Andrew Our job was not to "make an economic case [for or] against these technologies", it was just to do transparent evenhanded analysis.
On this topic I just don't have a bias about what the answer is. There are lots of weaknesses in the our study, but I think one of its strengths was that it used a relatively evenhanded treatment as none of the people involved has a particular attachment to or professional involvement in on any outcome. (I suppose you might argue that Aurora has primarily done aircraft, but Aurora now does contract engineering on a wide range of aerospace systems and I do not believe that strongly influence the outcome here. We are working on balloon systems with suspended tethers as part of our development of possible experiments). I think there are lots of very fine contributions in the work coming out of the SPICE group, but I do not think it is unfair to point out that this group is focused on developing a particular technology. In any case, the big answer from this paper and several others are that costs of delivery are small enough that they don't matter in any sensible policy analysis. The goal of our paper was help establish that fact as well as to establish that delivery could be accomplished with technologies that could be procured from multiple vendors today. It is fun to get into playing around with some particular technology to one loves to try and see if you can do the job a little bit cheaper. I have yet to see a coherent quantitative argument why it matters to get costs under the roughly few $/kg level we found here. I would be happy to see a high quality analysis of a novel gun the system that showed that costs were substantially cheaper. But what is needed here is analysis not assertions. Saying that the Novim study "notes the opportunity for substantial costs savings" does not say much. As a contributor on the Novim study, I can tell you we spent far less time analyzing the gun system there and we did in the work Aurora. David -----Original Message----- From: [email protected] [mailto:[email protected]] On Behalf Of Andrew Lockley Sent: Wednesday, September 05, 2012 9:30 AM To: David Keith Cc: geoengineering Subject: Re: [geo] Cost analysis of stratospheric albedo modification delivery systems (ERL) Open Access David Thanks for your reply. For the avoidance of doubt, I was grouping airships and fixed-wing craft as 'aircraft'. I don't doubt that your work in this area was very valuable. My concern is in the comparison of worked-up technology with less well developed technology. For comparison, you can consider the recent Phil Trans A paper by the SPICE team, which considers similar issues. This paper engineers the balloon system preferentially, and thus considers this to be a superior technology due to the cost improvements from this engineering process. The tendency should be clear, but to state explicitly: better worked technologies tend to have better cost profiles. (Paper at http://rsta.royalsocietypublishing.org/content/370/1974/4263.full.pdf ) My fear is that the analysis in your paper suffers this problem particularly as regards gun technology. You consider (briefly) hydrogen guns - but these are not necessary for the altitudes you try to reach. Methane-air or Methane-oxygen is adequate. These do not appear to have been discussed at all. Hydrogen guns do indeed have significant advantages for high altitude or widely-dispersed payloads, as their muzzle velocity is so high. But methane propellant is comparable to the Mk7 charge in terms of performance, and is vastly cheaper. N.B. I've spoken to industry experts too when developing my arguments - most notably Utron. The other major cost in the gun system is the projectile. Blackstock notes the opportunity for substantial costs savings (due to mass production) in the Novim report, and there are additional possibilities for cost-cutting by recovery, such as parachute recovery, splashdown, etc., which can potentially reduce the costs of projectiles by an order of magnitude or more if reuse is practical. Furthermore, guns generally offer substantial performance advantages in terms of their ability to deal with high-altitude dispersal and distribution through problematic weather conditions - something which may severely affect airships particularly. In summary, therefore: the paper is great at bringing forward proposals for optimised aircraft (inc. airships). However, it does not satisfactorily consider other technologies (e.g. guns), and therefore should not be used to make an economic case against these technologies. Thanks A On 5 September 2012 13:56, David Keith <[email protected]> wrote: > Andrew > > > > Answers to your questions about the our recent URL paper on > stratospheric albedo modification delivery systems. > > > > Q: Isn't this just a reformatted version of the Aurora flight report? > > A: Essentially yes. The online supplemental information is the Aurora > report, the paper is newly written but has relatively little view analysis. > The paper puts the report in an archival peer-reviewed journal. We > made minor improvements in response to review but nothing fundamental. > We could have kept the report to ourselves until publication, but > because our views about the importance of openness in this field we > decide to release the entire report when it was completed following our > internal peer-review. > > > > Q: it ignores gas guns (which are half the price in $/kg of > solid-propellant > guns) and contradicts SPICE balloon cost estimates. It works up > aircraft way more than other tech, leading to unsurprisingly lower > cost estimates of these technologies. Coming up with low prices for > worked up tech seems a common thread in papers. > > A: This seems to me a very odd criticism of this paper. Unlike (to my > knowledge) any other paper we examined all the different options in > our scope using the same costing assumptions and