Friday, August 1, 2025

Air Launch to Low Earth Orbit

There is a conundrum associated with launching to low Earth orbit from an airplane.  The illustration tries to sum up the various parts of it.  That is not to say that it cannot be done,  because it already has.  But,  it may,  or may not,  be an attractive way to do the mission.

The first part of this conundrum is the low speed of the launch aircraft (which for the Pegasus system is a wide-body subsonic airliner).  That forces the dropped rocket vehicle to be at least two-stage,  despite the advantage of the low stratospheric launch altitude.  As it says in the illustration,  speed at drop is the biggest influence on the rocket vehicle design,  and altitude the least,  although both are beneficial.  Mach 0.85 at 45,000 feet is but 822 feet/sec (0.25 km/s).  The drag loss of the rocket vehicle is (at least theoretically) less,  because it starts in thinner air up high.

The second part of this conundrum is not so obvious:  the level path angle of the carrier airplane at the drop point.   A low-loss non-lifting ballistic trajectory begun at stratospheric altitude would need a path angle at ignition on the order of 45 degrees,  maybe even a little more.  So,  either the carrier airplane,  or the rocket vehicle,  has to pull up rather sharply,  to reach that path angle from level flight.  One or the other must do this!

The usual airplane flying high in the stratosphere is at or near its “service ceiling”,  where there is barely enough wing lift being produced at an efficient angle of attack,  to hold up the weight,  and essentially all the thrust the airbreathing engines can make is just overcoming drag at the flight speed!  The airplane can neither accelerate path-wise,  nor can it climb!  That is the definition of “service ceiling”,  and for most planes,  it falls in the 45,000-55,000 foot altitude range,  at high subsonic speeds.  There have been exceptions:  the U-2 variants and the SR-71 variants could fly higher,  being very specialized designs.

Left unaddressed in the airplane,  the service ceiling problem puts the sharp pull-up task squarely upon the rocket vehicle to be dropped.  There are only two choices:  put wings on the rocket vehicle,  or fly it at very large angles of attack,  so that the cross-path vector component of its thrust is effectively a large lift force. 

Pegasus used large wings,  on the first stage of a two-stage rocket vehicle.  Those add both weight and drag,  especially drag-due-to-lift at the large lift coefficient needed to pull up sharply.  That pretty-well eats up the advantage gained by launching the rocket at elevated altitude in the thin air.  The wings are bigger than you would want,  precisely because of that thin air!  And that problem is why there have just not been that many Pegasus launches.

Leaving the wings off of the rocket vehicle forces you to pitch it up to very large angles of attack,  in the 45-75-degree range,  to get enough of a cross-path vector component of the rocket thrust,  to serve as the necessary lift force for a sharp pull-up maneuver.  That reduces the path-wise vector component of thrust,  while at the same time greatly increasing vehicle drag.  So,  you accelerate slowly( if at all) in rocket thrust during the pull-up maneuver,  using up a great deal of rocket propellant that adds nothing to your speed.  That also eats up any advantage of launching in the thin air,  way up high!

The only other feasible alternative is to add another large source of thrust to the launch airplane,  so that it can execute the pull-up maneuver into a zoom climb,  without stalling and falling out of the sky,  out-of-control.  Generally speaking,  you would add a source of thrust immune to the service ceiling effect,  and that is rocket thrust!  Your launch airplane would have to be modified for mixed (parallel-burn) rocket and gas turbine propulsion,  somewhat similar to the NF-104 and some of the early high-speed X-planes. 

So far,  no air-launch carrier plane has had this design approach,  but it certainly would be possible!  And it would take care of the high path angle requirement that is second only to speed at launch in importance,  while keeping the wings on the airplane where they belong,  and not on the rocket vehicle!

That leaves speed at launch,  the most important variable affecting the rocket vehicle design.  There are (or have been) very few supersonic aircraft designs that are also large enough to serve as a drop aircraft for a rocket vehicle of any significant size.  Those would include the B-58 Hustler (long-retired,  and none are left),  the SR-71 (also retired,  but very expensive to operate indeed),  and the B-1B bomber (currently in service as a military strategic bomber).  

