Study Aims, Sources, Method, and Parameters

My aim is not to analyze the contributions to computing and semiconductors of state-embedded industries as a class. Instead, I focus on a single industry: oil. There should be little dispute that oil is a state-embedded industry: The U.S. government has fought wars partially motivated by desire for oil, has fomented revolutions to retain access to oil, has used oil as a diplomatic tool, and has sought to curb other nations’ use of that tool; and its “spymasters” have been “oilmen” and vice versa.Footnote ¹³ More fundamentally, the oil industry’s products suffuse Americans’ understanding of the state and its proper relationship to themselves, the environment, and the marketplace.Footnote ¹⁴

I will show that oil firms rode the state’s coattails and shaped public policy to gain access to advanced computing and semiconductor technologies. In that, the oil industry differs little from the aerospace, automobile, or telecommunications industries; I am not claiming that the oil industry’s contributions were more significant than those industries’ contributions. Still, laying out oil’s role in semiconductors and computing is warranted for at least two reasons. First, oil firms’ contributions are not nearly as well-known as those of the large, regulated monopolies in the northeastern United States, or even those of the auto and aerospace industries. Putting oil at the center of narratives about semiconductors and computing helps us better understand all three industries’ relationships to the state and the ubiquity of oil in U.S. society and especially U.S. technoscience. The semiconductor and computing industries were hardly unusual in enjoying oil patronage; fields including biotechnology, solar and nuclear power, and medicine have as well.Footnote ¹⁵ This study is part of a larger project documenting “oil spillovers” to various sciences and technologies. Obviously, “oil spillover” is a pun; however, I am serious in translating the concept of spillovers into business history from the social sciences.Footnote ¹⁶

Second, in tracing oil spillovers, this article exposes an underappreciated obstacle to technological solutions to climate change. I thereby add to the recent material and environmental turns in histories of semiconductors and computing.Footnote ¹⁷ That literature argues—contrary to popular understandings promoted by industry—that computing and semiconductor manufacturing are carbon-intensive and environmentally ruinous. This article further asserts that computing and semiconductor manufacturing just are, in part, arms of the fossil fuel industry, and Silicon Valley is an “energy capital” not unlike Dallas and Houston.Footnote ¹⁸ A better picture of the historical oil-computing nexus draws attention to tech firms’ present-day alliances with oil (and opposition to state action against climate change) and undermines optimism that information technologies will facilitate a future low-carbon transition.Footnote ¹⁹

Before moving to my empirical material, some notes on scope, periodization, and sources. By the “oil industry,” I mean oil producers, both large and small, as well as oil field services firms; I only include petrochemical manufacturers if they also owned substantial oil production or refining units. I focus on firms headquartered in the United States or Western Europe, during the Cold War period when those firms’ influence was at its peak. Links between oil and computing are hard to find before the Cold War, and somewhat submerged again after 1989 (though in my “Conclusion” I note some present-day connections between oil and Big Tech).

My argument is that oil firms participated in every major turn in the development of U.S. semiconductor manufacturing and computing during the Cold War. This is counterintuitive, because the oil “industry has a reputation for being slow to develop and adapt innovations”—a reputation confirmed by oil firms’ relatively small (“less than 1% of their net revenue”) investments in R&D.Footnote ²⁰ Yet the oil industry is so large that small investments relative to its revenues can have enormous consequences for nascent firms and technologies. Moreover, the oil industry’s influence should not only be counted in dollars, but also in personnel, techniques, ideas, and institutions. To trace those strands of influence, I adopted the “follow the actors” research strategy associated with Bruno Latour and actor-network theory: I first identified networks that were clearly associated with either oil actors or the semiconductor and computing industries and then collected instances of overlap between the two networks.Footnote ²¹

I begin building my argument somewhat obliquely: first by offering a skeleton history of the U.S. semiconductor and computing industries, told in the conventional way without oil; after which I reinsert oil actors into that narrative. The conventional narrative that I offer does not encompass all work on the history of the U.S. computing and semiconductor industries, but it adequately summarizes surveys of that history such as Martin Campbell-Kelly and colleagues’ Computer, Paul Ceruzzi’s A History of Modern Computing, Alfred Chandler’s Inventing the Electronic Century, Thomas Haigh’s “The History of Information Technology,” and James Cortada’s “Progenitors of the Information Age.”Footnote ²² The same storyline also structures popular documentaries and fictionalizations.Footnote ²³

