The Regulation of Geoengineering - Science and Technology Commitee Contens


Parliament UK





4  Future regulatory arrangements

59. Having concluded in the previous chapter that there is a need to develop the regulatory regimes for geoengineering, we examine in this chapter what regulatory principles and arrangements should apply and how they might operate.


The formulation of a regulatory regime

60. The first stage in establishing a regulatory regime (or regimes) is to decide on principles and common procedures. The experts who gave us oral evidence favoured a "bottom-up generation of norms"[116] rather than a "top-down" approach from an organisation such as the UN. John Virgoe wished to develop and "socialise" the norms "among the community of nations, the community of scientists and other stakeholders".[117] He considered that the state of international understanding and also the knowledge base was currently so weak that the outcome from a top-down approach could be unsatisfactory. He explained: 

it is very possible to imagine, if this is put on the table in some sort of UN forum, you could end up with a decision [...] to make geoengineering a taboo, to outlaw it, and that would be a mistake, for a couple of reasons. One is that it may be that we actually need to be doing this research and that, some decades down the line, we will be very sorry if we have not started thinking through these techniques. The second is that I think there are a lot of actors out there [...] with the capacity to research and implement these techniques. Some of them may not feel bound by that sort of international decision, some of them may not be as responsible, and it would be very unfortunate if what geoengineering research was happening was going on under the radar screen, if you like. What we need is an open process which builds on some of the principles that are already out there around similar issues; for example, principles developed to deal with long-range air pollution or weather modification: principles around openness, transparency and research, notifying a neighbouring country or countries which might be affected. We probably develop these through maybe a slightly messier process than an international negotiation. Individual countries will have a role; communities of scientists will certainly have a role.[118]


61. While accepting that the "bottom-up" approach could work well for developing deployment technologies, laboratory research and computational modelling, Dr Blackstock had reservations whether it would be sufficient when it came to field tests, particularly high leverage SRM technologies and those with trans-boundary impact. He said that as well as the technical risk and the environmental risk there was the political risk in the perception of the test.[119] He cited the recent case of the ocean fertilisation experiment in 2009—Lohafex—an Indo-German collaboration. He said that the test would have had very small impacts in terms of the ecosystems and trans-boundary.[120] But it demonstrated the political sensitivities any geoengineering experiments could evoke. He said that at the core of this controversy was also the "difficulty of defining politically acceptable (national and international) scientific standards and oversight mechanisms for ensuring the environmental and transboundary risks of nominally subscale geoengineering field tests were in fact 'demonstrably negligible'".[121] DECC explained that a moratorium had been placed on large-scale ocean fertilisation research under the Convention for Biological Diversity while a regulatory agreement was being developed under the London Convention/Protocol.[122]


62. Dr Blackstock took the view that "the consideration of the norms is partly necessary but not sufficient to address the sort of political issues that will raise".[123] In his view it was necessary to have a "mechanism of legitimacy", to define subscale (that is, small) experiments "before we start pushing the boundaries of [...] subscale, that is [...] where we really need to have, not just scientific, but political agreement".[124] Where nation states were starting to fund research, particularly if it went to funding subscale experimentation, Dr Blackstock considered that "we need to ask what preventive commitments, what precautionary commitments nation states need [...] up front in order to avoid exacerbating all the mistrust that already exists within the international climate arena".[125]


63. Research Councils UK took a more cautious view than Dr Blackstock. It was concerned that even small-scale actions could generate negative environmental, social and economic consequences if undertaken without appropriate controls in place or a sufficient level of expertise. It cited, as an example, a field trial involving atmospheric SRM manipulations that might temporally—but perhaps coincidentally—be linked to extreme weather events resulting in high economic consequences. Research Councils UK also considered that some highly controversial techniques could be applied at relatively low cost and with relative ease, opening up geoengineering as a feasible unilateral activity to a wide range of actors with different knowledge, skills and motivations. Such actions might be linked to political as well as, or even instead of, environmental concerns. This suggested to Research Councils UK that "regulation might be best monitored at the level of supra-national governance structures such as the UN".[126]


64. Dr van Aalst was anxious that if geoengineering was raised at a high political level too early, it could be sending the "wrong signals".[127] He considered that there were more technically oriented UN bodies that would be more appropriate, such as the Intergovernmental Panel on Climate Change (IPCC). He hoped that, along with some conscious efforts at consultation focussed primarily on looking at risks, it "might actually be then guiding us towards more investments on the mitigation and adaptation sides".[128] He hoped that discussions in "UN bodies would then trigger a much wider debate, involving a larger range of stakeholders, and a more diverse set of stakeholders than have been taking part in this discussion so far".[129]


65. In our view, there is a case for starting to develop the international framework for geoengineering now as opposed to waiting for the state of international understanding and the knowledge base for geoengineering to grow. Characterising the development of an international framework as top-down may be exaggerated as development will not be uniform for geoengineering techniques and the development of geoengineering regulatory arrangements is likely to take years. Nor does it preclude the building of bottom-up practices and approaches to geoengineering. While accepting that the development of a "top-down" regulatory framework may have risks and limitations, we consider that these are outweighed by the benefits of an international framework: legitimacy; scientific standards; oversight mechanisms; and management of environmental and trans-boundary risks.






66. In a submission to our inquiry a group of academics set out five key principles by which they believed geoengineering research should be guided.[130We welcome the production of the principles by a group of academics which provide a basis to begin the discussion of principles that could be applied to the regulation of geoengineering. We consider that the proposed principles could be useful both to the "top-down" approach and, to a lesser extent, to a "bottom-up" approach. (It could, for example, inform the drafting of the code of practice on research suggested by the Royal Society—see paragraph 89.) We therefore examine the principles in detail. The principles and part of the explanatory text are set out in the box below.


Principle 1: Geoengineering to be regulated as a public good

While the involvement of the private sector in the delivery of a geoengineering technique should not be prohibited, and may indeed be encouraged to ensure that deployment of a suitable technique can be effected in a timely and efficient manner, regulation of such techniques should be undertaken in the public interest by the appropriate bodies at the state and/or international levels.


Principle 2: Public participation in geoengineering decision-making

Wherever possible, those conducting geoengineering research should be required to notify, consult, and ideally obtain the prior informed consent of, those affected by the research activities. The identity of affected parties will be dependent on the specific technique which is being researched—for example, a technique which captures carbon dioxide from the air and geologically sequesters it within the territory of a single state will likely require consultation and agreement only at the national or local level, while a technique which involves changing the albedo of the planet by injecting aerosols into the stratosphere will likely require global agreement.



Principle 3: Disclosure of geoengineering research and open publication of results

There should be complete disclosure of research plans and open publication of results in order to facilitate better understanding of the risks and to reassure the public as to the integrity of the process. It is essential that the results of all research, including negative results, be made publicly available.


Principle 4: Independent assessment of impacts

An assessment of the impacts of geoengineering research should be conducted by a body independent of those undertaking the research; where techniques are likely to have trans-boundary impact, such assessment should be carried out through the appropriate regional and/or international bodies. Assessments should address both the environmental and socio-economic impacts of research, including mitigating the risks of lock-in to particular technologies or vested interests. 


Principle 5: Governance before deployment


Any decisions with respect to deployment should only be taken with robust governance structures already in place, using existing rules and institutions wherever possible. [131]


67. In putting forward these principles the academics said that transparency in decision-making, public participation, and open publication of research results were key elements of the framework, designed to ensure maximum public engagement with, and confidence in, the regulation of geoengineering research. Alone or in combination, many of these principles were already applied in the regulation of hazardous substances and activities such as the trans-boundary movement of hazardous wastes and pesticides, radioactive substances and Genetically Modified Organisms (GMOs).[132]


68. Most debate and reservations focused on the regulation of geoengineering for the public good and public participation in geoengineering decision-making.




