The full details of recent experiments that made a deadly flu virus more contagious will be published, probably within a few months, despite recommendations by the United States that some information be kept secret for fear that terrorists could use it to start epidemics.

The announcement, made on Friday by the World Health Organization, follows two months of heated debate about the flu research. The recommendation to publish the work in full came from a meeting of 22 experts in flu and public health from various countries who met on Thursday and Friday in Geneva at the organization’s headquarters to discuss “urgent issues” raised by the research.

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- COMMUNICATION to CERN – For a neutral and multi-disciplinary risk assessment before any LHC upgrade

According to CERN’s Chamonix workshop (Feb. 6–10 2012) and a press release from today: In 2012 the collision energies of the world’s biggest particle collider LHC should be increased from 3.5 to 4 TeV per beam and the luminosity is planned to be increased by a factor of 3. This means much more particle collisions at higher energies.

CERN plans to shut down the LHC in 2013 for about 20 months to do a very costly upgrade (for CHF 1 Billion?) to run the LHC at double the present energies (7 TeV per beam) afterwards.

Future plans: A High-Luminosity LHC (HL-LHC) is planned, “tentatively scheduled to start operating around 2022” — with a beam energy increased from 7 to 16.5 TeV(!):
http://cdsweb.cern.ch/journal/CERNBulletin/2012/06/News%20Articles/1423292?ln=en

One might really ask where this should lead to – sooner or later – without the risks being properly investigated. Many critics from different fields are severely alarmed.

For comparison: The AMS 2 experiment for directly measuring cosmic rays in the atmosphere operates on a scale around 1.5 TeV. Very high energetic cosmic rays have only been measured indirectly (their impulse). Sort, velocity, mass and origin of these particles are unknown. In any way, the number of collisions under the extreme and unprecedented artificial conditions at the LHC is of astronomical magnitudes higher than anywhere else in the nearer cosmos.

There were many talks on machine safety at the Chamonix meeting. The safety of humans and environment obviously were not an official topic. That’s why critics turned to CERN in an open letter:

———————————————————–
Communication on LHC Safety directed to CERN

For a neutral and multidisciplinary risk assessment to be done before any LHC upgrade

—————————-
Communiqué to CERN
—————————-

Dear management and scientists at CERN,

Astronomer and Leonardo-publisher Roger Malina recently emphasized that the main problem in research is that “curiosity is not neutral”. And he concluded: “There are certain problems where we cannot cloister the scientific activity in the scientific world, and I think we really need to break the model. I wish CERN, when they had been discussing the risks, had done that in an open societal context, and not just within the CERN context.”

Video of Roger Malina’s presentation at Ars Electronica, following prominent philosopher and leading constructivist Humberto Maturana’s remarkable lecture on science and “certainy”: https://www.youtube.com/watch?v=DOZS2qJrVkU

In the eyes of many critics a number of questions related to LHC safety are not ruled out and some of them have concrete and severe concerns. Also the comparability of the cosmic ray argument is challenged.

Australian risk researcher and ethicist Mark Leggett concludes in a paper that CERN meets less than a fifth of the criteria of a modern risk assessment:
http://lhc-concern.info/wp-content/uploads/2009/09/leggett_r…_1__09.pdf

Without getting into details of the LHC safety discussion – this article in the well-recognized Physics arXiv Blog (MIT’s Technology Review) states: “Black Holes, Safety, and the LHC Upgrade — If the LHC is to be upgraded, safety should be a central part of the plans.”

Similar to pragmatic critics, the author claims in his closing remarks: “What’s needed, of course, is for the safety of the LHC to be investigated by an independent team of scientists with a strong background in risk analysis but with no professional or financial links to CERN.”
http://www.technologyreview.com/blog/arxiv/27319/

The renowned Institute for Technology Assessment and Systems Analysis (ITAS) in Karlsruhe and other risk researchers have already signalized interest in cooperation. We think, in such a process, naturally also CERN and critics should be constructively involved.

Please act in favour of such a neutral and multi-disciplinary assessment, maybe already following the present Chamonix meeting. Even if you feel sure that there are no reasons for any concerns, this must be in your interest, while also being of scientific and public concern.