The device of starting with the conventional narrative and then filling in its gaps is taken from Davis Baird and Ashley Shew’s study of participant histories of nanotechnology.Footnote ²⁴ The point is to show where particular actors could fit in predominant narratives but have not done so thus far. Putting those actors into the storyline makes evident the work and assumptions required to maintain their invisibility. This approach is not dissimilar to studies that illuminate minoritized and subaltern groups’ contributions to computing.Footnote ²⁵ Of course, the oil industry is hardly subaltern; bringing its contributions to light serves critique, not empowerment. Indeed, oil firms have themselves occluded their roles in semiconductors and computing. To counter critique and legal challenges, oil firms have been highly selective in making their strategies publicly transparent. Thus, I rely largely on published sources that present the oil industry’s own perspective—sources that I nevertheless read in ways oil actors did not intend.

The Established Narrative

I begin in 1947. There is, of course, an earlier history of computing, but I have not found exceptional oil industry involvement with calculating machines or human computing before the end of World War II. Such activity might turn up but would not alter my argument. There was, moreover, no semiconductor industry before 1947, as that year saw the invention of the transistor, the first solid-state semiconductor device to (eventually) be sold commercially. Virtually every popular and academic survey notes the invention of the transistor as a turning point, not just for what became the semiconductor industry, but also for computing and other U.S. high-tech industries, particularly in the San Francisco Bay Area.

The invention of the transistor, a solid-state amplifier and switch, was credited by their employer, Bell Laboratories, to William Shockley, John Bardeen, and Walter Brattain. A chemist, Gordon Teal, also contributed crucial crystal-growing knowledge.Footnote ²⁶ Shockley then left Bell Labs in 1956 to form Shockley Semiconductor, a subsidiary of Beckman Instruments, in Palo Alto.Footnote ²⁷ That venture gave rise to a more influential breakaway, Fairchild Semiconductor.Footnote ²⁸ In 1958–1959, the integrated circuit was simultaneously invented at Fairchild and at Texas Instruments (TI), instigated by the military’s need for more reliable transistors.Footnote ²⁹ Crucially, the transistors and other components in integrated circuits could be miniaturized, making electronic devices faster and less power-intensive; the steady shrinking of integrated circuitry since the early 1960s is now known as Moore’s law, after a Fairchild cofounder.Footnote ³⁰ Miniaturization radically decreased the unit price of transistors; however, extreme miniaturization also required more expensive semiconductor manufacturing facilities (“fabs”). Over time, that expense became prohibitive; since the 1990s, firms have abandoned their fabs and outsourced manufacturing to “foundries,” particularly the Taiwan Semiconductor Manufacturing Company (TSMC).Footnote ³¹

Semiconductor manufacturing quickly diffused from Bell Labs after 1947. East Coast conglomerates such as RCA and IBM were early leaders, soon joined by firms like TI and Motorola in the Southwest and spin-offs from Fairchild in the Bay Area such as Signetics and Rheem.Footnote ³² These “Fairchildren” sprouted thanks to the venture capital (VC) industry in what became known as Silicon Valley. VC money also meant that region’s semiconductor firms were later joined by industrial clusters in biotech, personal computing, networking, dot-commerce, and social media.Footnote ³³

By the early 1970s, miniaturization and integration of semiconductor components made a “computer on a chip,” or microprocessor, feasible—a device first marketed by one of the leading Fairchildren, Intel.Footnote ³⁴ Combining many components on one chip in turn made smaller, “personal” computers commercially viable. Such machines had long been forecast, particularly in circles in which the counterculture and military–industrial complex intersected. One such circle connected the Stanford Research Institute (SRI), Portola Institute, and Xerox’s Palo Alto Research Center, yielding (among other things) the Xerox Alto, a graphical user interface–based computer that influenced the Apple Macintosh, Microsoft Windows, and billions of similar devices used today.Footnote ³⁵

Members of the same circles were also involved with the ARPANET and early networking technologies. In the 1980s, civilian networks proliferated alongside the ARPANET, such as the NSFNET connecting academic supercomputing centers.Footnote ³⁶ The growth of such networks was aided by the dissolution of AT&T’s monopoly in 1984. This resulted in competition among telecommunications companies such as Sprint and Ericsson to lay fiber-optic cable and establish cellular networks.Footnote ³⁷ These developments stimulated the privatization of the internet in 1995 and the dot-commerce boom.