The modifications to include rocket propulsion to the SR-71 likely would not fit within its very-critical shape.  The M-21 variant that launched the D-21 drone was limited in payload size,  to the size of that drone (not very large).  A rocket might be added in the tail cone of a B-1B,  but its payload would be limited to that which would fit in its bomb bay.  That B-1B option would reach a low supersonic launch speed at the high path angle needed,  with a rather-dangerous zoom climb and recovery after drop.

That brings up the danger of supersonic store separation.  There is a very good reason that most military aircraft,  even those capable of supersonic flight,  are limited to high-subsonic weapon release speeds.  That is because the inherent wobbles of a released store will include pitch-up,  thus developing lift.  At high enough speeds,  that lift generated by the wobbling store will exceed its weight,  and it can easily fly up and collide with the drop aircraft,  before the store’s drag can pull it behind. 

It cost a destroyed airplane and the life of one of the two crew,  to learn this lesson with the M-21 trying to launch a D-21 drone (without a booster) at just about Mach 3.   That is why the drone was re-fitted with a big booster,  and launched subsonically from B-52’s instead.  It’s not that supersonic store separation cannot be done (because that booster separated at Mach 3 from the D-21).  But successful supersonic store separation is very difficult to achieve,  and the risks of doing it are inherently very high.

So how fast a drop speed can be obtained?  That depends upon the gas turbine engines powering the launch aircraft.  Those are seriously limited by the high air temperatures associated with capturing supersonic air.  Most are limited to about Mach 2.5.  There are a very few that went faster:  those powering the XB-70 at Mach 3,  those powering the SR-71 variants at Mach 3.2,  and the 500 hour short-life,  replace-don’t-overhaul engines in the Mig-25 at Mach 3.5.  So,  to have a wide range of possible engines available for new designs,  it looks like Mach 2.5 at drop is “about it” with gas turbine.  Maybe Mach 3.

So,  the answer would seem to be a mixed-propulsion airplane with gas turbine propulsion,  augmented by parallel-burn rocket propulsion,  added to enable the zoom-climb by a sharp pull-up maneuver.  This would be at high altitude near 45,000 feet,  for the drop of the rocket vehicle.  To do this successfully,  the very difficult supersonic store separation problem must be very carefully addressed!  Both aircraft and crews are at serious risk.

Mach 2.5 at that altitude would be 2419 feet/second (0.737 km/s),  less than 10% of low circular orbit speed,  so one is still looking at a two-stage rocket vehicle to reach orbit.  Deliverable payload would be limited in size by the size of the drop aircraft,  since that in turn limits the size of the rocket vehicle it can drop.

In a word,  this has already been done with subsonic carrier aircraft,  although it has proven no more attractive than vertical rocket launch,  at best.  The supersonic release has yet to be tried,  and will prove both difficult and dangerous,  although the improvement in attractiveness may be worth that effort and risk.  No one yet knows. 

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Search code 01082025;  

search keywords:  aerothermo,  airplanes,  launch,  space program  

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Update 8-2-2025:  Please do not misunderstand,  air launch to LEO is possible and in fact has been done more than once!  It's just not easy,  because many of the problems associated with it are hard.  They are hard enough that the attractiveness of this approach is still in question,  relative to the tried-and-true vertical rocket launch. 

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Update 8-4-2025:  For an air launch-to-orbit carrier aircraft,  the gas turbine speed limitation could be gotten around by instead using ramjet propulsion,  which for a true high speed design might reach speeds between Mach 3 and Mach 4 in the stratosphere,  limited mainly by atmospheric drag of something inherently not a “clean” missile shape. 

One would still need the rocket component of a mixed-propulsion parallel-burn scheme to achieve the necessary climb angle at launch of the rocket payload,  and one would still need to solve the dangerous supersonic store separation problem.  But this would get the highest possible speed at launch,  at the right launch angle,  and at an altitude high enough to be beneficial.

The downside is that ramjet has no static thrust!  You will need some sort of booster to reach ramjet takeover speed,  and the necessary high-speed ramjet design is going to have a takeover speed in the Mach 1.8 to 2.5 range.   Given that rocket is needed to reach the high climb angle at launch,  that same rocket is likely the propulsion needed to reach takeover speed. 

Speeds will be limited by the percentage of frontal blockage area occupied by each of the two propulsion systems.  The airbreather is fundamentally lower in frontal thrust density than is the rocket,  so it needs to occupy the larger fraction of the total frontal blockage area. 