In the name of many others:
[…]
————————–
LHC-Kritik / LHC-Critique
www.LHC-concern.info

Direct link to this Communication to CERN:
http://lhc-concern.info/?page_id=139
Also published in “oekonews”: http://www.oekonews.at/index.php?mdoc_id=1067776

CERN press release from Feb 13 2012:
http://press.web.cern.ch/press/PressReleases/Releases2012/PR01.12E.html

“Badly designed to understand the Universe — CERN’s LHC in critical Reflection by great Philosopher H. Maturana and Astrophysicist R. Malina”:
https://lifeboat.com/blog/2012/02/badly-designed-to-understa…t-r-malina

“LHC-Kritik/LHC-Critique – Network for Safety at experimental sub-nuclear Reactors”, is a platform articulating the risks related to particle colliders and experimental high energy physics. LHC-Critique has conducted a number of detailed papers demonstrating the insufficiency of the present safety measures under well understandable perspectives and has still got a law suit pending at the European Court of Human Rights.

More info at LHC-Kritik / LHC-Critique:
www.LHC-concern.info
[email protected]
+43 650 629 627 5

In 2012 LHC collision energies should be increased from 3.5 to 4 TeV per beam and the luminosity is planned to be highly increased. This means much more particle collisions at higher energies.

CERN plans to shut down the LHC in 2013 for about 20 months to do a very costly upgrade (CHF 1 Billion?) to run the LHC at 7 TeV per beam afterwards.

Future plans:  A High-Luminosity LHC (HL-LHC) is planned, “tentatively scheduled to start operating around 2022” — with a beam energy increased from 7 to 16.5 TeV(!).

One might really ask where this should lead to – sooner or later – without the risks being properly investigated.

For comparison: The AMS experiment for directly measuring cosmic rays in the atmosphere operates on a scale around 1.5 TeV. Very high energetic cosmic rays have only been measured indirectly (their impulse). Sort, velocity, mass and origin of these particles are unknown. In any way, the number of collisions under the extreme and unprecedented artificial conditions at the LHC is of astronomical magnitudes higher than anywhere else in the nearer cosmos.

There were many talks on machine safety at the Chamonix meeting. The safety of humans and environment obviously were not an official topic. No reaction on the recent claim for a really neutral, external and multi-disciplinary risk assessment by now.

Official reports from the LHC performance workshop by CERN Bulletin:

http://cdsweb.cern.ch/journal/CERNBulletin/2012/06/News%20Articles/?ln=de

LHC Performance Workshop — Chamonix 2012:

https://indico.cern.ch/conferenceOtherViews.py?view=standard&confId=164089

Feb 10 2012: COMMUNICATION directed to CERN for a neutral and multidisciplinary risk assessment to be done before any LHC upgrade:

http://lhc-concern.info/?page_id=139

More info at LHC-Kritik / LHC-Critique: Network for Safety at experimental sub-nuclear Reactors:

www.LHC-concern.info

(Article published in “oekonews”: http://oekonews.at/index.php?mdoc_id=1067777 )

The latest renowned “Ars Electronica Festival” in Linz (Austria) was dedicated in part to an uncritical worship of the gigantic particle accelerator LHC (Large Hadron Collider) at the European Nuclear Research Center CERN located at the Franco-Swiss border. CERN in turn promoted an art prize with the idea to “cooperate closely” with the arts. This time the objections were of a philosophical nature – and they had what it takes.

In a thought provoking presentation Maturana addressed the limits of our knowledge and the intersubjective foundations of what we call “objective” and “reality.” His talk was spiked with excellent remarks and witty asides that contributed much to the accessibility of these fundamental philosophical problems: “Be realistic, be objective!” Maturana pointed out, simply means that we want others to adopt our point of view. The great constructivist and founder of the concept of autopoiesis clearly distinguished his approach from a solipsistic position.

Given Ars Electronica’s spotlight on CERN and its experimental sub-nuclear research reactor, Maturana’s explanations were especially important, which to the assembled CERN celebrities may have come in a mixture of an unpleasant surprise and a lack of relation to them.