Meanwhile, miniaturization of semiconductor components continued thanks to advances such as atomic layer deposition and FinFET transistors.Footnote ³⁸ Putting those advances to use in laptops and cellphones, however, required parallel advances in power storage, particularly the lithium ion battery. By the twenty-first century, miniaturization made distributed storage fantastically cheap and processing fantastically fast. In the 2010s, these developments combined with progress in artificial intelligence (AI) research to place technologies such as self-driving cars and ubiquitous surveillance within reach.Footnote ³⁹

Replaying in the Key of Oil

The sources cited in my summary of the established narrative contain barely a handful of passing references to oil. Almost the only survey that meaningfully acknowledges oil firms’ place in the history of computing is in the first volume of Cortada’s The Digital Hand, in a single chapter on the petrochemical industry.Footnote ⁴⁰ Yet there are oil links to every single turn in the narrative presented above. That is not to say that oil conspiratorially lurked behind computing, nor that oil interests determined the events I have just sketched. Rather, I offer the more limited claim that oil actors participated in the U.S. semiconductor and computing industries far more than the conventional narrative acknowledges.

To some degree, that claim should not be surprising; oil was ubiquitous in American postwar society generally and in business in particular. A trivial example of that ubiquity comes from one of the earliest Fairchildren, Signetics, which had a former president of Standard Oil of California, Theodore Peterson, on its first board of directors.Footnote ⁴¹ Peterson only offered generic management expertise and did not steer Signetics in any oil-specific direction. Singly, such ties tell us little about oil or computing. Collectively, however, the links I describe were not trivial. The oil and semiconductor–computing industries formed a symbiotic relationship that gave them their present forms. To convey that symbiosis, I revisit the established narrative, this time highlighting oil actors’ presence. Then I will explain why oil firms took an interest in semiconductors and computing and what that means for the historiographies of all three industries.

Let us start, again, with the transistor. All the people I mentioned in connection with that invention were tied to oil. John Bardeen worked at Gulf Oil’s Pittsburgh research lab for several years before starting his PhD at Princeton.Footnote ⁴² While at Princeton, Bardeen became friends with another PhD student, Robert Brattain, who introduced Bardeen to his brother Walter (Bardeen’s future collaborator and Nobel co-laureate). Robert Brattain became one of Shell’s top scientists and developed a prototype of the IR-1 infrared spectrophotometer that Shell commissioned Arnold Beckman to produce commercially.Footnote ⁴³ This stimulated the postwar “instrumental revolution,” reorienting chemistry to physical, and specifically electronic, instrumentation.Footnote ⁴⁴ The money Beckman made from that revolution allowed him to hire William Shockley and form Shockley Semiconductor.Footnote ⁴⁵

Another firm often said to have established the Silicon Valley business model, Varian Associates, also depended heavily on selling spectrometers to oil and petrochemical companies.Footnote ⁴⁶ Yet another California firm founded to sell spectrometers for oil exploration, Consolidated Engineering Corporation, developed an early commercial computer, the CEC 30-103, before selling its computing unit to Burroughs. Renamed the Datatron 203, this became the basis for Burroughs’ successful entry into computing; ex-Shell employees were also responsible for Burroughs’ widely used version of Algol.Footnote ⁴⁷ As David Brock has shown, the early history of semiconductor manufacturing, too, owed much to cooperation between oil firms and instrumentation companies, particularly in California.Footnote ⁴⁸

Finally, the fourth transistor team member, Gordon Teal, left Bell Labs in 1953 to join TI. By that time, TI was largely focused on defense markets, but the company’s original incarnation, Geophysical Service Incorporated (GSI), was an oil field services firm. After the company was renamed in 1951, GSI continued until 1988 as its oil field services subsidiary. TI was the number one global semiconductor manufacturer of the 1970s and in the top four well into the 1990s; yet despite TI’s importance, semiconductor historians have written almost nothing about the decades-long coexistence of TI’s microelectronics and oil field services units.Footnote ⁴⁹