Principle 1: Geoengineering to be regulated as a public good



69. Commenting on Principle 1—geoengineering to be regulated as a public good—Mr Virgoe asked who was the public—the global public? He pointed out that geoengineering interventions affected the planet as a whole and that there were number of publics. Some publics were suffering very badly, or would be suffering very badly, from the effects of climate change. But some populations might benefit from climate change and, therefore, would not be happy to see climate change being put into "reverse gear", if that could be achieved. He said that the impact of some of the techniques was likely to be heavily differentiated. Some areas might continue to warm, whereas other areas cooled faster and there might be unintentional side effects. He considered that below the surface of the public good "you get into some difficult ethical territory".[133]


70. Sir David King raised the treatment of intellectual property rights (IPR). He pointed out that if we are going to go down the route of carbon dioxide capture from oceans or atmosphere, and this is going to be a good thing, we also need to know, where is the investment going to come from, to take the research into demonstration phase and into the marketplace, and there will be a marketplace with a price of carbon dioxide. That is going to be the private sector companies. If we do not allow protection of IPR, are we going to actually inhibit that process of investment? So I think I am a little hesitant to simply back the pure public good argument without IPR protection.[134]


71. We conclude that Principle 1 of the suggested five key principles on how geoengineering research should be guided—"Geoengineering to be regulated as a public good"—needs, first, to be worked up in detail to define public good and public interest. Second, the implied restriction suggested in the explanatory text to the Principle on intellectual property rights must be framed in such a manner that it does not deter investment in geoengineering techniques. Without private investment, some geoengineering techniques will never be developed.




Principle 2: Public participation in geoengineering decision-making




72. One of the principles international law suggests might be used in developing a regulatory regime for geoengineering is the requirement to inform or consult (Principle 10 of the Rio Declaration).[135] In the context of geoengineering, however, Mr Virgoe questioned what the principle meant at the global level, specifically, how public participation was achieved at the global level and how to ensure that certain parts of the public, or the public in certain countries, did not have privileged access compared with other countries, publics or other parts of the global public.[136]



73. Dr Blackstock said that some countries already had populations marginalised in terms of climate change or were on the edge of suffering from climate change impacts, because those marginalised populations were likely to be the ones most sensitive to geoengineering experiments and a high level of solar radiation management experiments and particularly implementation. He saw a risk that without directive public engagement, an attempt to reach out and provide the information proactively, "we end up with them inevitably being surprised later on by rapid climate change impacts [and] that requires international public consultation, not just domestic".[137] Dr van Aalst voiced a similar concern that the more vulnerable felt "threatened by the possibility that the winners will protect their wins, and the losers, which clearly are mostly them, will not get anything".[138] He wished to see an international debate fostered and to "include attention for [the] human dimension, and to try and involve that side of the debate early on".[139]


74. We conclude that Principle 2—"Public participation in geoengineering decision-making"—is to be supported but it needs to spell out in the explanatory text what consultation means and whether, and how, those affected can veto or alter proposed geoengineering tests.




Principle 3: Disclosure of geoengineering research and open publication of results






75. On Principle 3—disclosure of geoengineering research and open publication of results—we would add that as well as publishing plans and results the agency carrying out the test should also publish any modelling relevant to the test.


76. The one concern that was expressed to us which has a bearing on this principle was the effect of classifying or restricting access to SRM research on grounds of national security. Dr Blackstock commented that it "would dangerously provoke [...] international perceptions [...] that national or corporate interests might try (or just be perceived as trying) to control or profiteer from nascent SRM technologies".[140] He added that non-public SRM research would exacerbate international mistrust about unilateral control, provoking such disputes and potentially sparking a proliferation of similarly closed programs. This could even encourage the development and unilateral testing of SRM schemes targeted to benefit specific regional climates, regardless of other impacts. And any such developments could prejudice many countries against cooperation on broader climate issues—including mitigation."[141]

77. We endorse Principle 3—"Disclosure of geoengineering research and open publication of results". The requirement to disclose the results of geoengineering research should be unqualified. We recommend that the Government press for an international database of geoengineering research to encourage and facilitate disclosure.



Principle 4: Independent assessment of impacts




78. On Principle 4—independent assessment of impacts—we regard independent review of the results of geoengineering research not only to be good scientific practice but also good politics. In the final resort decisions weighing the benefits and risks of a geoengineering intervention will be made by those most affected by climate change and those affected by the geoengineering. Those affected and those taking the decisions on their behalf will need to be confident that the scientific assessment is the best that can be provided in the circumstances.


79. It is also important to link any decision to develop, and eventually to deploy, geoengineering to global warming. Sir David King reminded us that research into impacts, both in terms of the physical and economic impacts, would also need to take into account the impacts from rising temperature. In other words, geoengineering interventions would be deployed against a temperature rise of, say, 3.5 degrees centigrade.[142]


80. Consideration of impact raised the question of compensation for those affected by geoengineering interventions. Research Councils UK said that "approval-based mechanisms should [...] include protocols for the assessment of fair compensation; should adverse impacts occur, who would meet the costs of such impacts" but acknowledged that in some cases it would be difficult to attribute climatic impacts to particular acts of geoengineering and "research on how this should be done is essential".[143] Dr van Aalst cautioned against purely economic impact assessments as they tended "to lose out on the perspective of the most vulnerable groups, which do not count much on the economic analysis side".[144]


81. Distributional issues—between countries, and between groups—is likely, in our view, to raise questions of compensation, as well as political and legal issues of liability, which, as Mr Virgoe pointed out, will need to be addressed by a governance regime or through litigation. These issues would be particularly problematic in the case of a geoengineering intervention by one country, or a group of countries. We agree with him that this strengthens the case for seeking the explicit agreement of all countries through a UN-led, multilateral process.[145]


82. We also endorse Principle 4—"The independent assessment of impacts". But it too needs to be worked up in more detail in the explanatory text to: (i) define impacts; (ii) produce agreed mechanisms for assessing impacts, including for assessing the impact of global warming; and (iii) determine whether and how compensation should be assessed and paid. The agreement of these arrangements will need to command the broadest level of support across the globe and we consider that UN-led, multilateral processes are the best way to secure concurrence.





Principle 5: Governance before deployment




83. The sponsors of the principles were clear that it was imperative that governance structures were in place to "guide research in the short term and to ensure that any decisions taken ultimately with respect to deployment occur within an appropriate governance framework".[146] Others took the same view[147] and we consider that this is a sensible approach. It does not mean that research, including tests, the regulation of which we consider below, has to be halted until regulatory frameworks are in place. It does mean that research must be carried out in parallel with discussions on the legal, social and ethical implications of geoengineering, and its regulation and governance.[148]


84. We endorse Principle 5—"Governance before deployment of any geoengineering technique". We recommend that the Government carry out research, and press for research to be carried out through international bodies on the legal, social and ethical implications, and regulation and governance of geoengineering.



The precautionary principle



85. One principle of international law not included in the suggested list is the precautionary principle (Principle 15 of the Rio Declaration).[149] In his recent article Mr Virgoe pointed out that the precautionary principle would be likely to influence debate, particularly as the side-effects of geoengineering techniques are not yet well understood. But it is unlikely that it could act as a legal, as opposed to rhetorical or moral, constraint on geoengineering: as noted by Weiss (2006), "no non-European international court has thus far accepted the Precautionary Principle as a binding principle of international law."[150]

He said that it would be necessary to be cautious in the way international debate on geoengineering was initiated. Geoengineering was so far from the current mitigation-adaptation paradigm, and raised so many concerns, "that a premature discussion might well see geoengineering banned in line with the precautionary principle".[151] Already, in June 2008, the Conference of the Parties to the Convention on Biological Diversity cited the precautionary principle in calling for a moratorium on ocean fertilisation activities. While he had sympathy for that decision on the specific issue of ocean fertilisation, Mr Virgoe said that it was "important that genuine research into geoengineering techniques are subjected to an appropriate, cautious regulatory regime rather than a blanket ban".[152]


86. The precautionary principle is an issue that our predecessor committee considered in 2006. In its Report onScientific Advice, Risk and Evidence Based Policy Making, the Committee noted that, while the precautionary principle was "valuable in dealing with uncertainty",[153] it believed that it was best to use the term precautionary approach, but with a consistent explanation of the degree and nature of the risks, benefits and uncertainty and an explanation of the concept of proportionality. It should never be considered a substitute for thorough risk analysis which is always required when the science is uncertain and the risks are serious.[154]


This approach holds good for geoengineering. To go further and make the precautionary principle predominant risks not only halting geoengineering research and small tests being carried out by those states playing by the rules to develop a Plan B but it could also force from international and public scrutiny any research carried out by other bodies or states not playing by the rules. In our view the five Principles as drafted contain a precautionary approach and that to go further is unnecessary. We conclude that the key principles should not include the precautionary principle as a discrete principle.



Conclusion on principles



87. In our view the principles as drafted provide a good starting point for either a bottom-up or a top-down approach to building a regulatory arrangements for geoengineering research. While some aspects of the suggested five key principles need further development, they provide a sound foundation for developing future regulation. We endorse the five key principles to guide geoengineering research.