Being a lower percentage of vehicle frontal blockage area than the ~100% of a “clean” missile design,  the max possible speed capability of a ramjet (near Mach 6) cannot be reached with this kind of a vehicle.  But the ramjet weighs far less than any possible turbojet propulsion!  That makes a smallish rocket system feasible for getting off the ground with wings,  and reaching Mach 1.8 to 2.5 takeover speed at relatively low altitude. 

From there,  you climb in ramjet to high altitude at speeds near Mach 2.5,  and pull over level to accelerate to top speed in the thin air.  Fire up the rocket to climb steeply for the supersonic store separation,  then shut down the rocket and throttle-back the ramjet to execute a zoom climb and descent back into air dense enough to support controlled flight.  Cruise back in ramjet,  then glide to a landing with the rocket in reserve for go-around capability.

The real trade-off here,  yet to be evaluated,  is whether to integrate the two propulsion systems into some sort of combined-cycle rocket-ramjet,  or leave them as separate systems to be operated entirely separately.  Combined-cycle usually seriously compromises the performance of both components,  while parallel-burn does not,  instead running into the fraction-of-frontal area problem. 

And there is also the problem of there being “no such thing as cooling air” above about Mach 3 to 3.5 in the stratosphere.  Vehicle designs flying faster than that will need one-shot ablatives for their ramjet combustor and nozzle heat protection.  Which means you must swap-out the entire combustor and nozzle unit after every flight!  Given that eventuality,  you could do a solid propellant integral booster in the combustor and nozzle unit,  like a great big JATO motor,  for the initial takeoff.  That reduces the volume (and cross-sectional area) of the on-board propellants for the liquid rockets.  

None of these issues have been resolved for an air launch-to-orbit application. 

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Monday, July 28, 2025

Education Department to be Shuttered by Trump?

I found this on LinkedIn.  It’s too true not to share.  It’s also rather funny,  in a gallows humor sort of way.

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Search code 28072025

Search keywords:  bad government,  idiocy in politics


Saturday, July 26, 2025

Tank Design for Easy Cryogenic Transfers in Weightlessness

I recently came up with a design for a cryogenic propellant tank that makes transfers of propellant easy in weightlessness!  I filed a provisional patent application on it,  with USPTO (the United States Patent and Trademark Office).  A couple of preliminary searches on their site revealed nothing that duplicates it. 

This design is depicted in cartoon form in the illustration.  Is there any outfit out there,  dealing in rocket launch vehicle designs,  that might be interested in such a thing?  If so,  do please contact me!  I would like to license this design to an outfit that might actually use it to good effect!  That would include propellant depot space stations in Earth orbit,  plus the tanker launch vehicles that keep such stations supplied. 

While one motor and a reversing gear is shown,  two motors are also covered in the provisional patent application,  as well as a variety of vane shapes. 

Contact data:

Gary W. Johnson,  PE(ret.),  PhD

5886 New Windsor Parkway

McGregor,  TX  76657 (USA)

Email gwj5886@gmail.com

Blog site http://exrocketman.blogspot.com 


Update 8-1-2025 If anybody at NASA or one of the launch companies wants to use this invention,  do please contact me..  I'd certainly be interested in licensing this notion.  And,  it's not the only skill I bring to the table for launch,  or other kinds of space missions.  While I'm an old retired guy,  I can still consult.  


Friday, July 18, 2025

Why Trump Did Not Want To Release the Epstein Files

Trump has vehemently resisted releasing the Epstein files,  which his cult supporters believed had a client list containing many names of their political opponents.  He has insulted those cult supporters who wanted those files,  and he has lied egregiously about this issue (something verified) multiple times. 

There may,  or may not be,  any sort of “client list” in those legal files.  If there is,  it may or may not have been compiled by Epstein or his people;  it might well have been compiled by the government lawyers.  There are photos documenting that Trump was once a close friend and frequent visitor to Epstein’s haunts. 

One such is shown here,  and it is not a fake or an AI construct,  but it is a real Getty image.   It shows Trump with Melania before they were married,  with Epstein (deceased in jail during Trump’s first term),  and Ghislane Maxwell (Epstein’s girl friend now serving a prison sentence for sex trafficking). 