During the question-and-answer period, Markus Goritschnig asked Maturana whether it wasn’t problematic that CERN is basically controlling itself and discarding a number of existential risks discussed related to the LHC — including hypothetical but mathematically demonstrable risks also raised — and later downplayed — by physicists like Nobel Prize winner Frank Wilczek, and whether he thought it necessary to integrate in the LHC safety assessment process other sciences aside from physics such as risk search. In response Maturana replied (in the video from about 1:17): “We human beings can always reflect on what we are doing and choose. And choose to do it or not to do it. And so the question is, how are we scientists reflecting upon what we do? Are we taking seriously our responsibility of what we do? […] We are always in the danger of thinking that, ‘Oh, I have the truth’, I mean — in a culture of truth, in a culture of certainty — because truth and certainty are not as we think — I mean certainty is an emotion. ‘I am certain that something is the case’ means: ‘I do not know’. […] We cannot pretend to impose anything on others; we have to create domains of interrogativity.”

Disregarding these reflections, Sergio Bertolucci (CERN) found the peer review system among the physicists’ community a sufficient scholarly control. He refuted all the disputed risks with the “cosmic ray argument,” arguing that much more energetic collisions are naturally taking place in the atmosphere without any adverse effect. This safety argument by CERN on the LHC, however, can also be criticized under different perspectives, for example: Very high energetic collisions could be measured only indirectly — and the collision frequency under the unprecedented artificial and extreme conditions at the LHC is of astronomical magnitudes higher than in the Earth’s atmosphere and anywhere else in the nearer cosmos.

The second presentation of the “Origin” Symposium III was held by Roger Malina, an astrophysicist and the editor of “Leonardo” (MIT Press), a leading academic journal for the arts, sciences and technology.

Malina opened with a disturbing fact: “95% of the universe is of an unknown nature, dark matter and dark energy. We sort of know how it behaves. But we don’t have a clue of what it is. It does not emit light, it does not reflect light. As an astronomer this is a little bit humbling. We have been looking at the sky for millions of years trying to explain what is going on. And after all of that and all those instruments, we understand only 3% of it. A really humbling thought. […] We are the decoration in the universe. […] And so the conclusion that I’d like to draw is that: We are really badly designed to understand the universe.”

The main problem in research is: “curiosity is not neutral.” When astrophysics reaches its limits, cooperation between arts and science may indeed be fruitful for various reasons and could perhaps lead to better science in the end. In a later communication Roger Malina confirmed that the same can be demonstrated for the relation between natural sciences and humanities or social sciences.

However, the astronomer emphasized that an “art-science collaboration can lead to better science in some cases. It also leads to different science, because by embedding science in the larger society, I think the answer was wrong this morning about scientists peer-reviewing themselves. I think society needs to peer-review itself and to do that you need to embed science differently in society at large, and that means cultural embedding and appropriation. Helga Nowotny at the European Research Council calls this ‘socially robust science’. The fact that CERN did not lead to a black hole that ended the world was not due to peer-review by scientists. It was not due to that process.”

One of Malina’s main arguments focused on differences in “the ethics of curiosity”. The best ethics in (natural) science include notions like: intellectual honesty, integrity, organized scepticism, dis-interestedness, impersonality, universality. “Those are the believe systems of most scientists. And there is a fundamental flaw to that. And Humberto this morning really expanded on some of that. The problem is: Curiosity is embodied. You cannot make it into a neutral ideal of scientific curiosity. And here I got a quote of Humberto’s colleague Varela: “All knowledge is conditioned by the structure of the knower.”

In conclusion, a better co-operation of various sciences and skills is urgently necessary, because: “Artists asks questions that scientists would not normally ask. Finally, why we want more art-science interaction is because we don’t have a choice. There are certain problems in our society today that are so tough we need to change our culture to resolve them. Climate change: we’ve got to couple the science and technology to the way we live. That’s a cultural problem, and we need artists working on that with the scientists every day of the next decade, the next century, if we survive it.

Then Roger Malina directly turned to the LHC safety discussion and articulated an open contradiction to the safety assurance pointed out before: He would generally hope for a much more open process concerning the LHC safety debate, rather than discussing this only in a narrow field of particle physics, concrete: “There are certain problems where we cannot cloister the scientific activity in the scientific world, and I think we really need to break the model. I wish CERN, when they had been discussing the risks, had done that in an open societal context, and not just within the CERN context.”

Presently CERN is holding its annual meeting in Chamonix to fix LHC’s 2012 schedules in order to increase luminosity by a factor of four for maybe finally finding the Higgs Boson – against a 100-Dollar bet of Stephen Hawking who is convinced of Micro Black Holes being observed instead, immediately decaying by hypothetical “Hawking Radiation” — with God Particle’s blessing. Then it would be himself gaining the Nobel Prize Hawking pointed out. Quite ironically, at Ars Electronica official T-Shirts were sold with the “typical signature” of a micro black hole decaying at the LHC – by a totally hypothetical process involving a bunch of unproven assumptions.