88. In our earlier Report on engineering we supported research into geoengineering. The research that is most controversial is that into SRM technologies. Dr Blackstock supplied the table below which summarises the stages of SRM research that could be undertaken, along with the environmental risks and political issues each raises.[155] In this Report we have examined three stages of research: modelling; development and subscale (that is, small) field testing; and climate impact testing.



Depiction of the level of environmental impacts and the type international political issues associated with each progressive stage of SRM research.




Research: modelling




89. The Minister did not seek to put any constraint on modelling work and pointed out that the Royal Society had suggested there should be a code of conduct for research[156] at a certain level. In her view "a code of conduct is probably entirely appropriate, and we would very much support that".[157] Professor Keith considered that the "crucial thing" was to start from the bottom up through the management of a research programme in an international and transparent way. From the bottom up does not mean just that the scientists decide—that is certainly not the right answer—but it means, I think, that it would be premature to start a full UN scale EU Court treaty process, because it is simply not clear yet what the capacities are and states, individuals, have not had long enough to consider seriously what the trade-offs are.[158]

Mr Virgoe said that countries commencing geoengineering research prior to an internationally agreed framework being in place needed to make voluntary commitments to full international collaboration and transparency. Otherwise national geoengineering research that failed to make or meet such commitments "could spark international mistrust over future intentions, and disrupt the already inadequate progress toward essential mitigation".[159]


90. We agree with DECC and Professor Keith and see no reason to develop the panoply of international regulation to cover modelling of geoengineering interventions. Provided those carrying out research follow a code of practice along the lines of that suggested by the Royal Society, incorporating in particular Principle 3 on the disclosure of geoengineering research and open publication of results, we see no reason for an international regulatory regime applying to paper and computer modelling of geoengineering techniques.



Research: development and field testing




91. The ETC Group in a graphic phrase wanted to draw a "'line in the sand' at the lab door". It did not believe that it was "warranted to move geoengineering out of the laboratory and the most urgent questions of governance concern keeping that 'lab door' closed against the pressures from industrial players to move to open air geoengineering research and deployment".[160]


92. Sir David King took that view that there should be a temporary ban on solar radiation management as "the unintended consequences of that are extremely difficult to foresee".[161] He was not happy about smaller experiments being conducted at this stage in time before the unintended consequences have been fully evaluated. We are dealing with an extraordinarily complex issue here, and we all know scientifically that complex phenomena, as complexity increases, we get emergent properties that are not always easy to predict. So I do think we need to watch the stratosphere very carefully, but at the same time, in terms of regulation of the others, get ahead of the game, precisely because firstly, you want to keep the public on side, if we lose the public, then we lose the game; and secondly, we want to see that the regulation encourages the right behaviour.[162]


93. While cautious also, Dr Blackstock did not go quite as far as Sir David. To encourage international climate cooperation, he considered that countries beginning SRM research needed to take early steps to encourage the collective international exploration of SRM as a possible means for insuring global public welfare in the face of highly uncertain climate change. This, he suggested, meant making several preventive commitments. First, to foreswear climatic impacts testing—and very conservatively limit field testing—until approved by a broad and legitimate international process. Second, to keep all SRM research, including generated knowledge and technologies, in the public domain. Third, to integrate all SRM research into any subsequent international research framework.[163]


94. While we understand Sir David's concerns, we consider that a temporary ban on SRM may not be the way forward. First, it would have to be negotiated through an international agreement which will take time and may not be achieved. Second, as we noted in the previous chapter, small scale testing may already be underway. Third a ban on all testing could inhibit laboratory development of geoengineering techniques. Instead, we consider that the approach suggested by Dr Blackstock may be the way forward. Much of the focus in the previous chapter on the need for regulation was on testing. For the reasons we set out in that chapter, we are of the view that there are good scientific reasons for allowing investigative research and for seeking to devise and implement some regulatory frameworks, particularly for those techniques with the potential to allow a single country or small group of countries to test or deploy, in order to affect the global climate. We consider that a ban, even a short-term ban, on all SRM geoengineering testing would prevent work on geoengineering as "Plan B". It may well also be unenforceable and be counter-productive as those carrying out tests do so in secrecy.


95. As we have indicated we favour international regulation of SRM technologies. But we recognise that it is going to take time to devise, agree and implement regulatory frameworks for the testing of SRM technologies. In the meantime, in order to encourage research into geoengineering techniques and to foster public understanding of geoengineering, we conclude that development and small tests of SRM geoengineering should be allowed provided they:


a)  are fully in accordance with an internationally agreed set of principles such as those we have considered in this Report;

b)  have negligible or predictable environmental impact; and


c)  have no trans-boundary effects.









96. As tests increase in scale and impact they need to be regulated. We consider that any testing that impacts on the climate must be subject to an international regulatory framework.







97. Mr Virgoe pointed out that given the pre-existing mistrust on global climate issues, further steps should also be taken to foster international confidence and cooperation. He considered that national SRM programmes should involve international scientists, particularly including those from vulnerable developing countries and "more importantly, these programmes should give priority to research on SRM schemes that may preserve global public welfare, rather than focusing on narrowly defined national interests".[164]


98. We agree with both points and consider that the UK Government should lead by example. We recommend that any UK SRM programmes should involve international scientists, particularly including those from vulnerable developing countries, and that these programmes should give priority to research on SRM schemes that may preserve global public welfare. We further recommend that the UK Government press the governments of other countries to a adopt similar approach to SRM research.






97. Mr Virgoe pointed out that given the pre-existing mistrust on global climate issues, further steps should also be taken to foster international confidence and cooperation. He considered that national SRM programmes should involve international scientists, particularly including those from vulnerable developing countries and "more importantly, these programmes should give priority to research on SRM schemes that may preserve global public welfare, rather than focusing on narrowly defined national interests".[164]



98. We agree with both points and consider that the UK Government should lead by example. We recommend that any UK SRM programmes should involve international scientists, particularly including those from vulnerable developing countries, and that these programmes should give priority to research on SRM schemes that may preserve global public welfare. We further recommend that the UK Government press the governments of other countries to a adopt similar approach to SRM research.




Formulating international regulatory arrangements for geoengineering




99. As we noted at paragraph 39, regulatory regimes for most SMR techniques have yet to be developed. As Mr Virgoe noted in his recent article,[165] there are important arguments in favour of a UN process. It would give the implementation of geoengineering legitimacy, in the form of a multilateral mandate. Most multilateral environmental regimes tend to operate by consensus, at least where major decisions are concerned, whatever their formal decision-making rules. We would add that it would give a voice to those likely to be most likely to be affected by the direct environmental consequences of the use of geoengineering technology. The problem he noted was that the UN process complicated and slowed down the decision-making process and any serious geoengineering proposal would certainly lead to vigorous international debate. He considered that the chances of achieving a multilateral agreement to deploy geoengineering were "not good". He identified the following difficulties.



  • The UNFCCC/Kyoto process was committed to the mitigation/adaptation paradigm. Institutional inertia, and the commitments already made by states, would make it hard to argue for a complete change in approach under this process—and equally difficult to establish a separate multilateral process.


  • The introduction of a whole new approach would raise developing country suspicions that it would divert attention and funds from adaptation; other countries and communities would be concerned that it would reduce pressure to mitigate climate change.


  • In the absence of a substantial political community in its favour, international discussion of geoengineering would be likely to result in its prohibition in line with the precautionary principle.[166]



None of the alternative approaches—waiting for events, individual action or regional or interested groups—would have the legitimacy that action through the UN would provide.We consider that the way forward for the regulation of geoengineering is through the UN and we recommend that the UK Government and other interested countries develop proposals for the regulation of not only CDR but also SRM techniques and begin to press them through the UN.


101. The starting point for the formulation has to be the five key principles which we have discussed in this chapter. In addition, as Mr Virgoe pointed out, it will be important to ensure evidence based decision-making.[168] It will also be crucial that regulatory measures are able to respond rapidly, if necessary, following the application of geoengineering techniques. A key criterion for geoengineering to be taken forward will be the facility to withdraw applications quickly in case of negative consequences.[169] The Royal Society considered it was essential that mechanisms for the regulation of geoengineering were imbued with a high level of flexibility because:


First, regulatory controls will need to adapt to the evolution of environmental, scientific, technological, geo-political, economic and social risks. Major uncertainties remain about geoengineering and it is impossible to foresee how technologies will develop, their public confidence, and the measures that will be needed to shape and respond to such developments. In addition, environmental, geo-political, economic and social factors that will influence the development of geoengineering are also in a constant state of flux and must therefore be accounted for through flexible regulatory arrangement.