Clearly, though, oil field services offered an important early market for TI’s microelectronics branch. For instance, in 1962 GSI rolled out the 15000-transistor Texas Instruments Automatic Computer (TIAC), intended primarily for seismic analysis and made possible by funding from Mobil and Texaco.Footnote ⁵⁰ The TIAC later gave rise to “the TIAC 870, one of the first integrated-circuit computers,” and then in the early 1970s the Advanced Scientific Computer, developed with support from Chevron, Amoco, Texaco, Mobil, Phillips, and Unocal.Footnote ⁵¹

Knowledge, technology, and personnel also flowed from TI’s oil operations into microelectronics. One example is digital signal processing (DSP) and TI’s most famous consumer product, the Speak & Spell. Academic and participant histories of Speak & Spell do not draw a link to GSI, but plainly the oil industry was tremendously important in the development of the DSP chips that went into it.Footnote ⁵² Signal processing of seismic data was an early application of digital computers going back at least to MIT’s Whirlwind computer (one of the first real-time digital electronic computers). Historians of computing have depicted Whirlwind as a creature of the military.Footnote ⁵³ However, students in MIT’s Geophysical Analysis Group were coopting Whirlwind for seismic analysis, with funding from oil firms Magnolia, Stanolind, and Atlantic Richfield, by 1952 (a few months after Whirlwind became operational).Footnote ⁵⁴ Other oil companies, such as Shell, keenly followed the Whirlwind work.Footnote ⁵⁵

The deconvolution methods developed on Whirlwind soon became standard in oil prospecting.Footnote ⁵⁶ By the early 1970s, those techniques were good enough that some researchers leapt from processing seismic signals to processing (roughly similar) acoustic signals, that is, voice and music. One was John Burg, the son of Kenneth Burg, an early and influential employee of GSI. John Burg developed “the maximum entropy spectrum [as] an outgrowth of the deconvolution filtering technique long used in oil-exploration data processing” while he—following his father—was employed by TI in the early 1960s.Footnote ⁵⁷ Burg later founded TSP (Time and Space Processing), where he applied the maximum entropy spectrum method to voice transmission over digital networks, primarily for military customers. Through Burg himself and colleagues in ARPANET circles, digital voice processing techniques then flowed back to the TI group that developed Speak & Spell.Footnote ⁵⁸

TI’s microelectronics business was also aided by Texas elites’ desire to diversify the region’s economy to buffer periodic oil downturns. Indeed, Texas elites even backstopped risky gambles such as the Graduate Center of the Southwest, which TI established in 1961 to train future employees. When the Graduate Center began hemorrhaging money, the Texas state government (at the behest of oil and other business elites) took it off TI’s hands and transformed it into the University of Texas–Dallas.Footnote ⁵⁹

A more frustrated case involved Jack Kilby, famous as coinventor of the integrated circuit. Less well-known is Kilby’s work in the 1970s on the TI Solar Energy System (TISES).Footnote ⁶⁰ This was a residential system for generating heat and electricity, which Kilby and another former TI employee, Jay Lathrop, invented in response to the 1973 OAPEC oil embargo. In the late 1970s, TI and the Department of Energy jointly invested more than US$(2022)100 million in TISES.

In 1980, though, the price of oil started to drop, making the economics of TISES less favorable. At that point, TI and Kilby sought investors to help them start up and sustain manufacturing until economies of scale kicked in. They concluded that the only viable sources of that level of investment were oil companies and Saudi princes.Footnote ⁶¹ This was less counterintuitive than it seems now, because most major oil companies had solar energy programs at the time and the Saudi royal family splashily sponsored various solar power experiments.Footnote ⁶² Oil money was not forthcoming for TISES, however, and TI’s attempt to move from semiconductors into solar—inspired by the scarcity of, and with the hoped-for aid of, oil—was canceled in 1983.

Fairchildren and Angels

So far, I have shown that the oil industry multiply intersected with the invention of the transistor, diffusion of transistor manufacturing to Texas and Silicon Valley, and the invention of the integrated circuit. I have also shown that oil firms were crucial early consumers of discrete transistors (in instrumentation for petrochemical manufacturing and oil exploration) and of digital computers and integrated circuits (in digital analysis of seismic signals). The next turn in the conventional narrative, then, is the VC industry and Silicon Valley’s start-up culture. There, too, oil was everywhere.

