanitarian funding under the 2022 aid appeal are located in or border the drought-stricken Horn of Africa region.

That is leading to some tough choices.

The WFP has, in some cases, been forced to reduce rations, said Ollo Sib, a senior researcher for the agency in West Africa.

"We can keep people alive, but we don't just want to keep people alive," he said.

Chad, for example, currently hosts 577,000 refugees from other countries, the largest group in West Africa. Since 2020, conflict there has also more than doubled the number of internally-displaced Chadians to around 381,000.

Faced with overwhelming needs, the WFP has already begun reducing rations for some refugees. And it told Reuters that, without more funding soon, it could be forced to suspend food assistance for all but the ten percent of refugees considered the most vulnerable.

Moscow's Ukraine campaign also throttled grain exports.

The UN  and Turkey brokered a deal in July to unblock three Black Sea ports. Under that initiative, 615 vessels left Ukrainian ports between August 1 and December 13 carrying over 13.8 million tonnes of corn, wheat, rapeseed and sunflower oil.

However, only just  11 of these ships were destined for sub-Saharan Africa.

It's making a contribution. But there is no silver bullet," said the WFP's Dunford.

Disruptions caused by that war have also provoked a fertiliser shortage. Where stocks are available, prices have risen beyond the means of many farmers. The result will be smaller harvests next year: In West Africa, the WFP estimates cereal production could fall 20%.

The Benadir hospital cannot always help.

"Sometimes mothers bring us dead children," said Farhia Moahmud Jama, head nurse at the paediatric emergency unit. "And they don't know they're dead."

Weakened by hunger, camp residents are vulnerable to disease and people are dying due to a lack of food, said Nadifa Hussein Mohamed, who managed the camp where Isak's family initially stayed.

"Maybe the whole world is hungry and donors are bankrupt, I don't know," she said. "But we're calling out for help and we do not see relief."

Isak and her husband said some nights, armed men threaten and beat the residents: "They want to sell the land."

Ahmed, the district official, said security around the camps was tight.

 

Food supplies are distributed during a visit by World Food Programme (WFP) Regional Director Michael Dunford to a camp for the internally-displaced in Adadle, in the Somali Region of Ethiopia, January 22, 2022. (AP)
Food supplies are distributed during a visit by World Food Programme (WFP) Regional Director Michael Dunford to a camp for the internally-displaced in Adadle, in the Somali Region of Ethiopia, January 22, 2022. (AP)

Debt

COVID-19 left Africa facing the strongest economic headwinds in years, according to the International Monetary Fund (IMF).

After years of borrowing, countries are struggling to service their debts. According to the IMF, 19 of sub-Saharan Africa's 35 low-income countries are in debt distress where a government is unable to fulfil its financial obligations and debt restructuring is required or at high risk of it.

Ghana is an example. The country of 32 million people owed around $42 billion in September,  over $1,300 per person. In July, the government turned to the IMF for relief. In December, Finance Minister Ken Ofori-Atta said debt had topped 100% of Ghana's Gross Domestic Product.

Ghana's currency, the cedi, is Africa's weakest. At its lowest level this year, in November, it sank by 59% against the dollar, straining the country's ability to pay for imports. Shopkeepers shut their doors temporarily in October in protest.

In October, Ghana's inflation rate hit a new 21-year high of 40.4%, driven in large part by higher food costs. Cereal prices have gone up over 51%. Dairy and eggs by nearly 59%.

Globally, prices of cereals, dairy, meat, vegetable oils and sugar climbed over 23% in 2021, the fastest in more than a decade, according to an index from the FAO.

Food expenses constitute 40% of households' consumer spending in sub-Saharan Africa, the highest share in the world, according to the IMF.

For Ghanaian Evelyn Lartey, a trip to market in the capital Accra has become a race.

"The maths you use one day expires the next, and you don't know what are the real prices," she said. "You just have to pay what you're told or else keep walking."

Heart pain

On Wednesday October 19, months after Muna and Hamdi's deaths, two of Isak's other daughters Nasib and Fardawsa could not sleep.

"They were complaining of heart pain. It was 2am," she said.

They set off for the hospital. There were few vehicles on the road and none stopped when they tried to wave them down, so Isak and her husband carried the children for four kilometres.

A normal three-year-old child has between 11 and 13.7 grams of haemoglobin, the iron-rich protein that carries oxygen around the body, per decilitre of blood.

Doctors told Isak that Fardawsa's blood contained one gram of haemoglobin per decilitre. She needed a blood transfusion.

The medics could not find a vein on her hands, so they transfused the blood through a vein in her head.

"It's not yet her time to die," her mother said, relieved.

Government failures

African governments have done little to prevent food crises from recurring.

In a move to boost production, reduce import reliance and improve food security, leaders in 2003 pledged to commit at least ten percent of their national budgets to agriculture and rural development within five years.

By 2021, nearly two decades later, just two countries in sub-Saharan Africa, Mali and Zimbabwe, met that target.

Instead, an analysis of 39 African countries by UK charity Oxfam found, spending on agriculture fell as a share of budgets between 2019 and 2021.

Agriculture makes up nearly 20% of Africa's GDP and more than half of Africans work in the sector, according to the World Bank. Most of this is low-productivity subsistence farming and the region is a net importer of staples including wheat, palm oil and rice, the FAO says.

Productivity and crop yields have increased, but they are still the lowest in the world and the FAO says they come nowhere close to keeping up with the continent's growing population, which the UN  forecasts will more than triple to 4.3 billion by the end of the century.

So agricultural production per capita is falling, according to the FAO.

Self-sufficiency for major food commodities is decreasing. Without action, the World Bank says Africa's food import bill, which stood at $43 billion in 2019, could rise to $110 billion in 2025.

"We have 65% of the world's available arable land. We have to wake up," Akinwumi Adesina, president of the African Development Bank, told Reuters.

"For me, the bare minimum is that Africa is able to feed itself."

"Strength, but no work"

Nasib and Fardawsa spent a week in the hospital, receiving blood transfusions, medicine and nutritional biscuits. They recovered, but then Isak's four-month-old, Farhan, needed care.

He received an emergency transfusion and treatment. The doctor prescribed syrups and supplementary iron tablets that the family cannot afford.

"I don't have any money," she said.

In search of aid and security, in November the family moved onto an abandoned military camp closer to the city centre.

They are no longer harassed, but attacks by Islamist militants periodically send the city into lock-down. Isak's husband, Mohamed Ibrahim, hoped he could earn money for food in town, working as a porter.

"I have strength but no work. I have a wooden wheelbarrow," he said. But most people use the services of tuk-tuks instead.

After months on the move, from her village to the city, from camp to camp and hospital to hospital, Isak is running out of energy. She believes she herself and two other children are now also anaemic.

"If he gets a dollar or two, this is not even enough for food for the children."

Written By  Joe Bavier, Abdi Sheikh, Aditi Bhandari and Michael Ovaska