First, regulatory controls will need to adapt to the evolution of environmental, scientific, technological, geo-political, economic and social risks. Major uncertainties remain about geoengineering and it is impossible to foresee how technologies will develop, their public confidence, and the measures that will be needed to shape and respond to such developments. In addition, environmental, geo-political, economic and social factors that will influence the development of geoengineering are also in a constant state of flux and must therefore be accounted for through flexible regulatory arrangement.[170]


102. As we have noted at paragraph 27, the ENMOD treaty requires members "not to engage in military or any other hostile use of environmental modification techniques having widespread, long-lasting or severe effects as the means of destruction, damage or injury to any other State Party". We consider that it is crucial to the development of geoengineering that this principle is applied comprehensively to all geoengineering technologies.


103. We recommend that the UK Government is proactive in persuading and working with other governments to press for regulatory arrangements for geoengineering through the UN. They should do this on the basis of the following principles and objectives:

a)  geoengineering to be regulated as a public good;

b)  public participation in geoengineering decision-making;

c)  disclosure of geoengineering research and open publication of results;

d)  independent assessment of impacts;

e)  governance arrangements to be clear before deployment;

f)  decisions to be based on the best scientific evidence, including social science;

g)  regulatory measures to be able to respond rapidly;

h)  regulatory measures imbued with a high level of flexibility to be able, for example, to encompass new technologies as they emerge; and

i)  prohibition of the use of geoengineering techniques for military purposes.




Suitability of existing bodies to provide regulation of geoengineering




104. We received evidence on the suitability of existing international bodies to provide a model for the regulation of geoengineering, particularly SRM.[171] In the time available we have not been able to examine the operation of the bodies sufficiently to reach a view on whether:

a)  any organisation would provide a model for a regulatory regime for SRM; or

b)  existing bodies could be adapted to encompass SRM.


105. We were therefore attracted to the proposal of the Royal Society that a suitable international body, not exclusively a UN body, should commission a review of existing international and regional mechanisms to:


  • consider the relevant roles of the following bodies such as UNCLOS,[172] LC/LP,[173] CBD,[174] CLRTAP,[175] Montreal Protocol,[176] Outer Space Treaty,[177] Moon Treaty,[178] UNFCCC/KP,[179] ENMOD[180] the regulation of geoengineering;


  • identify existing mechanisms that could be used to regulate geoengineering research and deployment activities, if suitably extended as necessary; and


  • (for geoengineering in general) identify where regulatory gaps exist in relation to geoengineering methods proposed to date, and establish a process for the development of mechanisms to address these gaps.[181]



106. We recommend that the Government press for a suitable international body to commission a review of existing international and regional mechanisms to: (i) consider the relevant roles of the existing international bodies in the regulation of geoengineering; (ii) identify existing mechanisms that could be used to regulate geoengineering research and deployment activities, if suitably extended as necessary; and (iii) identify where regulatory gaps exist in relation to geoengineering methods proposed to date, and establish a process for the development of mechanisms to address these gaps.


107. The next stage, which DECC suggested, was that a suitable organisation needed to be identified, whose mandate would enable it to take the lead in facilitating the collaborative development of international regulations.[182] The Royal Society has suggested that an international consortium is formed to explore the safest and most effective geoengineering options while building a community of researchers and developers,[183] and we, like DECC,[184] consider that this is worth pursuing.


108. As the cost, effectiveness, timeliness and risk of putative geoengineering approaches vary substantially, Research Councils UK considered that it was therefore important that international collaboration was sought at an early stage. It explained that:

An international geoengineering advisory group may well be an appropriate body to help address these challenges. With representation from the scientific, policy, commercial, regulatory and non-governmental communities, such a group would provide independent oversight of evolving regulatory issues concerning geoengineering. It would be tasked with the coordination of existing research, and the identification of a new research agenda, as well as the development of an effective and objective assessment framework to inform the regulation of geoengineering. This would involve making informed judgements about the weight of different environmental, social and economic costs and benefits and striking an appropriate balance between short-term and long-term effects.[185]

109. We recommend that, in parallel with the development of an international regulatory framework, the UK Government press for the establishment of an international consortium, to explore the safest and most effective geoengineering options, while building a community of researchers and developers.




Role of the UK



110. Dr van Aalst pointed out that there was probably a difference between the sort of debate taking place on geoengineering in the UK and the debate in other countries, including in several different states which may already be at the stage of small scale testing of some geoengineering techniques. He considered that the UK was "in a way also operating as an international arena, and in a way setting moral standards and setting an example for how globally we should be approaching this, which is a very important side effect for your own considerations, I think, at this stage".[186]


111. We were disappointed to be told by the Minister that she could not recall any ministerial involvement in discussions on geoengineering and that it was "unlikely that we have had any ministerial discussions on regulation, but we are aware, our officials are alive to the issue, and it is something that we know needs to be done".[187] She continued:

Of course, the IPCC is going to be reporting itself, and we have taken a lot of our leads from reports from the IPCC. It is clear that if there is to be regulation, it is going to have to be in some international body, whether a scientific body, or whether the UN itself, but clearly, this is something that will have to be developed over time.[188]



112. We recommend that the UK should take the lead in raising geoengineering within international bodies such as the EU and the Commonwealth.










130   Ev 42: Professor Steve Rayner (University of Oxford), Professor Catherine Redgwell (University College London), Professor Julian Savulescu (University of Oxford), Professor Nick Pidgeon (Cardiff University) and Mr Tim Kruger (Oxford Geoengineering Institute) Back



138   Q 44; see also J Virgoe, "International governance of a possible geoengineering intervention to combat climate change", Climatic Change, 2009, 95:103-119, para 2.3. Back



145   J Virgoe, "International governance of a possible geoengineering intervention to combat climate change",Climatic Change, 2009, 95:103-119, para 2.3 Back


149   The Precautionary Principle has been endorsed internationally on many occasions. At the Earth Summit meeting at Rio in 1992, World leaders agreed Agenda 21, which advocated the widespread application of the Precautionary Principle in the following terms: "In order to protect the environment, the precautionary approach shall be widely applied by States according to their capabilities. Where there are threats of serious or irreversible damage, lack of full scientific certainty shall not be used as a reason for postponing cost-effective measures to prevent environmental degradation." (Principle 15) Back

150   J Virgoe, "International governance of a possible geoengineering intervention to combat climate change",Climatic Change, 2009, 95:103-119, para 3 Back


153   Science and Technology Committee, Seventh Report of Session 2005-06, Scientific Advice, Risk and Evidence Based Policy Making, HC 900-I, para 165 Back

154   Science and Technology Committee, Seventh Report of Session 2005-06, Scientific Advice, Risk and Evidence Based Policy Making, HC 900-I, para 166 Back

156   The Royal Society, Geoengineering the climate Science, governance and uncertainty, September 2009, rec 7  Back


165   J Virgoe, "International governance of a possible geoengineering intervention to combat climate change",Climatic Change, 2009, 95:103-119, para 4.1 Back


168   J Virgoe, "International governance of a possible geoengineering intervention to combat climate change",Climatic Change, 2009, 95:103-119, para 4.1 Back

170   Ev 24, para 17; see also J Virgoe, "International governance of a possible geoengineering intervention to combat climate change", Climatic Change, 2009, 95:103-119, para 2.4 Back

172   1994 United Nations Convention on the Law of the Sea Back

173   1972 London Convention with the 1996 Protocol of the London Convention Back

174   1992 Convention on Biological Diversity Back

175   1979 Convention on Long-Range Transboundary Air Pollution Back

176   1987 Montreal Protocol on Substances That Deplete the Ozone Layer Back

177   1967 Treaty on Principles Governing the Activities of States in the Exploration and Use of Outer Space, including the Moon and Other Celestial Bodies  Back

178   1979 Agreement Governing the Activities of States on the Moon and Other Celestial Bodies Back

179   1997 United Nations Framework Convention on Climate Change/ Kyoto Protocol Back

180   1977 Convention on the Prohibition of Military or Any Other Hostile Use of Environmental Modification Techniques Back


183   The Royal Society, Geoengineering the climate Science, governance and uncertainty, September 2009, rec 4.2 Back




House of Commons  

Science and Technology Committee Fifth Report

The Regulation of Geoengineering

Ein künstliches Klima durch SRM Geo-Engineering



 Sogenannte "Chemtrails"     sind SRM Geoengineering-   Forschungs-Experimente


 Illegale Feldversuche der   SRM Technik, weltweit.



