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The XB-70 Was a Mach 3 Bomber with One Mission: Nuclear Bomb Russia

Image: Screenshot from video embedded below.

Sure, over the course of the history of the U.S. Air Force, there have been countless designs of both fighters and bombers that make their way to the drawing board and become demo planes only to be scratched later on. While the XB-70 did not serve in the Air Force, the idea of a fast bomber to nuke Russia is undoubtedly worth a page in history: In the late 1950s, the North American XB-70 Valkyrie looked like it had been ripped straight out of the pages of a science fiction comic book. With a sharp, angular design, six afterburning engines, and the latest targeting, navigation, and electronic warfare systems America could muster, the XB-70 was to become the world’s biggest, fastest, and highest-flying bomber in history… Until it wasn’t.

Today, the Valkyrie serves not just as a reminder, but arguably as the very pinnacle of the Cold War aviation philosophy of circumventing defenses through ever higher and faster platforms. The XB-70, like America’s famed SR-71 Blackbird and its defunct interceptor sister the YF-12, aimed to deliver on both in classic American style: by burning through budgets like jet fuel.

Born on the precipice of the missile age, the Valkyrie may have become America’s go-to nuclear deterrent, had the technology to build it been available just ten years sooner. But time waits for no man nor machine, and the Valkyrie was no exception.

A bomber design so big its fuel tanks were the size of other bombers

The program that was to eventually produce the Air Force’s B-70 supersonic bomber began in the mid-1950s, thanks to rapid advancements in the science surrounding supersonic flight. In an incredible bit of irony, the XB-70 was intended as a replacement for the brand-new-at-the-time B-52 Stratofortress, which despite having incredible range and payload capabilities, was already vulnerable to Soviet intercept fighters by the time it entered service in 1955. Now, nearly seventy years later, the XB-70 is merely one of the many bombers to fail to dethrone America’s mighty BUFF; a list that is soon to include the retiring B-2 Spirit and B-1B Lancer.

At the time, the primary threats a bomber faced during a mission were intercept fighters and anti-aircraft guns, both of which could be mitigated by simply flying higher than they could reach and faster than they could shoot. This approach, while simple in theory, created incredible engineering challenges that would lead to some of the most exotic, dynamic, and capable aircraft ever to take to the skies.

Initial designs for the XB-70 leaned on what engineers called the “brute force concept,” which called for carrying an absolutely massive amount of fuel for a long-duration subsonic flight into Soviet territory and an aerodynamic design that was optimized for high performance during a relatively “short” sprint through enemy airspace. This approach led to absolutely massive concepts that leveraged external fuel tanks that could be jettisoned once they were depleted. These “tip tanks” may have been disposable, but they were neither small nor cheap. As a 1960 Congressional report pointed out, each 191,000-pound tip-tank was approximately the same size as America’s existing B-47 Stratojet long-range bomber.

When presented to legendary Air Force general Curtis LeMay, the man behind America’s B-29 bombing raids in the Pacific Theater of World War II, he dismissed the massive 750,000-pound bomber outright.

“This isn’t an airplane,” LeMay reportedly said, “this is a three-ship formation.”

With orders to go back to the drawing board, North American’s team turned to a recently published paper by Alfred J Eggers and Clarence Syverston from the National Advisory Committee for Aeronautics. The innocuously titled document “Aircraft Configurations Developing High Lift-drag Ratios at High Supersonic Speeds” explained that aircraft that were designed from nose to tail for a single flight condition could dramatically outperform those designed to compromise between both high and low-speed flight. In fact, it went on to prove that aircraft, inlet, and engine designs meant to maintain high supersonic speeds could offer comparable fuel economy to designs meant for subsonic operation.

In other words, the paper offered the startling conclusion that the Valkyrie could reduce its fuel needs by a wide margin by adopting a specifically high-speed design and then simply keeping the pedal to the medal, so to speak.

The XB-70 Valkyrie is born

North American returned with a proposal for a bomber that was designed from the ground up to fly the majority of its missions at Mach 3 and at 70,000 feet (though some sources claim 80,000). In order to achieve and maintain these high speeds, their XB-70 was actually designed to “ride” on the shockwave it produced at supersonic speeds, using a delta-wing, slab-sided fuselage, and a large triangular intake on its belly, positioned well ahead of the bomber’s engines.

This angular intake allowed North American’s designers to intentionally position the high pressure created by the shock wave on the bottom side of the wings. In other words, the XB-70 would surf at Mach 3 on a shock wave of its own creation.