Why was Trump so desperate not to reveal the Epstein files?  All I can say is what I believe,  without a public admission or (so far) any proof.  In a word,  Trump is on that “client list”,  however it was compiled and whoever compiled it.  He is on the “client list” of a convicted sex trafficker,  including the trafficking of underage girls.  He did not want you to know that!

You Trump cult believers can add that character fault to all the other verified character faults this man has. 


 86 47

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search code 18072025,  search keywords bad government,  idiocy in politics

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Update 7-29-2025:  my wife found this on her Facebook.  It is both too funny and too true,  and fits right in with the original article here.  It essentially summarizes succinctly and accurately all the bluster coming from Trump's mouth about this issue.




Tuesday, July 8, 2025

Oxygenation Issues for Habitats and Space Suits

search code 08072025;  search keywords space program,  spacesuit

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The following is an evaluation of oxygenation issues for space habitations and oxygen suits,  without using any models for in-lung oxygen partial pressure.   Only what is in the breathing gas to be inhaled is considered here!   That way,  the issue is not clouded with the effects of breathing gas displacement by in-lung water vapor,  or by in-lung carbon dioxide,  or by in-lung dead-end volume effects.  Not everyone agrees on the efficacy of those models.

Shown in Figure 1 is a list of selected air pressures versus altitude from a US 1962 Standard Day atmosphere model,  which is identical to the ICAO Standard Day model up to about 65,000 feet.  The breathing gas to be inhaled is either Earthly air at 20.9 volume percent oxygen,  or 100% oxygen in a vented face mask,  with delivery at the altitude’s pressure.  The corresponding oxygen partial pressures were computed and included,  along with a description of the circumstances,  and an indication of the duration of the exposure. 

Figure 1 – Oxygenation Limits Short and Long Term

Partial pressure of oxygen is important,  because it is related to the partial pressure of oxygen in-lung.   The difference between in-lung partial pressure and that in the blood,  is what drives the diffusion of oxygen across the lung membranes into the blood. 

The duration of the exposure is very important to determining what levels of oxygen partial pressure are suitable.  What I tried to identify as short-term criteria relate to the military and civil altitude requirements for going on oxygen in unpressurized airplane cockpits.  Use of such oxygen can be for many hours exposure,  and it makes sure the pilots are fully cognitive,  up to the upper altitude limits for such vented masks.

Those upper altitude limits for vented oxygen face masks are “fuzzy”.  Different people quote different values,  usually close to 40,000 or 45,000 feet.  Below that upper altitude “limit”,  you are “good” for hours.  Above it,  exposure time with high cognition is limited to only minutes or even seconds.  These are typically very short zoom-climb experiences,  peaking at 50-some thousand feet altitude.   One needs a pressure suit to stay up there. 

For long-term criteria,  the experiences of populations living at high elevations are very informative.  There are two things known that are relevant:  chronic hypoxia effects that manifest as “chronic mountain sickness”,  and an increase in pregnancy and birthing difficulties above the low-elevation rates,  presumably also due to chronic hypoxia.  Both start above around 2500 m elevation,  and get worse as elevation increases.  Below 2500 m,  there seem to be no detectable chronic mountain sickness symptoms,  and the rates of difficulties with pregnancy and birthing seem indistinguishable from those at sea level.    

Maximum oxygen partial pressures are limited by enhanced fire dangers above 21 volume percent near sea level,  and seem to be “OK” up to about 0.83 atm partial pressure for several hours flight time,  using the Navy criterion for going on oxygen at 5000 feet.   The ultimate “fatal exposure” limit (1+ atm) derives from experiences with oxygen in diving. 

All of these things are shown in the figure,  and highlighted in different colors.  The overall conclusions I drew from this are in a small table at the bottom of the figure.  I chose partial pressure limits for long-term exposure suitable for habitations,  and short-term exposure limits suitable for hours-long work shifts in pure oxygen space suits.  The space suit criteria further divide into full cognition,  versus mere survival (with presumed cognitive impairment if longer than a few minutes).

Turning to the space suit issueFigure 2 shows the suit pressures in a variety of units of measure,  corresponding to the oxygen partial pressure criteria already identified above,  and also as corrected upward to compensate for a 10% pressure leak-down during a long shift.  These would obtain,  if there were no other effects to consider,  but there are

Experience also shows that breathing oxygen at low pressures causes a loss of water from the tissues in the lungs and respiratory tract.  This drying-out of tissues can cause bleeding,  which is a very serious problem indeed!   