Illegale militärische und zivile GE-Forschungen finden in einer rechtlichen Grauzone statt.


Feldversuche oder illegale SRM Interventionen wurden nie in nur einem einzigen Land der Welt,  je durch ein Parlament gebracht, deshalb sind sie nicht legalisiert und finden in einer rechtlichen Grauzone der Forschung statt. Regierungen wissen genau, dass sie diese Risiko-Forschung, die absichtliche Veränderung mit dem Wetter nie durch die Parlamente bekommen würden..


HAARP - Die Büchse der Pandora in militärischen Händen



Illegale zivile und militärische SRM Experimente finden 7 Tage die Woche (nonstop) rund um die Uhr statt. 


Auch Nachts - trotz Nacht-



Geo-Engineering Forschung


Wissenschaftler planen 10 bis 100 Megatonnen hoch toxischer Materialien wie Aluminium, synthetischen Nanopartikeln jedes Jahr in unserer Atmosphäre auszubringen.


Die Mengenangaben von SRM Materialien werden neuerdings fast immer in Teragramm berechnet. 


  1 Teragramm  = 1 Megatonne

  1 Megatonne  = 1 Million Tonnen



SAI = Stratosphärische

Aerosol Injektionen mit toxischen Materialen wie:


  • Aluminiumoxide
  • Black Carbon 
  • Zinkoxid 
  • Siliciumkarbit
  • Diamant
  • Bariumtitanat
  • Bariumsalze
  • Strontium
  • Sulfate
  • Schwefelsäure 
  • Schwefelwasserstoff
  • Carbonylsulfid
  • Ruß-Aerosole
  • Schwefeldioxid
  • Dimethylsulfit
  • Titan
  • Lithium
  • Lithiumsalze
  • Kohlenstoff Flugasche 
  • Kalkstaub
  • Titandioxid
  • Natriumchlorid
  • Meersalz 
  • Calciumcarbonat
  • Siliciumdioxid
  • Silicium
  • Bismuttriiodid (BiI3
  • Polymere
  • Polymorph von TiO2
  • Dialektrika:
  • Sulfate
  • Halogenide und
  • Kohlenstoffverbindungen
  • Halbleiter:
  • Indiumantimonid (InSb)
  • Bleitellunid (PbTe)
  • Indiumarsen (InAs)
  • Carbonat Aersole
  • Silberjodit, Silberiodit
  • Trockeneis (gefrorenes Kohlendioxid)
  • Hygroskopische Materialien wie Salz,
  • Silanox
  • Cilicagel, Kieselgel
  • Kieselsäure 
  • Syloid65 (Subventionierte Brennstoffmischungen =
  • Chemtrail Chemikalien Mix) aus Patentunterlagen
  • Silberiodit-Kaliumiodit-Komplex
  • Lithium-Silberiodit-Komplex
  • Militär verteilt: Glasfaser-Spreu






Der Wissenschaftler David Keith, der die Geo-Ingenieure Ken Caldeira und Alan Robock in ihrer Arbeit unterstütztsagte auf einem Geo-Engineering - Seminar am 20. Februar 2010, dass sie beschlossen hätten, ihre stratosphärischen Aerosol-Modelle von Schwefel auf Aluminium umzustellen


Niemand auf der ganzen Welt , zumindest keiner der staatlichen Medien berichtete von diesem wichtigen Ereignis.





April 2016 

Aerosol Experiments Using Lithium and Psychoactive Drugs Over Oregon.



SKYGUARDS: Petition an das Europäische Parlament - 2013



Wir haben keine Zeit zu verlieren!




Klage gegen Geo-Engineering und Klimapolitik 


Der Rechtsweg ist vielleicht die einzige Hoffnung, Geo-Engineering-Programme zum Anhalten zu bewegen. Paris und andere Klimaabkommen schaffen Ziele von rechtlich international verbindlichen Vereinbarungen. Wenn sie erfolgreich sind, werden höchstwahrscheinlich SRM-Programme ohne ein ordentliches Gerichtsverfahren legalisiert. Wenn das geschieht, wird das unsere Fähigkeit Geoengineering zu verhindern und jede Form von rechtlichen Maßnahmen zu ergreifen stark behindern.


Ziel dieser Phase ist es, Mittel zu beschaffen um eine US- Klage vorzubereiten. Der Hauptanwalt Wille Tierarzt wählt qualifizierte Juristen aus dem ganzen Land aus, um sicher zu stellen, dass wir Top-Talente sichern, die wir für unser langfristiges Ziel einsetzen.



Die Fakten sind, dass seit einem Jahrzehnt am Himmel illegale Wetter -Änderungs-Programme stattfinden, unter Einsatz des Militärs im Rahmen der NATO, ohne Wissen oder Einwilligung der Bevölkerung..

EU-Konferenz und Petition über Wettermodifizierung und Geoengineering in Verbindung mit HAARP Technologien


Die Zeit ist gekommen. Anonymous wird nicht länger zusehen. Am 23. April werden wir weltweit gegen Chemtrails und Geoengineering friedlich demonstrieren.


Anonymous gegen Geoengineering 



Wir waren die allerletzten Zeit Zeugen eines normalen natürlichen blauen Himmels.





Heute ist der Himmel nicht mehr blau, sondern eher rot oder grau. 



Metapedia –

Die alternative Enzyklopädie




Die neue Enzyklopädie Chemtrails GeoEngineering HAARP






SRM - Geoengineering

Aluminium anstatt Schwefeloxid


Im Zuge der American Association for the Advancement of Science (AAAS) Conference 2010, San Diego am 20. Februar 2010, wurde vom kanadischen Geoingenieur David W. Keith (University of Calgary) vorgeschlagen, Aluminium anstatt Schwefeldioxid zu verwenden. Begründet wurde dieser Vorschlag mit 1) einem 4-fach größeren Strahlungsantrieb 2) einem ca. 16-fach geringeren Gerinnungsfaktor. Derselbe Albedoeffekt könnte so mit viel geringeren Mengen Aluminium, anstatt Schwefel, bewerkstelligt werden. [13]


Mehr Beweise als dieses Video braucht man wohl nicht. >>> Aerosol-Injektionen


Das "Geo-Engineering" Klima-Forschungsprogramm der USA wurde direkt dem Weißen Haus unterstellt,

bzw. dort dem White House Office of Science and Technology Policy (OSTP) zugewiesen. 



Diese Empfehlung lassen bereits das Konfliktpotential dieser GE-Forschung erahnen.






In den USA fällt Geo-Engineering unter Sicherheitspolitik und Verteidigungspolitik: 



Geo-Engineering als Sicherheitspolitische Maßnahme..


Ein Bericht der NASA merkt an, eine Katastrophensituation könnte die Entscheidung über SRM maßgeblich erleichtern, dann würden politische und ökonomische Einwände irrelevant sein. Die Abschirmung von Sonnenlicht durch SRM Maßnahmen wäre dann die letzte Möglichkeit, um einen katastrophalen Klimawandel abzuwenden.


maßgeblich erleichtern..????


Nach einer Katastrophensituation sind diese ohnehin illegalen geheimen militärischen SRM Programme wohl noch leichter durch die Parlamente zu bringen unter dem Vorwand der zivilen GE-Forschung. 




Der US-Geheimdienst CIA finanziert mit 630.000 $ für die Jahre   2013/14 

Geoengineering-Studien. Diese Studie wird u.a. auch von zwei anderen staatlichen Stellen NASA und NOAA finanziert. 




Um möglichst keine Spuren zu hinterlassen.. sind wirklich restlos alle Links im Netz entfernt worden. 






Es existieren viele Vorschläge zur technologischen Umsetzung des stratosphärischen Aerosol- Schildes.


Ein Patent aus dem Jahr 1991 behandelt das Einbringen von Aerosolen in die Stratosphäre

(Chang 1991).


Ein neueres Patent behandelt ein Verfahren, in dem Treibstoffzusätze in Verkehrsflugzeugen zum Ausbringen reflektierender Substanzen genutzt werden sollen (Hucko 2009).




Die von Microsoft finanzierte Firma Intellectual Ventures fördert die Entwick­lung eines „Stratoshield“ genannten Verfahrens, bei dem die Aerosolerzeugung in der Strato­sphäre über einen von einem Ballon getragenen Schlauch vom Erdboden aus bewirkt werden soll.