An early example is Dean Knapic, a Shockley Semiconductor employee who carpooled with two of Fairchild Semiconductor’s future cofounders.Footnote ⁶³ In 1957, Knapic also left Shockley to form a company to sell silicon to spec. Knapic’s seed money came from Norsworthy Industries, the investment vehicle of a Dallas oilman, Lamar Norsworthy Jr.Footnote ⁶⁴ Despite the company’s rapid growth, Norsworthy withdrew after three years and Knapic folded, ceding the silicon market in part to companies with oil ties, particularly Monsanto. One of Knapic’s employees, Robert Lorenzini, later founded silicon suppliers Elmat and Siltec.Footnote ⁶⁵ Another, Arthur del Prado, formed ASM International, today one of the world’s leading semiconductor process equipment suppliers.Footnote ⁶⁶ Norsworthy’s investment thus stimulated the emergence and globalization of Silicon Valley start-up culture.

More broadly, oil firms and actors have been crucial players throughout the history of VC. Most histories credit Georges Doriot with founding the East Coast VC industry, and Eugene Kleiner and Arthur Rock the West Coast variant.Footnote ⁶⁷ However, Martin Kenney and David Hsu have shown that Rockefeller Brothers was equally important in establishing the industry’s practices.Footnote ⁶⁸ Rockefeller Brothers (Venrock after 1969), was a vehicle for the Rockefeller siblings to invest money inherited from their grandfather, John D. Rockefeller, founder of Standard Oil. Among Venrock’s investments were Intel, Apple, and Mosaic. (Another major early investor in Intel was Gordon Moore’s financial adviser, Fayez Sarofim, who made his pre-Intel fortune investing for Houston’s oil barons.Footnote ⁶⁹)

Doriot himself put money into oil companies, including George H. W. Bush’s Zapata Oil.Footnote ⁷⁰ He also relied on advice from “his former student and family friend Arnaud de Vitry,” head of Mobil’s operations research unit.Footnote ⁷¹ In 1957, de Vitry counseled Doriot to make his most famous and successful investment in Digital Equipment Corporation. In the end, though, Doriot was outrun by VC firms that adopted the limited partnership legal template—which was invented by oil wildcatters to collectively share the risk (and profit) from drilling oil wells.Footnote ⁷² Only in 1959 was the limited partnership imported by “the first venture capital firm in Silicon Valley: Draper, Gaither & Anderson.”Footnote ⁷³

As the VC industry matured, oil companies themselves joined in. The leader, founded in 1964, was Exxon Enterprises, which took stakes in (among others) nuclear power, solar energy, and even sporting equipment.Footnote ⁷⁴ Its best-known investment was probably Zilog, one of the most promising semiconductor start-ups of the 1970s. Zilog was founded by Fairchild and Intel veterans, including Federico Faggin, coinventor of the microprocessor.Footnote ⁷⁵ Alongside Zilog, Exxon bought into semiconductors (Supertex), superconductors (Intermagnetics General), word processing (Vydec, Xonex), optical scanning (Scantron), displays (Ramtek, Kylex, EPID), fax machines (Qwip), printers (Qume, Danbury Systems), typewriters (Qyx), digital voice storage and transmission (Delphi Communications), photodiodes (Emdex), semiconductor lasers (Optical Information Services), memory (Micro-Bit, Exxon STAR Systems), voice recognition and synthesis (Dialog [renamed Verbex Voice Systems], Periphonics), office telephony (Intecom), and disk drive heads (Magnex).Footnote ⁷⁶

In the early 1980s, Exxon packaged these companies’ products into an office information suite built around a computer powered by a Zilog chip.Footnote ⁷⁷ In 1984, it abandoned the effort, leaving the associated firms and personnel to seek their fortunes elsewhere. Some, such as James and Janet Baker of Verbex Voice, had more success post-Exxon: elements of their Dragon Naturally Speaking software are today embedded in Apple’s and Microsoft’s voice recognition packages.Footnote ⁷⁸ In addition, Exxon Enterprises itself trained a few influential venture capitalists.Footnote ⁷⁹