That same experience suggests that there is a minimum suit pressure below which there is a tissue-drying problem,  and above which there is no problem.  This is a bit “fuzzy”,  but the value most quoted is 3.00 psia (corresponding to 0.2041 atm).  This is the value to which the 10% leak-down factor needs to be applied for a higher design suit pressure,  in order to avoid tissue dry-out during a long work shift,  even with leakage.

The result is the final table at the bottom of the figure,  showing the “min suit design” pressure,  the 10% leak-down pressure for long work shifts,  and the short term survival criteria with full cognition,  and with impaired cognition,  after only minutes. 

Figure 2 – Oxygenation Issues for Pure Oxygen Space Suits

Returning to the two-gas mixture habitat atmosphere issue,  we have a good minimum partial pressure criterion for very long-term exposures:  near 0.15 atm,  per the discussion above.  However,  there are three other things to worry about when setting the habitat breathing gas mixture,  presumed to be oxygen and nitrogen.  These are:  (1) a pressure leak-down over time,  to be compensated when detected,  (2) the enhanced fire danger of higher percentage oxygen,  but which is offset by lower total pressures,  and (3) avoiding pre-breathe time,  if possible,  when going from the two-gas mix to the pure oxygen suit.    

I picked the partial pressure of oxygen in the standard atmosphere table at 8200 feet (2500 m) as the “exact” long-term criterion.  That partial pressure of 0.1551 atm is indicated in the first calculation with green highlighting,  near the top of Figure 3.  Just below it,  I ran the compositions of air as it was known in the 1960’s,  air as it is today with increased carbon dioxide,  and a synthetic air (2-gas mix) at the same oxygen content as today’s air.  This includes evaluations of molecular weight,  gas constant,  densities at 1 atm and 59 F (15 C) and also at 1 atm and “room temperature” 77 F (25 C). 

From those densities and the mass fraction of oxygen,  I computed the oxygen concentrations in kg/m3,  at 1 atm and 77 F (25 C) as “room temperature air at sea level”.  That value is 0.2738 kg/m3.  That would be the max oxygen concentration allowable in the habitat breathing gas,  to keep the fire danger as no more hazardous than that of “room temperature sea level air”.   It is based on an overall Arrhenius reaction rate model.

I also checked the oxygen concentration of 40% hospital oxygen at sea level and room temperature,  known to be a severe fire hazard.  It is about twice the concentration of oxygen in ordinary air at sea level and room temperature. That is near the bottom of the figure,  result highlighted in blue.  One would expect those fires to propagate twice as fast.

The habitat atmosphere calculations start with design values for gas composition and total pressure,  and include a leaked-down set of values.  These are on the right of the figure,  with much blue highlighting,  and user inputs highlighted yellow.  Based on prior workI chose to investigate what I call a “rule of 43” 2-gas mix atmosphere of oxygen and nitrogen.  The oxygen is 43 volume percent of the mix (leaving 57% nitrogen),  and the total pressure is 43% of 1 standard atmosphere.  The resulting oxygen partial pressure (0.1849 atm) exceeds the criterion 0.1551 atm,  which is a lower limit,  and the calculated oxygen concentration (0.2418 kg/m3) is less than the criterion value,  which is an upper limit. 

Just above that calculation is an estimate of the minimum suit pressure,  based on the nitrogen partial pressure of 0.2451 atm,  divided by the “no pre-breathe” criterion of factor 1.2.  That produces a 0.2043 atm min suit pressure,  which meets the “no tissue dry-out” criterion of 3 psia,  and also far exceeds the cognition limits.  That would be the minimum suit pressure you can use with no pre-breathe interval to blow off nitrogen:  you can just don the suit and go right out of the airlock.  Any higher suit pressure also qualifies.

Down in the lower right corner of the figure is the habitat leak-down analysis,  set by the min partial pressure of oxygen.  It says we can leak down 19% in pressure at the same oxygen percentage,  and still meet all criteria for safety.  Even the fire danger is OK:  the oxygen concentration reduces as pressure reduces,  depending as it does on density.

Figure 4 below summarizes these results in one place.  The “rule of 43” habitat atmosphere allows the use of rather low-pressure space suits without any pre-breathe requirements,  and provides plenty of leak-down margin,  while at the same time keeping the fire spread danger similar to that in sea level room temperature air.  The recommended suit pressure still meets the 3 psia tissue dry-out criterion as leaked-down 10% after a long work shift.