CE-Technologien wirken entweder symptomatisch oder ursächlich


Symptomatisch wirkend: 

Modifikation durch SRM-Geoengineering- Aerosole in der Stratosphäre


Ursächlich wirkend: 

Reduktion der CO2 Konzentration (CDR) 


Effekte verschiedener Wolkentypen


Dicke, tief hängende Wolken reflektieren das Sonnenlicht besonders gut und beeinflussen kaum die Energie, die von der Erde als langwellige Infrarotstrahlung abgegeben wird. Hohe Wolken sind dagegen kälter und meist dünner. Sie lassen daher mehr Sonnenlicht durch, dafür speichern sie anteilig mehr von der langwelligen, abgestrahlten Erdenergie. Um die Erde abzukühlen, sind daher tiefe Wolken das Ziel der Geoingenieure.



Zirruswolken wirken also generell erwärmend (Lee et al. 2009). Werden diese Wolken künstlich aufgelöst oder verändert, so wird sich in der Regel ein kühlender Effekt ergeben.


Nach einem Vorschlag von Mitchell et al.  (2009) könnte dies durch ein Einsäen von effizienten Eiskeimen bei der Wolkenbildung geschehen.



Eiskeime werden nur in sehr geringer Menge benötigt und könnten beispielsweise durch Verkehrs-Flugzeuge an geeigneten Orten ausgebracht werden. Die benötigten Materialmengen liegen dabei im Bereich von einigen kg pro Flug.



Die RQ-4 Global Hawk fliegt etwa in 20 Kilometer Höhe ohne Pilot.

1 - 1,5  Tonnen Nutzlast.


Instead of visualizing a jet full of people, a jet full of poison.



Das Militär hat bereits mehr Flugzeuge als für dieses Geo-Engineering-Szenario erforderlich wären, hergestellt. Da der Klimawandel eine wichtige Frage der nationalen Sicherheit ist [Schwartz und Randall, 2003], könnte das Militär für die Durchführung dieser Mission mit bestehenden Flugzeugen zu minimalen Zusatzkosten sein.




Die künstliche Klima-Kontrolle durch GE


Dies sind die Ausbringung von Aerosolpartikeln in der Stratosphäre, sowie die Erhöhung der Wolkenhelligkeit in der Troposphäre mithilfe von künstlichen Kondensationskeimen.




Brisanz von Climate Engineering  (DFG)


Climate-Engineering wird bei Klimakonferenzen (z.B. auf dem Weltklimagipfel in Doha) zunehmend diskutiert. Da die Maßnahmen für die angestrebten Klimaziele bisher nicht greifen, wird Climate Engineering als alternative Hilfe in Betracht gezogen.





Umweltaktivistin und Trägerin des alternativen Nobelpreises Dr. Rosalie Bertell, berichtet in Ihrem Buch »Kriegswaffe Planet Erde« über die Folgewirkungen und Auswirkungen diverser (Kriegs-) Waffen..


Bild anklicken
Bild anklicken


Dieses Buch ist ein Muss für jeden Bürger auf diesem Planeten.


..Indessen gehen die Militärs ja selbst gar nicht davon aus, dass es überhaupt einen Klimawandel gibt, wie wir aus Bertell´s Buch wissen (Hamilton in Bertell 2011).


Sondern das, was wir als Klimawandel bezeichnen, sind die Wirkungen der immer mehr zunehmenden


und Eingriffe ins Erdgeschehen mittels Geoengineering, insbesondere durch die HAARP-ähnlichen Anlagen, die es inzwischen in aller Welt gibt..


Bild anklicken
Bild anklicken



Why in the World are they spraying 


Durch die bahnbrechenden Filme von Michael J. Murphy "What in the World Are They Spraying?" und "Why in the world are the Spraying?" wurden Millionen Menschen die Zerstörung durch SRM-Geoengineering-Projekte vor Augen geführt. Seitdem bilden sich weltweit Bewegungen gegen dieses Verbrechen.



Die Facebook Gruppe Global-Skywatch hat weltweit inzwischen schon über 90.000 Mitglieder und es werden immer mehr Menschen, die die Wahrheit erkennen und die "gebetsmühlenartig" verbreiteten Lügengeschichten der Regierung und Behörden in Bezug zur GE-Forschung zu Recht völlig hinterfragen. 


Bild anklicken: Untertitel in deutscher Sprache
Bild anklicken: Untertitel in deutscher Sprache





SRM Programme - Ausbringung durch Flugzeuge 




Die Frage die bleibt, ist die Antwort auf  Stratosphärische Aerosol- Injektions- Programme und die tägliche Umweltzer-störung auf unserem Planeten“




Die Arbeit von Brovkin et al. (2009) zeigt für ein Emissionsszenario ohne Emissionskontrolle, dass der Einsatz von RM für mehrere 1000 Jahre fortgesetzt werden muss, je nachdem wie vollständig der Treibhausgas-induzierte Strahlungsantrieb kompensiert werden soll.




Falls sich die Befürchtung bewahrheitet, dass eine Unterbrechung von RM-Maßnahmen zu abruptem Klimawandel führt, kann sich durch den CE-Einsatz ein Lock-in-Effekt ergeben. Die hohen gesamtwirtschaftlichen Kosten dieses abrupten Klimawandels würden sozusagen eine Weiterführung der RM-Maßnahmen erzwingen.







Neben den Studien von CSEPP (1992) und Robock et al. (2009), ist insbesondere die aktuelle Studie von McClellan et al. (2010) hervorzuheben. Für die Ausbringung mit Flugsystemen wird angenommen, dass das Material mit einer Rate von 0,03 kg/m freigesetzt wird. Es werden Ausbringungshöhen von 13 bis 30 km untersucht.





Bestehende kleine Düsenjäger, wie der F-15C Eagle, sind in der Lage in der unteren Stratosphäre in den Tropen zu fliegen, während in der Arktis größere Flugzeuge wie die KC-135 Stratotanker oder KC-10 Extender in der Lage sind, die gewünschten Höhen zu erreichen.


SRM Protest-Märsche gleichzeitig in circa 150 Städten - weltweit.


Geoengineering-Forschung als Plan B für eine weltweit verfehlte Klimapolik. 


Bild anklicken:
Bild anklicken:


Staaten führen illegale Wetter-Änderungs-Techniken als globales Experiment gegen den Klimawandel durch, geregelt über die UN, ausgeführt durch die NATO, mit militärischen Flugzeugen werden jährlich 10-20 Millionen Tonnen hoch giftiger Substanzen in den Himmel gesprüht..


Giftige Substanzen, wie Aluminium, Barium, Strontium, die unsere Böden verseuchen und die auch auf Dauer den ph-Wert des Bodens deutlich verändern würden. Es sind giftige Substanzen, wie Schwefel, welches die Ozonschicht systematisch zerstören würde. 






Weltweite  Protestmärsche gegen globale Geoengineering Experimente finden am 25. April 2015 in all diesen Städten gleichzeitig statt:




AUSTRALIEN - (Adelaide)

AUSTRALIEN - (Albury-Wodonga)

AUSTRALIEN - (Bendigo)

AUSTRALIEN - (Brisbane)

AUSTRALIEN - (Byron Bay)


AUSTRALIEN - (Canberra)


AUSTRALIEN - (Gold Coast)


AUSTRALIEN - (Melbourne)

AUSTRALIEN - (Newcastle)

AUSTRALIEN - (New South Wales, Byron Bay)


AUSTRALIEN - (Port Macquarie)

AUSTRALIEN - (South Coast NSW)

AUSTRALIEN - (South East Qeensland)

AUSTRALIEN - (Sunshine Coast)


AUSTRALIEN - (Tasmania)

BELGIEN - (Brüssel)

BELGIEN - (Brüssel Group)

BRASILIEN - (Curitiba)

BRASILIEN - (Porto Allegre)


Kanada - Alberta - (Calgary)

Kanada - Alberta - (Edmonton)

Kanada - Alberta - (Fort Saskatchewan)

Kanada - British Columbia - (Vancouver Group)

Kanada - British Columbia - (Victoria)

Kanada - Manitobak - (Winnipeg)

Kanada – Neufundland

Kanada - Ontario - (Barrie)

Kanada - Ontario - (Cambridge)

Kanada - Ontario - (Hamilton)

Kanada - Ontario - (London)

Kanada - Ontario - (Toronto)

Kanada - Ontario  - (Ottawa)

Kanada - Ontario - (Windsor)

Kanada - Québec - (Montreal)

KOLUMBIEN - (Medellin)


KROATIEN - (Zagreb)

DÄNEMARK - (Aalborg)

DÄNEMARK - (Kopenhagen)

DÄNEMARK - (Odense)

ESTLAND - (Tallinn)