Where Exxon leads, other oil companies follow. BP, for instance, had both BP Ventures and a venture research unit that offered grants to, among others, the prominent computer scientist Edsger Dijkstra.Footnote ⁸⁰ (It is probably a coincidence, though worth noting, that Dijkstra held the Schlumberger Centennial Chair in Computer Science at the University of Texas from 1980 to 1999; Schlumberger is an oil field services firm.) In 1979, Texaco founded Harrison Capital, while in 1980 Standard Oil of Ohio formed Vista Ventures (explicitly modeled on Exxon Enterprises).Footnote ⁸¹ Vista “invested about $20 million, primarily in computer companies, including Fortune Systems… [While] about 50% of Harrison’s investments [were] in computer companies, including Iomega … and Micro-Five.”Footnote ⁸² Atlantic Richfield’s ARCO Ventures was mostly focused on solar and biotech but also funded signal processing research at Stanford’s Ginzton Lab in the early 1980s.Footnote ⁸³

Amoco Technology similarly mainly invested in solar but made bets in computing, including acquiring Stanford AI researcher Ed Feigenbaum’s company, Intelligenetics, in 1986.Footnote ⁸⁴ Amoco Technology also bought 15 percent of chip manufacturer Analog Devices in 1977 and then formed a joint investment venture, Analog Devices Enterprises (ADE), in 1980.Footnote ⁸⁵ ADE put money into computing-related companies such as Signal Processing Circuits, International Imaging Systems, Charles River Data Systems, Numerix, Photodyne, GigaBit Logic, Quantitative Technology Corp, TestSystems, Bipolar Integrated Technology, Imagerie Industrie Systeme, and Altera.Footnote ⁸⁶

Spillovers Beyond Money

Oil firms’ contributions to computing and semiconductor manufacturing were not, however, limited to investment. Their in-house capabilities, too, spilled over to other industries. For instance, in the mid-1970s, Sun Oil established Sun Information Services (SIS) to handle its data processing.Footnote ⁸⁷ SIS then attracted interest from external clients interested in data backup for disaster recovery. In 1983, Sun spun off SIS and four other computing subsidiaries (SunGard Services, Applied Financial Systems, Catallactics Corporation, and NMF Inc.) to form SunGard, one of the top data backup and disaster recovery firms until the 2010s.Footnote ⁸⁸

Sometimes, capabilities developed for one purpose unexpectedly spilled into computing. For instance, Exxon’s formation of an Advanced Battery Division in the late 1970s was originally intended to help it get into “batteries to power electric vehicles.”Footnote ⁸⁹ Yet, as Matthew Eisler documents, Exxon’s contributions to lithium ion batteries, along with parallel contributions by Atlantic Richfield and Schlumberger, instead made possible today’s mobile phones and portable computers.Footnote ⁹⁰

In semiconductor manufacturing, oil firms’ materials expertise plugged directly in rather than spilling over. The chemicals used in semiconductor processing include various petrochemicals, especially photoresists used in lithography, sold by chemical suppliers such as Rohm & Haas and KMG Chemicals. Historically, chip-grade silicon was a specialty chemicals market too: as Monsanto’s president put it in 1983, “Monsanto is the world’s largest producer and marketer of polished silicon wafers. We have been an active member of the semiconductor industry for the past 24 years.”Footnote ⁹¹ Note that, from 1955 to 1975, Monsanto also operated an oil refinery and gas station chain.

Oil firms also offered challenging organizational environments where advances in computing could be refined. ARCO headquarters, for instance, was one of four locations where the Xerox Alto was field-tested in 1978 (alongside Xerox, the White House, and the U.S. House of Representatives).Footnote ⁹² Thus, firms involved in complex oil exploration and production projects have led development of advanced database systems, such as Stone & Webster’s Construction Management Display System and the Amoco Distributed Database System.Footnote ⁹³

The physical environments across which oil firms operate also stimulated innovation. Oil companies were, for instance, among the first customers for GPS technology.Footnote ⁹⁴ Likewise, the rancher and oilman Thomas Carter invented the Carterfone, an attachment for connecting a two-way radio to a telephone, for users working far from telephone lines. AT&T’s opposition to Carter, and the FCC’s landmark 1968 decision backing him, accelerated AT&T’s breakup and fostered “the motley world of funny receivers, slick switch boxes, and rickety answering machines. More importantly, [because of the Carterfone decision] consumers quickly embraced the modulate/demodulate device, otherwise known as the telephone modem.”Footnote ⁹⁵