Figure 3 – Oxygenation Issues for Space Habitats

Figure 4 – Results for Combined Habitats and Space Suits

Final Remarks

There are other habitat 2-gas mixtures and pressures that would qualify.  Not all of these produce space suit designs with min pressures as low as the one found here. 

My selection of the “rule of 43” habitat atmosphere is based on previous work I did trying to meet all these criteria while getting as low a suit pressure as possible.  It is also an easy specification to remember.  Further,  that lowered suit pressure is important for 2 very compelling reasons: 

First,  a higher suit pressure not only is more difficult to design,  it also stiffens like a sports ball at higher pressures,  greatly reducing the mobility available to its wearer. 

Second,  higher suit pressures pretty much rule out suit designs based on mechanical counter-pressure (MCP),  since the materials and design practices for MCP are unavailable in any form that might be donned and doffed with reasonable ease at higher pressures.

References:

All these listed references are prior studies posted at http://exrocketman.blogspot.com.  For rapid access,  there is an archive tool on the left side of that page.  All you need is the posting date and the title.  Click on the year,  then the month,  then the title if need be (such as if other articles were posted that same month). 

1-2-22                  Refining Proposed Suit and Habitat Atmospheres best case and easiest-to-remember cases,  plus an independent estimate of the utter min suit pressures feasible

1-1-22                  Habitat Atmospheres and Long-Term Health adds a long term hypoxia criterion for the habitat in addition to short term criteria for the min-P suit

3-16-18                Suit and Habitat Atmospheres 2018

11-23-17              A Better Version of the MCP Spacesuit?

2-15-16                Suits and Atmospheres for Space

1-15-16                Astronaut Facing Drowning Points Out Need for Better Space Suit

11-17-14              Space Suit and Habitat Atmospheres

2-11-14                On-Orbit Repair and Assembly Facility

12-13-13              Mars Mission Study 2013

1-21-11                Fundamental Design Criteria for Alternative Space Suit Approaches


Sunday, June 29, 2025

Where You Get Your “Facts” Matters!

This is another one I found on LinkedIn that I thought I would post here.  As readers of this blog already know,  I often say “you are entitled to your own opinions,  but you are NOT entitled to your own facts”. 

Most of the totally-unregulated right-wing social media,  many cable television news outlets,  and most infamously on broadcast and cable television Fox News,  are all well-known purveyors of lies and conspiracy theories.  About 30% of which was planted there by the Russians to divide us,  and successfully,  as near as I can tell.  My opinion of the veracity of Fox News has been in the toilet for about 30+ years now.  To me,  they are “Faux News”.

So,  if you who get your “facts” from such sources want to be smarter than most dogs,  please come out of your echo chambers and look around elsewhere!



Wednesday, June 25, 2025

On the new Iran war

Update 7-1-2025:  The Waco "Tribune-Herald" newspaper today published a version of the original article just below,  as a board of contributors opinion piece (I am on that board).  It was hardly edited at all.  The recent update below was not included,  not being in the original submittal as a column.

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Original article written 6-23-2025:

It would seem likely that we are starting down the path to another long Mideast war,  with no clear end in sight,  despite what government officials claim.  Netanyahu started this,  desperately wanting Trump to join in,  despite his campaign pledge not to,  and he did!  Israel did not have the means to hit the deeply buried facilities,  and we did,  which is why this has taken place. 

Iran’s regime is a set of terrorists,  masquerading as religious clerics,  using a private army (the Revolutionary Guard) to stay in power as a dictatorship,  and abusing religion to justify to their captive people the evils they have long done.  They have been sending out terrorist proxy armies to do their dirty work for about 4 decades now.   I think most people would have to agree with that entire assessment. 

There never was any realistic hope of negotiating an end to the Iranian nuclear weapon program,  because we are dealing with terrorists,  not any sort of people who value logic or the safety of their country and its people.  The previous nuclear agreement only slowed their pace,  until Trump abrogated it in his first term. 

It accelerated since then.  They now have a stockpile of reportedly-60% enriched uranium,  which was evacuated from the sites before Trump bombed them! 