Ägypten (Alexandria)

FINNLAND - (Helsinki)




DEUTSCHLAND - (Düsseldorf)




Ungarn (Budapest)

IRLAND - (Cork City)

IRLAND - (Galway)

ITALIEN - (Milano)

Italien - Sardinien - (Cagliari)

MAROKKO - (Rabat)


NIEDERLANDE - (Groningen)

NEUSEELAND - (Auckland)

NEUSEELAND - (Christchurch)

NEUSEELAND - (Hamilton)


NEUSEELAND - (New Plymouth)



NEUSEELAND - (Wellington)

NEUSEELAND - (Whangerei)




PORTUGAL - (Lissabon)

SERBIEN - (Glavni Gradovi)



SPANIEN - (Barcelona)

SPANIEN - (La Coruna)

SPANIEN - (Ibiza)

SPANIEN - (Murcia)

SPANIEN - (San Juan - Alicante)

SCHWEDEN - (Gothenburg)

SCHWEDEN - (Stockholm)

SCHWEIZ - (Bern)

SCHWEIZ - (Genf)

SCHWEIZ - (Zürich)

UK - ENGLAND - (London)

UK - ISLE OF MAN - (Douglas)

UK - Lancashir - (Burnley)

UK - Scotland - (Glasgow)

UK - Cornwall - (Truro)

USA - Alaska - (Anchorage)

USA - Arizona - (Flagstaff)

USA - Arizona - (Tucson)

USA - Arkansas - (Hot Springs)

USA - Kalifornien - (Hemet)

USA - CALIFORINA - (Los Angeles)

USA - Kalifornien - (Redding)

USA - Kalifornien - (Sacramento)

USA - Kalifornien - (San Diego)

USA - Kalifornien - (Santa Cruz)

USA - Kalifornien - (San Francisco)

USA - Kalifornien - Orange County - (Newport Beach)

USA - Colorado - (Denver)

USA - Connecticut - (New Haven)

USA - Florida - (Boca Raton)

USA - Florida - (Cocoa Beach)

USA - Florida - (Miami)

USA - Florida - (Tampa)

USA - Georgia - (Gainesville)

USA - Illinois - (Chicago)

USA - Hawaii - (Maui)

USA - Iowa - (Davenport)

USA - Kentucky - (Louisville)

USA - LOUISIANA - (New Orleans)

USA - Maine - (Auburn)

USA - Maryland - (Easton)

USA - Massachusetts - (Worcester)

USA - Minnesota - (St. Paul)

USA - Missouri - (St. Louis)

USA - Montana - (Missoula)

USA - NEVADA - (Black Rock City)

USA - NEVADA - (Las Vegas)

USA - NEVADA - (Reno)

USA - New Jersey - (Red Bank)

USA - New Mexico (Northern)

USA - NEW YORK - (Ithaca)

USA - NEW YORK - (Long Island)

USA - NEW YORK - (New York City)

USA - NORTH CAROLINA - (Asheville)

USA - NORTH CAROLINA - (Charlotte)

USA - NORTH CAROLINA - (Greensboro)

USA - Oregon - (Ashland)

USA - Oregon - (Portland)

USA - Pennsylvania - (Harrisburg)

USA - Pennsylvania - (Pittsburgh)

USA - Pennsylvania - (West Chester)

USA - Pennsylvania - (Wilkes - Barre)

USA - SOUTH CAROLINA - (Charleston)

USA - Tennessee - (Memphis)

USA - Texas - (Austin)

USA - Texas - (Dallas / Metroplex)

USA - Texas - (Houston)

USA - Texas - (San Antonio)

USA - Vermont - (Burlington)

USA - Virginia - (Richmond)

USA - Virginia - (Virginia Beach)

USA - WASHINGTON - (Seattle)

USA - Wisconsin - (Milwaukee)


Bild anklickem: Holger Strom Webseite
Bild anklickem: Holger Strom Webseite


Der Film zeigt eindrucksvolle Beispiele, beginnend beim Einsatz der Atombomben mit ihren schrecklichen Auswirkungen bis hin zu den gesundheitszerstörenden, ja tödlichen Hinterlassenschaften der Atomenergienutzung durch die Energiewirtschaft. Eine besondere Stärke des Films liegt in den Aussagen zahlreicher, unabhängiger Fachleute. Sie erläutern mit ihrem in Jahrzehnten eigener Forschung und Erfahrung gesammelten Wissen Sachverhalte und Zusammenhänge, welche die Befürworter und Nutznießer der Atomtechnologie in Politik, Wirtschaft und Militärwesen gerne im Verborgenen halten wollen.


Prof. Dr. med. Dr. h. c. Edmund Lengfelder



Nicht viel anders gehen Politiker/ Abgeordnete des Deutschen Bundestages mit der hoch toxischen riskanten SRM Geoengineering-Forschung um, um diese riskante Forschung durch die Parlamente zu bekommen.


Es wird mit gefährlichen Halbwissen und Halbwahrheiten gearbeitet. Sie werden Risiken vertuschen, verdrehen und diese Experimente als das einzig Richtige gegen den drohenden Klimawandel verkaufen. Chemtrails sind Stratosphärische Aerosol Injektionen, die  illegal auf globaler Ebene stattfinden, ohne jeglichen Parlament-Beschluss der beteiligten Regierungen.


Geoengineering-Projekte einmal begonnen, sollen für Jahrtausende fortgeführt werden - ohne Unterbrechung (auch bei finanziellen Engpässen oder sonstigen Unruhen) um nicht einen Umkehreffekt  auszulösen.


Das erzählt Ihnen die Regierung natürlich nicht, um diese illegale hochgefährliche RM Forschung nur ansatzweise durch die Parlamente zu bringen.


Spätestens seit dem Atommüll-Skandal mit dem Forschungs-Projekt ASSE wissen wir Bürger/Innen, wie Politik und Wissenschaft mit Forschungs-Risiken umgehen.. Diese Gefahren und Risiken werden dann den Bürgern einfach verschwiegen. 



Am 30. September 2012 ist eine neue Internetplattform zu Climate Engineering online gegangen  


Die Plattform enthält alle neuen Infos -Publikationen, Veranstaltungen etc. zu Climate-Engineering.





Gezielte Eingriffe in das Klima?

Eine Bestandsaufnahme der Debatte zu Climate Engineering

Kieler Earth Institute



Climate Engineering:

Ethische Aspekte

Karlsruher Institut für Technologie



Climate Engineering:

Chancen und Risiken einer Beeinflussung der Erderwärmung. Naturwissenschaftliche und technische Aspekte

Leibniz-Institut für Troposphärenforschung, Leipzig


Climate Engineering:

Wirtschaftliche Aspekte 

Kiel Earth Institute



Climate Engineering:

Risikowahrnehmung, gesellschaftliche Risikodiskurse und Optionen der Öffentlichkeitsbeteiligung

Dialogik Stuttgart



Climate Engineering:

Instrumente und Institutionen des internationalen Rechts

Universität Trier



Climate Engineering:

Internationale Beziehungen und politische Regulierung

Wissenschaftszentrum Berlin für Sozialforschung




Illegale Atmosphären-Experimente finden in Deutschland  seit  2012 „täglich“ am Himmel statt.


Chemtrails  -  Verschwörung am Himmel ? Wettermanipulation unter den Augen der Öffentlichkeit


Auszug aus dem Buch: 


Ich behaupte, dass in etwa 2 bis 3 mal pro Woche, ungefähr ein halbes Dutzend  von frühmorgens bis spätabends in einer Art und Weise Wien überfliegen, die logisch nicht erklärbar ist. Diese Maschinen führen über dem Stadtgebiet manchmal auffällige Steig- und Sinkflüge durch , sie fliegen Bögen und sie drehen abrupt ab. Und sie hinterlassen überall ihre dauerhaft beständigen Kondensstreifen, welche auch ich Chemtrails nenne. Sie verschleiern an manchen Tagen ganz Wien und rundherum am Horizont ist strahlend blauer ...
Hier in diesem Buch  aus dem Jahr 2005 werden die anfänglichen stratosphärischen SRM-Experimente am Himmel beschrieben... inzwischen fliegen die Chemie-Bomber ja 24 h Nonstop, rund um die Uhr.





Weather Modification Patente


Umfangreiche Liste der Patente











Von Pat Mooney - Er ist Gründer und Geschäftsführer der kanadischen Umweltschutzorganisation ETC Group in Ottawa.