At times, the combination of oil’s geography and materiality plus oil firms’ complexity inspired developments in computing and especially networking. ARPANET’s topology, for instance, was partly derived from earlier studies of offshore oil and gas pipeline networks.Footnote ⁹⁶ Much later, Amoco “led a group of 20 network companies and government agencies” as well as Chevron, Shell, and Schlumberger (and the American Petroleum Institute) in the ARIES project in the early 1990s. This was an influential pilot of asynchronous transfer mode network protocols for moving data from remote locations (such as oil platforms) to central facilities where the data could be interpreted.Footnote ⁹⁷

A particularly convoluted example is the U.S. arm of Swedish telecommunications giant Ericsson. Despite benefiting greatly from AT&T’s breakup in 1984, Ericsson had virtually no presence in the United States before 1980, when it formed a joint venture, Anaconda-Ericsson, with Atlantic Richfield (a collaboration arising from the two companies’ Mexican subsidiaries).Footnote ⁹⁸ Atlantic Richfield’s contribution was a subsidiary called Anaconda Telecommunications, a spin-off from Anaconda Wire and Cable. Wire and cable are critical material infrastructure for telecommunications, but also lucrative markets for copper companies such as the giant mining conglomerate, Anaconda Copper, which ARCO had taken over in 1977.Footnote ⁹⁹

As the maze of subsidiaries in the Anaconda–Ericsson episode indicates, oil firms dabbled in many non-oil industries, particularly in the 1970s. Thus, the standard explanation for oil firms’ computing ventures is that they were “part of a diversification effort” (as Bo Lojek dismissively described Schlumberger’s 1979 purchase of Fairchild).Footnote ¹⁰⁰ Yet just because a business appears (especially retrospectively) unrelated to oil production does not mean that an oil company invested in it solely to diversify its portfolio. And even where diversification strategies were at work, we have to ask why oil companies diversified in some directions and not others.

Schlumberger, for instance, bought Fairchild for specific reasons: “Schlumberger used computerized tools for measurement and oil research and, therefore, required increasing amounts of semiconductor components.”Footnote ¹⁰¹ Purchasing Fairchild also gave Schlumberger an umbrella under which to place related acquisitions such as Accutest, a semiconductor test equipment manufacturer.Footnote ¹⁰² Perhaps most importantly, Schlumberger stocked the Fairchild Advanced Research Laboratory with leading AI researchers from Stanford and SRI, including Peter Hart, Jay Martin Tenenbaum, Harry Barrow, and Richard Duda.Footnote ¹⁰³ Several prominent Silicon Valley figures spent time at Schlumberger, including Reed Hastings (cofounder of Netflix) and Michael Kass (an Oscar-winning computer graphics developer at Pixar).Footnote ¹⁰⁴

Moreover, other oil companies “diversified” into AI at exactly the same time. In the early 1980s, BP and Shell worked with Intelligent Terminals Limited, a start-up associated with prominent academic AI researchers Donald Michie and Jean Hayes-Michie, while Amoco bought an AI company founded by Stanford’s Ed Feigenbaum.Footnote ¹⁰⁵ Others venturing into 1980s-vintage AI included Exxon, Elf Aquitaine, Saga Petroleum, Gulf, Chevron, and Phillips.Footnote ¹⁰⁶ With respect to AI, then, “diversification” is an explanation that begs further explanation of why oil companies concentrated their investments in certain areas.

Even in cases in which diversification was less targeted, we should still note its consequences. Oil companies’ magnitude, combined with their diverse and often short-term pursuits, has allowed them to serve as stepping-stones for many figures in the history of semiconductors and computing, from John Bardeen to Reed Hastings. Not all were successful: the final president of RCA before its collapse was Thornton Bradshaw, formerly president of Atlantic Richfield.Footnote ¹⁰⁷ Some we might wish had been less successful: Auto-Tuned pop music descends from geophysical algorithms developed by Andy Hildebrand at Exxon.Footnote ¹⁰⁸ Some carried little trace of oil: Adam Osborne marketed “the first successful portable computer” and wrote “the documentation for the first microprocessor” after being fired from Shell.Footnote ¹⁰⁹ Yet to understand the recruitment networks that brought people into semiconductors and computing, we need to acknowledge the oil industry’s role in training large numbers of technical personnel and instilling the dissatisfaction or entrepreneurialism needed to move to other pursuits.