Despite its futuristic aesthetic, this new XB-70 Valkyrie wasn’t too far off in dimensions from the B-52 it intended to replace, at least when compared to the 750,000-pound behemoth originally proposed. It was longer, at 185 feet versus the B-52’s 160 or so feet, and much more narrow, with a wingspan of just 105 feet versus the B-52’s 185. It boasted a nearly 30-foot-long bomb-bay big enough to accommodate any nuclear or conventional weapons in Uncle Sam’s arsenal that was marketed as adaptable to suit Special Electronic Counter Measure (ECM) suites or reconnaissance pods to allow the high-speed bomber to serve in non-kinetic roles.

The bomber was powered by six General Electric YJ93-GE-3 afterburning turbojet engines that were rated at 30,000 pounds of thrust each with their afterburners engaged, though the engines actually produced closer to 29,000. Even if they were a bit over-sold, that still shakes out to more than 174,000 pounds of thrust, which was almost three times that of the brand-new-at-the-time B-58 Hustler, which was the world’s first operational Mach 2 bomber. These engines were lined up on the centerline of the underside of the aircraft, giving it a tail view that now looks almost reminiscent of an Imperial Star Destroyer from the Star Wars franchise, despite being thirty or so years earlier.

The XB-70 was operated by a four-man crew comprised of a pilot (and aircraft commander), co-pilot, bomb and navigation officer, and defensive systems officer. Incredibly, the cabin was designed to provide each crew member with an “encapsulated ejection seat” that would enclose around them to provide pressurized oxygen for the descent from 70,000 feet. This approach wasn’t unheard of, as a similar ejection capsule had already been designed for the B-58.

If the encapsulated seat landed in water, it worked like a boat and even came complete with a radio and fishing equipment. Documents show that the aircraft would also carry 45 pounds of survival equipment, including cold-weather clothing, a hunting rifle, and a week’s worth of rations, for each crew member—though it’s unclear if that was stowed in the ejection seat capsule or not.

This system included a provision for the pilot to remain with the aircraft in a sealed capsule while the other crew members ejected, allowing him to ensure the damaged bomber didn’t careen into populated areas or nearby American forces before ejecting himself.

The fuselage, and in fact most of the aircraft’s external surfaces, were all made using a stainless steel honeycomb-style “sandwich” approach to construction, which offered a great deal of strength and low weight. In a report penned by future president Lyndon B. Johnson and other members of the Senate Preparedness Subcommittee, North American was credited with leveraging lessons learned in development of programs like the the intercontinental supersonic SM-64 Navaho cruise missile and, of course, the hypersonic X-15 research plane in their construction methods. Wherever possible, high-strength titanium alloys were used to further cut down on weight.

The materials used in the Valkyrie’s construction were chosen specifically for their ability to manage the high heat of flight at Mach 3, well above what was commonly known as the “thermal barrier” for aircraft that leveraged aluminum in their fuselage construction. As a result, aluminum-based fighters like many of those employed by the Soviet Union couldn’t be upgraded to close this speed gap, and entirely new platforms would have to be designed.

The Valkyrie’s large delta-wing was paired with forward canards, referred to as horizontal stabilizers in some source materials, which provided lift ahead of the aircraft’s center of gravity and allowed for better trim control and a reduction in trim drag at high supersonic speeds. The canards themselves had flaps, which coupled with using the aircraft’s elevons as flaps and that large delta-wing allowed for lower speeds on take-off and landing than would otherwise be possible with such a design.

Secondary power for the Valkyrie’s onboard subsystems was touted as extremely lightweight and efficient and was described as able to provide “the equivalent horsepower of a modern V-8 engine in one-third the volume and two-thirds the weight.”

Despite the design’s dedication to high speeds, the outer-most portions of its wings, or outer wing panels, were actually hinged to allow for improved subsonic and supersonic flight. The panels would lie flat during take-off and low-speed flight, effectively extending the wing surface and improving the aircraft’s lift to drag ratio. Once the Valkyrie was flying at supersonic speeds, the wingtips would angle down to reduce the wing area behind the bomber’s center of gravity (reducing trim drag) and increase directional stability at high speeds.

Cabin pressurization was achieved by using the immense pressure of the air pouring into the intake during supersonic flight, with an engine-driven compressor assisting as needed to keep the interior feeling like a comfortable 8,000 feet above sea level. This pressurized cabin created what the Air Force referred to as a “tee-shirt” flight environment, which not only made long-duration flights more comfortable but also eliminated the need for special pressure suits like those worn by SR-71 and U-2 pilots. Skipping this time-consuming suit-up step would allow for faster scramble times in the event of a nuclear war.