Im Jahr 1975 tat sich der US-Geheimdienst CIA mit Newsweek zusammen und warnte vor globaler Abkühlung. Im selben Jahr wiesen britische Wissenschaftler die Existenz eines Lochs in der Ozonschicht über der Antarktis nach und die UN-Vollversammlung befasste sich mit identischen Anträgen der Sowjetunion und der USA für ein Verbot von Klimamanipulationen, die militärischen Zwecken dienen. Dreißig Jahre später redeten alle - auch der US-Präsident über globale Erwärmung. 


Wissenschaftler warnten, der Temperaturanstieg über dem arktischen Eis  und im sibirischen Permafrost könnte in die Klimakatastrophe führen, und der US-Senat erklärte sich bereit , eine Vorlage zu prüfen, mit der Eingriffe in das Klima erlaubt werden sollten. 


Geo-Engineering ist heute Realität. Seit dem Debakel von Kopenhagen bemüht sich die große Politik zusammen mit ein paar Milliardären verstärkt darum, großtechnische Szenarien zu prüfen und die entsprechenden Experimente durchzuführen.


Seit Anfang 2009 überbieten sich die Medien mit Geschichten über Geoengineering als "Plan B". Wissenschaftliche Institute und Nobelpreisträger legen Berichte und Anträge vor, um die Politik zur Finanzierung von Feldversuchen zu bewegen. Im britischem Parlament wie im US-Kongress haben die Anhörungen schon begonnen. Anfang 2010 berichteten Journalisten, Bill Gates investiere privat in Geoengineering-Forschung und werde bei Geoengineering-Patenten zur Senkung der Meerestemperatur und zur Steuerung von Hurrikanen sogar als Miterfinder genannt. Unterdesssen hat Sir Richard Branson - Gründer und Besitzer der Fluglinie Virgin Air - verkündet, er habe eine Kommandozentrale für den Klimakrieg eingerichtet und sei für alle klimatechnischen Optionen offen. Zuvor hatte er 25 Millionen Dollar für eine Technik ausgesetzt, mit der sich die Stratosphäre reinigen lässt. 


Einige der reichsten Männer der Welt (z.B. Richard Branson und Bill Gates ) und die mächtigsten Konzerne (z.B. Shell , Boeing ) werden immer beteiligt.


Geoengineering Karte - ETC Group


ETC Group veröffentlicht eine Weltkarte über Geoengineering-Experimente, die groß angelegte Manipulation des Klimas unserer Erde.  Zwar gibt es keine vollständige Aufzeichnung von Wetter und Klima-Projekten in Dutzenden von Ländern, diese Karte ist aber der erste Versuch, um den expandierenden Umfang der Forschungs-Experimente zu dokumentieren. 


Fast 300 Geo-Engineering-Projekte / Experimente sind auf der Karte vertreten, die zu den verschiedenen Arten von Klima-Änderungs-Technologien gehören.

Einfach anklicken und vergrößern..
Einfach anklicken und vergrößern..


Aus der Sicht der reichen Länder (und ihrer Unternehmen) erscheint Geoengineering einfach perfekt. Es ist machbar. Es ist (relativ) billig. Und es erlaubt der Industrie, den Umbau unserer Wirtschaft und Produktionsweise für überflüssig zu erklären.


Das wichtigste aber ist: Geoengineering braucht keinerlei internationale Übereinkunft. Länder, Unternehmen, ja sogar superreiche Geo-Piraten können es auf eigene Faust durchziehen. Eine bescheidene >Koalition der Willigen< genügt vollauf, und eine Handvoll Akteure kann den Planeten nach Belieben umbauen.


Damit wir es nicht vergessen:


Seit 1945  führten die USA, die UdSSR, England, Frankreich und später auch China mehr als 2000 Atomtests durch – über und unter der Erde und ohne Rücksicht auf die zu erwartenden Auswirkungen auf Gesundheit und Umwelt weltweit. Niemand wurde um Erlaubnis gefragt. Wenn das Weltklima zu kippen droht, werden sie da wirklich vor einseitigen Entscheidungen zurückschrecken? 




Warum ist Geo-Engineering nicht akzeptabel..?


SRM Geoengineering kann nicht im Labor getestet werden: Es ist keine experimentelle Labor-Phase möglich, um einen spürbaren Einfluss auf das Klima zu haben. Geo-Engineering muss massiv eingesetzt werden.


Experimente oder Feldversuche entsprechen tatsächlich den Einsatz in der realen Welt, da kleine Tests nicht die Daten auf Klimaeffekte liefern.


Auswirkungen für die Menschen und die biologische Vielfalt würden wahrscheinlich sofort massiv und möglicherweise irreversibel sein.





Hände weg von Mutter Erde (HOME) ist eine weltweite Kampagne, um unserem kostbaren Planeten Erde, gegen die Bedrohung durch Geo-Engineering-Experimente zu verteidigen. Gehen Sie mit uns, um eine klare Botschaft an die Geo-Ingenieure und die Regierungen weltweit zu senden, dass unsere Erde kein ein Labor ist.



Liste der (SRM) Geoengineering-Forschung

Hier anklicken:
Hier anklicken: research funding 10-9-13.xls


Weltweite Liste der Geoengineering-Forschung SRM Forschungs Länder: 


Großbritannien, Vereinigte Staaten Amerika, Deutschland, Frankreich, Norwegen, Finnland, Österreich und Japan.



In "NEXT BANG!" beschreibt Pat Money neue Risikotechnologien, die heute von Wissenschaftlern, Politikern und mächtigen Finanziers aktiv für den kommerziellen Einsatz vorbereitet werden:


Geo-Engineering, Nanotechnologie, oder die künstliche >Verbesserung< des menschlichen Körpers.


"Die  Brisanz des Buches liegt darin, dass es zeigt, wie die Technologien, die unsere Zukunft bestimmen könnten, heute zum großflächigen Einsatz vorbereitet werden – und das weitgehend unbemerkt von der Öffentlichkeit. Atomkraft, toxische Chemikalien oder genmanipulierte Organismen konnten deshalb nicht durch demokratische Entscheidungen verhindert werden, weil hinter ihnen bereits eine zu große ökonomische und politische Macht stand, als ihre Risiken vielen Menschen erst bewusst wurden.


Deshalb dürfen wir die Diskussion über Geoengineering, Nanotechnologie, synthetische Biologie  und die anderen neuen Risikotechnologien nicht länger den selbsternannten Experten überlassen. Die Entscheidungen über ihren künftigen Einsatz fallen jetzt - es ist eine Frage der Demokratie, dass wir alle dabei mitreden."


Ole von UexküllDirektor der Right Livelihood Award Foundation, die den Alternativen Nobelpreis vergibt



Vanishing of the Bees - No Bees, No Food !


Verschwinden der Bienen  - Keine Bienen, kein Essen !






Solar Radiation Management = SRM

Es ist zu beachten, dass SRM Maßnahmen zwar auf kurzer Zeitskala wirksam werden können, die Dauer ihres Einsatzes aber an der Lebensdauer des CO-2 gebunden ist, welches mehrere Tausend Jahre beträgt.


CDR- Maßnahmen hingegen müssten über einen sehr langen Zeitraum (viele Jahrzehnte) aufgebaut werden, ihr Einsatz könnte allerdings beendet werden, sobald die CO2 Konzentration wieder auf ein akzeptables Niveau gesenkt ist. Entsprechende Anstrengungen vorausgesetzt, könnte dies bereits nach einigen Hundert Jahren erreicht sein.


CDR Maßnahmen: sind relativ teuer und arbeiten viel zu langsam. Bis sie wirken würden, vergehen viele Jahrzehnte


Solar Radiation Management SRM Maßnahmen: billig.. und schnell..



Quelle: Institut für Technikfolgenabschätzung






Solar Radiation Management = SRM


Ironie der Geoengineering Forschung:


Ein früherer SRM Abbruch hätte einen abrupten sehr heftigen Klimawandel zur Folge, den wir in dieser Schnelligkeit und heftigen Form nie ohne diese SRM Maßnahmen gehabt hätten. 


Das, was Regierungen mit den globalen GEO-ENGINEERING-INTERVENTIONEN verhindern wollten, genau das wären dann die globalen Folgeschäden bei der frühzeitigen Beendigung der SRM Forschungs-Interventionen.


Wenn sie diese hoch giftigen SAI - Programme  aus wichtigen Gründen vorher abbrechen müssten, droht uns ein abrupter Klimawandel, der ohne diese GE-Programme nie dagewesen wäre. 


Das bezeichne ich doch mal  als wahre  reale Satire..