In 2013 CERN plans to adapt the LHC due to construction failures for up to CHF 1 Billion to run the “Big Bang Machine” at double the present energies. A neutral and multi-disciplinary risk assessment is still lacking, while a couple of scientists insist that their theories pointing at even global risks have not been invalidated. CERN’s last safety assurance comparing natural cosmic rays hitting the Earth with the LHC experiment is only valid under rather narrow viewpoints. The relatively young analyses of high energetic cosmic rays are based on indirect measurements and calculations. Sort, velocity, mass and origin of these particles are unknown. But, taking the relations for granted and calculating with the “assuring” figures given by CERN PR, within ten years of operation, the LHC under extreme and unprecedented artificial circumstances would produce as many high energetic particle collisions as occur in about 100.000 years in the entire atmosphere of the Earth. Just to illustrate the energetic potential of the gigantic facility: One LHC-beam, thinner than a hair, consisting of billions of protons, has got the power of an aircraft carrier moving at 12 knots.

This article in the Physics arXiv Blog (MIT’s Technology Review) reads: “Black Holes, Safety, and the LHC Upgrade — If the LHC is to be upgraded, safety should be a central part of the plans.”, closing with the claim: “What’s needed, of course, is for the safety of the LHC to be investigated by an independent team of scientists with a strong background in risk analysis but with no professional or financial links to CERN.”
http://www.technologyreview.com/blog/arxiv/27319/

Australian ethicist and risk researcher Mark Leggett concluded in a paper that CERN’s LSAG safety report on the LHC meets less than a fifth of the criteria of a modern risk assessment. There but for the grace of a goddamn particle? Probably not. Before pushing the LHC to its limits, CERN must be challenged by a really neutral, external and multi-disciplinary risk assessment.

Video recordings of the “Origin III” symposium at Ars Electronica:
Presentation Humberto Maturana:

Presentation Roger Malina:

“Origin” Symposia at Ars Electronica:
http://www.aec.at/origin/category/conferences/

Communication on LHC Safety directed to CERN
Feb 10 2012
For a neutral and multidisciplinary risk assessment to be done before any LHC upgrade
http://lhc-concern.info/?page_id=139

More info, links and transcripts of lectures at “LHC-Critique — Network for Safety at experimental sub-nuclear Reactors”:

www.LHC-concern.info

In this light it is rather ‘cute’ that the site here dedicated to existential risks to society is called the Lifeboat Foundation when one of our less discussed risks is that of world-wide flooding of a massive scale to major coastal cities/ports & industries right across the world.

Why do we still continue to grow our cities below a safe limit of say 10 meters above sea level when cities are built to last thousands of years, but could now be flooded within hundreds. How many times do we have to witness disaster scenarios such as the Oklahoma City floods before we contemplate this occurring irreversibly to hundreds of cities across the world in the future. Is it feasible to take the approach of building large dams to preserve these cities, or is it a case of eventually evacuating and starting all over again? In the latter case, how do we safely contain chemical & nuclear plants that would need to be abandoned in a responsible and non-environmentally damaging procedure?

Let’s be optimistic here — the Antarctic ice sheets are unlikely to disappear in time scales we need to worry about today — but the Greenland ice sheet is topical. Can it be considered an existential risk if the process takes hundreds of years and we can slowly step out of the way though so much of the infrastructure we rely on is being relinquished? Will we just gradually abandon our cities to higher ground as insurance companies refuse to cover properties in coastal flooding areas? Or will we rise to a challenge and take first steps to create eco-bubbles & ever larger dams to protect cities?

I would like to hear others thoughts on this topic of discussion here - particularly if anyone feels that the Greenland ice sheet situation is reversible…

The general consensus is that Venus was more like that of the Earth several billion years ago, with liquid water on the surface, but a runaway greenhouse effect may have been caused by the evaporation of the surface water and subsequent rise of greenhouse gases.

It poses not just a harsh warning of the prospects of global warming on Earth, but also a case study for how to counter such effects — reversing the runaway greenhouse effect.