industry-standard > cost estimating relationships (CERs). I am not aware that the SPICE > project has done anything similar. > > > > We did not come into it with any particular bias towards airplanes and > in practice we spent a lot of time on hybrid airships and on the > balloon with hose option because analysis there was relatively harder > to do. If you discount the section on existing aircraft which seems > fair since there are no alternative options that are as ready to go, > the section on new aircraft is not substantially longer than the > sections on hybrid airships or the hose option. > > > > Finally it seems like an odd criticism because in fact we found that > the cost of hybrid airships, new aircraft, and the balloon with hose > option were broadly comparable. > > > > gas guns (which are half the price in $/kg of solid-propellant guns) > We did not spend significant time on gas guns because we talked to > David Whelan, US National Academy member and senior scientist at > Boeing, one of the world experts on this topic, and he advised us that > gas guns would not be a significant advantage for the altitude range > that is relevant here. Even if gas guns were half the price of solid > propellant guns as you assert, and I do not know of a study that shows > that to be true when you count capital and operating costs, the cost > would still be absurdly high compared to the other options > investigated (hybrid airships, the balloon with hose, or regular > aircraft) and therefore all but irrelevant. > > > > David > > > > > > -----Original Message----- > From: [email protected] > [mailto:[email protected]] On Behalf Of Andrew Lockley > Sent: Thursday, August 30, 2012 5:52 PM > To: geoengineering; David Keith > Subject: [geo] Cost analysis of stratospheric albedo modification > delivery systems (ERL) Open Access > > > > Poster's note: Isn't this just a reformatted version of the Aurora > flight report? If so, it ignores gas guns (which are half the price > in $/kg of solid-propellant guns) and contradicts SPICE balloon cost > estimates. It works up aircraft way more than other tech, leading to > unsurprisingly lower cost estimates of these technologies. Coming up > with low prices for worked up tech seems a common thread in papers. > > This could be clarified by authors generally, I feel. > > > > http://iopscience.iop.org/1748-9326/7/3/034019 > > > > We perform engineering cost analyses of systems capable of delivering > > 1-5 million metric tonnes (Mt) of albedo modification material to > altitudes of 18-30 km. The goal is to compare a range of delivery > systems evaluated on a consistent cost basis. Cost estimates are > developed with statistical cost estimating relationships based on > historical costs of aerospace development programs and operations > concepts using labor rates appropriate to the operations. We evaluate > existing aircraft cost of acquisition and operations, perform in-depth > new aircraft and airship design studies and cost analyses, and survey > rockets, guns, and suspended gas and slurry pipes, comparing their > costs to those of aircraft and airships. Annual costs for delivery > systems based on new aircraft designs are estimated to be $1-3B to > deliver 1 Mt to 20-30 km or $2-8B to deliver 5 Mt to the same altitude > range. Costs for hybrid airships may be competitive, but their large > surface area complicates operations in high altitude wind shear, and > development costs are more uncertain than those for airplanes. Pipes > suspended by floating platforms provide low recurring costs to pump a > liquid or gas to altitudes as high as ~ 20 km, but the research, > development, testing and evaluation costs of these systems are high > and carry a large uncertainty; the pipe system's high operating > pressures and tensile strength requirements bring the feasibility of > this system into question. The costs for rockets and guns are > significantly higher than those for other systems. We conclude that > > (a) the basic technological capability to deliver material to the > stratosphere at million tonne per year rates exists today, (b) based > on prior literature, a few million tonnes per year would be sufficient > to alter radiative forcing by an amount roughly equivalent to the > growth of anticipated greenhouse gas forcing over the next half > century, and that (c) several different methods could possibly deliver > this quantity for less than $8B per year. We do not address here the > science of aerosols in the stratosphere, nor issues of risk, > effectiveness or governance that will add to the costs of solar > geoengineering. > > > > -- > > You received this message because you are subscribed to the Google > Groups "geoengineering" group. > > To post to this group, send email to [email protected]. > > To unsubscribe from this group, send email to > [email protected]. > > For more options, visit this group at > http://groups.google.com/group/geoengineering?hl=en. > > > > -- > You received this message because you are subscribed to the Google > Groups "geoengineering" group. > To post to this group, send email to [email protected]. > To unsubscribe from this group, send email to > [email protected]. > For more options, visit this group at > http://groups.google.com/group/geoengineering?hl=en. -- You received this message because you are subscribed to the Google Groups "geoengineering" group. To post to this group, send email to [email protected]. To unsubscribe from this group, send email to [email protected]. For more options, visit this group at http://groups.google.com/group/geoengineering?hl=en. -- You received this message because you are subscribed to the Google Groups "geoengineering" group. To post to this group, send email to [email protected]. To unsubscribe from this group, send email to [email protected]. For more options, visit this group at http://groups.google.com/group/geoengineering?hl=en.