So all the pieces for an Iranian atomic bomb are still in place,  despite the bombing,  including the terrorist government so desperate to have those weapons!  Contrary to the claims in the news reports,  you do not have to have 90% enrichment to build an atomic bomb!  Anything over 50% will work! 

Although,  for the same yield,  much smaller devices can be built at 90% than 50%.  This is no secret,  it’s been in public libraries since I first read it there as a young boy,  more than 65 years ago. 

Regime change in Iran was the one and only realistic hope of actually putting a stop to the Iranian atomic bomb!  And now Netanyahu and Trump have made that very much harder to accomplish,  turning the Iranian people against us by bombing their country,  and killing civilians in the process.  Plus,  the regime’s leaders have now gone into hiding,  so that we cannot easily take them out anymore. 

The right way to have done this would have been to support the Iranian people to rise up and do their own regime change from within,  without making enemies of them by bombing their country!  They would just need help overcoming the Revolutionary Guard.  Which without a war going on,  actually could have been done with targeted air strikes.

The Iranian people tried insurrection once before,  during Obama’s administration,  but failed,  because we failed to aid them.  Now,  such a scenario is no longer possible.  The only regime change now possible will have to be imposed from outside,  with boots on the ground,  and against a civil population rallying to defend their government from foreign attackers. 

You can “thank” Netanyahu and Trump for that really ugly prospect!  Although,  “blame” is a better word.

Any child who has passed grade school social studies (taught up to standard,  not just “to the test”) could have predicted some,  or even all,  of this.  But apparently neither Netanyahu nor Trump understood the likely results of their actions,  and apparently they still don’t. 

That conclusion is based on what they have done,  not anything either of them said.  Remember,  you can always tell when a politician is lying:  his lips are moving. 

I think both our countries have the wrong governments.  The Iranians are not the only ones in need of regime change.

Update 6-25-2025:  The cease fire between Iran and Israel seems to be holding,  after some initial violations.  I am surprised but pleased to see it.  It means maybe we have avoided getting into another endless war,  at least for a little while.

Meanwhile,  intelligence reports are still quite sparse,  but some seem to indicate that what I said above is true:  the Iranians managed to move out some of their enriched uranium and related equipment before the attack took place.  That is a thing that President Trump really hates to hear,  because it directly conflicts with his chest-thumping. 

Long term,  do not expect this cease fire to lead to any sort of permanent peace!  You are not dealing with normal political people as Iran’s government.  You are dealing with fanatical terrorists!  They will say anything and do anything,  that lets them continue their evil activities,  including building nuclear weapons.  Their history over the last 4 decades says so. 

The only permanent solution here was,  is,  and always will be,  regime change in Iran!  Unfortunately,  that will henceforth be hellishly difficult,  now that there has been a direct war to alienate the civil population.  Plus,  the ruling mullahs and the Revolutionary Guard private army that keeps them in power,  both survive intact.

Photo from Maxar showing immediately-visible damage: 

Other photos taken a day or two before the strike show a lot of unusual roadway truck activity.  Presumably,  that was truck traffic evacuating the materials and equipment,  anticipating a coming strike. 

Update 6-29-2025 The continuing variance among intelligence reports within and without the government very strongly suggests that the US bombing did great damage to Iran's nuclear weapon efforts,  but did not "obliterate it",  as Trump insists.  In fact,  he gets quite angry with those who disagree with him over this,  clear evidence of his fragile but enormous ego.  

I think the truth lies somewhere in between the extremes of the various assessments,  including ALL of them,  even the first one Trump claimed to be "leaked".  We set them back by somewhere between a few to several (or many) months.  I also rather think that those Maxar photos showing heavy truck traffic at the Fordow site just before the strike,  indicate that the Iranians got at least some of their enriched uranium out,  and hid it elsewhere.  And maybe some centrifuges,  too.

Bear in mind,  please,  that further enrichment beyond their 60% is not necessary to build a workable nuclear weapon,  it's just that the weapon will be very large and heavy,  much like our first generation devices were.  If too heavy for their rockets,  they could always deliver it as a suicide truck bomb.  Think about that!

Regime change in Iran is the only long term solution for this threat,  exactly as I said above in the article!   And Trump and Netanyahu have made that very difficult indeed,  by starting this war,  cease fire or not.  The Iranian people will now tend to rally behind their government against foreign attackers,  despite its brutal history of oppressing them.  That's just human tribal nature.