I have wondered if anyone has given serious thought to chemical processes which could be set in motion on Venus to extract the carbon dioxide from the atmosphere. The most common gas in the Universe is of course hydrogen, and if sufficient quantities could be introduced to the Venusian atmosphere, with the appropriate catalysts, could the carbon dioxide in the atmosphere be eventually reversed back into solid carbon compounds, water vapor and oxygen? The effect of this would of course not only bring down the temperature, but return the surface pressure, with 95% of its atmosphere removed, to one more similar to that of Earth. Perhaps in adding other aerosols the temperatures could be reduced further and avoid a re-runaway effect.

I’d like to hear others thoughts on this. It would be a long term project — but would perhaps make our closest planet our most habitable one in the future — one we could turn into a habitat that would be very accessible, with ample oxygen, water and mineral resources… The study of such a process would also greatly benefit Earth in the event that theorized runaway greenhouse effects start to occur on our own planet, the strategies learned could save it. Other issues to address regarding Venus: lack of magnetic field and  its slow rotation would have to be considered, though hardly off-putting, and 150ppm sulfur dioxide in the atmosphere would need to be cleansed — surely not insurmountable.

One thing everyone agrees on is that local resources will have to be used. We now know that There has been a lot of geological and hydrological activity on Mars that has segregated and concentrated useful ore bodies that can be exploited with current extractive technology. One type of mineral of interest is the occurrence of iron and magnesium carbonate formations on the surface. Magnesium carbonate is easily converted by heating to magnesium oxide, the primary component of a type of cement that I am researching as a construction material for Mars. The widespread occurrence of sulfate salts also gives reason to believe that metal sulfide ore bodies are also available there. This type of ore can easily be refined with simple electrolytic equipment. The same metal refining on the Moon would require grinding and processing basalt with a lot of heavy equipment.

I would argue that Mars also has a more friendly environment. First, it has higher gravity than the moon, at 38% of Earth’s gravity. This may prove to be significant in minimizing the health effects of reduced gravity. The higher gravity would also aid in many industrial processes such as ore separation and concrete consolidation. Mars also has an atmosphere, however thin. While 4 to 8 millibars may not sound like much, it is enough to burn up a lot of micrometeorites before they reach the surface, reducing the danger of micrometeorite damage. It may also help reduce the danger of galactic cosmic rays, but that will need to be tested. One thing that is certain from my own research is that the thin atmosphere is enough to allow magnesium oxychloride cement to cure before a significant amount of water has evaporated from it, and prevent boiling during the curing process. On the airless Moon, this type of cement would boil violently and the water would evaporate before it would cure. The total lack of atmosphere on the Moon would preclude the use of any cement that depends on water for curing.

Dust will be the biggest challenge to machinery in either place, and I argue that it is much less of a challenge on Mars. We have already studied lunar dust, and it is composed of fractured particles that retain sharp edges and points, with no mechanisms for smoothing the surfaces such as wind or water movement. This makes Moon dust very abrasive to machinery (and air seals) and very irritating to human tissues on contact. Mars has annual wind storms that blow dust around the planet, and has had flowing water recently in it’s history. This would serve to smooth out Martian dust particles to something more closely resembling the kind of material found on Earth, which we can more easily deal with. As further evidence, we have had rovers survive multiple dust storms and keep operating. I would say this is as much a testament to the Martian environment as it is to NASA engineers. Additionally, the dust has been found to be largely magnetic, meaning that magnetic filtration could be used to keep it out of habitable spaces.

Some would argue that solar power is more abundant on the Moon, but the problem there is that it intermittent. 14 days on, then 14 days off. Power either has to be stored for two weeks at a time, or produced from other sources. On Mars, you just need to get through a single night. The dust storms can cause problems of course, but that is at most a month out of every 22.

Finally, there is the question of water. On the Moon, water ice is probably at the bottom of some deep craters near the poles. It can probably be mined beneath the surface, we are just not sure how far down we need to go. On Mars, snow has been observed made up of water ice, and water ice has been seen just beneath the surface in rover tracks. It appears to be everywhere, just below the surface.

The Moon may be closer as the bird flies, but in terms of energy to get there, Mars is not much further. The biggest challenge will be getting humans there alive, but once that is done the learning curve once we get there is much shorter. Instead of developing new and untested industrial processes to exploit lunar resources, we can use proven technology to exploit Martian resources with much less effort. The prize is there for the taking, and there is no point in stopping on the way to build a temple to Luna.