The Wider Context

I invite readers now to reread my “Established Narrative” with an eye to the connections to oil that I have made visible in subsequent sections. So far, I have offered reasons why those connections existed, but I have not shown how oil and computing coevolved in some broader historical context. That is a topic for future research. Here I simply paint in broad strokes the major trends that brought oil and computing together.

The main reason for oil-computing spillovers is that the semiconductor industry and the digital electronic programmable computer came into being exactly as oil extraction was becoming much more technologically intensive. From the 1950s onward, new sources of oil could only be found in increasingly difficult political and physical environments: the North Sea, Gulf of Mexico, North Slope of Alaska, Arabian Peninsula, and so on.Footnote ¹¹⁰ Thus, oil companies grabbed technological advantages to overcome competitors, rentier states, and a recalcitrant Earth. Computing aided everything from designing offshore oil rigs to analyzing seismic data to predicting future prices to automating refineries. Before long, the oil industry existentially depended upon digital technologies to maintain profits and continue expanding operations. Drilling in the North Sea, for instance, could not have extended into deep offshore waters if not for advances in software for controlling pipeline flows.Footnote ¹¹¹

Oil companies also used computing to obtain political advantage. In particular, from the late 1960s onward, the largest producers headquartered in Western Europe and the United States faced growing demands from “petrostates” in the Global South for a greater share of revenues.Footnote ¹¹² Thus, where the majors earlier dismissed talk of scarcity or “peak oil,” by the late 1960s, a few oil actors were sponsoring and publicizing forecasts that oil would become precipitously more expensive and harder to access.Footnote ¹¹³ Computer modeling helped legitimate forecasting as a modern and objective practice. Oil firms had already adopted computer models for internal use: “The Sun Oil Corporate Financial Model developed … between 1965 and 1968 was the first large-scale model ever built; it was also an abject failure which was completely abandoned in 1969.”Footnote ¹¹⁴ Sun’s model was superseded by the Industrial Dynamics model developed by Whirlwind inventor Jay Forrester, which led the Club of Rome to commission Forrester to model global resource scarcity; several Club members (Frits Böttcher, Maurice Strong, Joseph Slater) were current or former oil or gas executives, as were close allies of the Club such as George Mitchell and Robert Anderson. The resulting World3 model underlay the Club’s bestselling 1972 Limits to Growth report, which spurred a global debate about scarcity to which oil firms were very much interested parties.Footnote ¹¹⁵ Oil companies also developed alternatives to Industrial Dynamics, such as scenario planning and long-range planning, that were not necessarily computing intensive.Footnote ¹¹⁶ Shell’s scenario planning approach, in particular, proved immensely popular among Silicon Valley techno-optimists who were skeptical of Limits to Growth. Footnote ¹¹⁷

In the short-term, though, Limits’ claims were bolstered by the 1973 OAPEC oil embargo.Footnote ¹¹⁸ The oil shock led to windfall profits for oil companies. It also inspired innovation in energy conservation, such as computerized “smart grids” and the battery and electric vehicle research mentioned earlier.Footnote ¹¹⁹ Many of the direct oil investments in computing that I have outlined occurred in this period from the late 1960s to the mid-1980s. Oil firms needed to park their windfall profits somewhere, and computer and semiconductor technologies offered good returns on investment. The same technologies also looked like promising aids in the search for oil and other fossil fuels.

Then the price of oil started to decline in 1980, reaching pre-1973 levels by 1986. That left oil firms starved of the cash they earlier put into computing.Footnote ¹²⁰ Legislative and financial changes also shifted power to activist investors who demanded short-term returns and an end to long-term investment in technologies not immediately related to oil production.Footnote ¹²¹ Oil companies were still active in computing after 1986, but in more focused, less visible ways than before. Thus, U.S. oil firms were not visible contributors to the dot-com and social media booms, even if those booms built on technologies and institutions in which oil firms formerly invested. In recent years, however, Big Tech companies—particularly Google and Microsoft—have quietly provided crucial aid in extending the life of the fossil-fuel industry.Footnote ¹²² In return, oil money—particularly from Saudi Arabia—has underwritten the emergence of new computing-based industries such as rideshare platforms.Footnote ¹²³ The story of oil and computing is by no means over.