The Valkyrie leveraged a bombing and navigation system developed by IBM that incorporated gyro-stabilized inertial navigation alongside automatic star-tracking to continuously provide up-to-date information about time and distance to target. A search-radar system with such high definition that its imaging was compared to “taking a photograph” was intended, and the aircraft’s defensive systems operator would be capable of jamming radar frequencies as well as operating conventional countermeasures like flares and chaff.

On paper, the XB-70 would provide the altitude and speed necessary to defeat Soviet defenses, the payload capacity to carry America’s most powerful weapons, and the fuel economy to fly more than 6,000 miles without a top-up. In the age of speed and altitude, the Valkyrie would rule the roost. But unfortunately for this envelope-pushing design, the world was changing quickly around it.

The XB-70 was a cutting edge design that cut the wrong edges

In a lot of ways, the XB-70 promised to be the most advanced and capable bomber ever built, but it came at a time when the very future of bombers was in flux. In 1959, the SM-65 Atlas missile, America’s first operational Intercontinental Ballistic Missile (ICBM), entered service. That same year, testing began on the UGM-27 Polaris missile, America’s first submarine-launched ballistic missile (SLBM). These new weapon systems revolutionized America’s approach to delivering nuclear munitions to far-flung targets. No longer was it necessary to put bomber crews in harm’s way, nor did it seem as appropriate to invest heavily into new bomber designs at the dawn of what many thought would be “the missile age.”

On December 3, 1959—one day after taking office—newly appointed Secretary of Defense Thomas Gates cut the XB-70 program back to a single flyable prototype, bereft of any of the military-specific subsystems it would need to serve as a bomber… but even with the fangs removed from the Valkyrie, the program itself still had quite a bit of fight left in it. Despite this decision, the program was given injections of funds in 1960 and again in 1961.

In 1960, then-senators John F. Kennedy and Lyndon B. Johnson both made public statements in support of the program shortly before winning the year’s presidential election against sitting Vice President Richard Nixon and Henry Cabot Lodge Jr. Johnson even oversaw a 60-page argument in favor the XB-70 from the Preparedness Investigating Subcommittee, writing a full-page letter to open the report calling for it to be restored as a military weapon system. As a bit of historical humor, Johnson cites the B-52’s “obsolescence” as reason for continuing the program (the B-52 is now expected to remain in service beyond the 2040s).

But it wouldn’t be long before both politicians changed their tunes. Just a year later, in 1961, newly elected President Kennedy would give the XB-70 the final ax. The program limped on for eight more years as a technology demonstration effort that would field two prototype aircraft designated XB-70As. One prototype was destroyed after colliding with an F-104 Starfighter during a flying photoshoot in 1966, and the other would find a lasting home at the National Museum of the United States Air Force at Wright Patterson Air Force Base.

But even that still wasn’t the end for the XB-70 Valkyrie. The Air Force and North American would go on to pitch that platform for a wide variety of jobs, including launching and recovering spacecraft in flight, serving as a supersonic refueler, a supersonic personnel transport, and even an ICBM launch platform. None of these efforts, however, we enough to pull the expensive program back off the page and into real production.

Before long, bombers would once again come back into fashion, thanks initially to the fact that they can be recalled once launched, making them a good rapid-response option for early warnings of a potential nuclear threat. As time went on, the benefits of crewed bomber platforms coupled with the advent of stealth would place strategic bombers right back at the top of America’s nuclear strategy heap. But with stealth came a reduced focus on speed and altitude, relegating the XB-70 Valkyrie’s incredible new capabilities to the scrab bin for good.

Today, with hypersonic flight increasingly an area of focus for the United States and its near-peer competitors, it seems likely that we’ll see a resurgence of aircraft that are capable of flying at such blistering speeds. If so, we may yet see some of the lessons learned from the XB-70 program manifest in future bomber platforms. But the Valkyrie itself will always remain another what-if filed away neatly in the bowels of the Pentagon.

Alex Hollings is a writer, dad, and Marine veteran who specializes in foreign policy and defense technology analysis. He holds a master’s degree in Communications from Southern New Hampshire University, as well as a bachelor’s degree in Corporate and Organizational Communications from Framingham State University. This first appeared in Sandboxx News. 

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Sandboxx News is a digital and print military media outlet focused on the lives, experiences, and challenges facing today’s service members and America’s defense apparatus. Built on the simple premise that service members and their supporters need a reliable news outlet free of partisan politics and sensationalism, Sandboxx News delivers stories from around the world and insights into the U.S. Military’s past, present, and future– delivered through the lens of real veterans, service members, military spouses, and professional journalists.