Techno-Nationalism E-Book

Table of Contents

Cover

Table of Contents

Title Page

Copyright

Dedication

List of Illustrations & Diagrams

LIST OF FIGURES

LIST OF IMAGES

PART I: The Elements of Techno-Nationalism

Introduction: My China Lessons

THREE IMPORTANT LESSONS

THE ORIGINS OF THIS BOOK

Chapter 1: Techno-Nationalism

THE POWER OF THE STATE

THE GREAT REORGANISATION

THE GREAT BIFURCATION

PARADOXES AND CONTRADICTIONS

A STEADY SHIFT TOWARDS DECOUPLING

STATES AND FIRMS IN A GREY ZONE

THE BIG QUESTIONS

OVERVIEW OF SECTIONS AND CHAPTERS

Chapter 2: The Technology Feedback Loop

EARLY INTERNATIONAL TALENT WARS

EARLY BRITISH EXPORT CONTROLS

HISTORY’S TECHNOLOGY FEEDBACK LOOP

THE DUTCH SEAFARING TECHNOLOGIES

TECHNO-NATIONALISM AND THE FOUR INDUSTRIAL REVOLUTIONS

PHYSICS AND CHEMISTRY WARS

COMPUTERS, ATOMIC BOMBS AND A SPACE RACE

THE MANHATTAN PROJECT

THE THIRD INDUSTRIAL REVOLUTION (3IR)

CHINA’S 4IR FEEDBACK LOOP

Chapter 3: Paradigm Shift and Paradox

PARADIGM SHIFT BECOMES POLICY

CEOs VERSUS TECHNO-NATIONALISTS

THE WICKED PARADOX

Chapter 4: The In-China-for-China Grey Zone

WELCOME TO THE GREY ZONE

THE TRADITIONAL ‘IN-CHINA-FOR-CHINA’ MODEL

CHINA’S TECH SUBSIDIES: FROM TVs TO EVs

CHINA’S ANTI-ESPIONAGE LAWS

Chapter 5: De-Risking and Decoupling

STRATIFIED GLOBAL VALUE CHAINS

STATES VERSUS FIRMS

THE UKRAINE WAR, DE-RISKING AND DECOUPLING

DECOUPLING FROM RUSSIA

DE-RISKING AND DECOUPLING FROM CHINA

CHINA’S DE-AMERICANISATION LONG GAME

Chapter 6: Export Controls

EXPORT CONTROLS IN THE MODERN ERA

BLACKLISTED ENTITIES

EXTRATERRITORIALITY

WORKAROUNDS, LOOPHOLES AND BACKDOORS

HIGH APPROVAL RATES, LONG GRACE PERIODS AND BINGE-BUYING

CLOUD ACCESS, THIRD-PARTY BACKDOORS AND BLACK MARKETS

A REVAMPED, MULTILATERAL EXPORT CONTROL REGIME

Chapter 7: Semiconductor Ground Zero

CHIP-CENTRIC GEOPOLITICS

WHAT ARE SEMICONDUCTORS?

SEMICONDUCTOR GLOBAL VALUE CHAINS

MOORE’S LAW

CHIP-MANUFACTURING CHOKE POINTS

PACKAGING

RATIONALISED SUPPLY CHAINS

Chapter 8: China’s Semiconductor Problem

TRAILING-EDGE CHIPS

LEADING-EDGE CHIPS

CHINA’S FALSE-POSITIVE CHIP TEST

THE ROAD BEHIND AND AHEAD

Chapter 9: Re-shoring Chip Manufacturing to America

THE CHIPS AND SCIENCE ACT

CHIPS AND THE TRAILING-EDGE REVOLUTION

CHALLENGES, SCEPTICISM AND ASSUMPTIONS

PART II: Undercurrents and Power-Multipliers

Chapter 10: The War Against Huawei

THE THREE POINTS OF REFERENCE

THE SUPERMICRO ANTECEDENT

AMERICA’S HISTORIC TELECOMS-ESPIONAGE MONOPOLY

SENATE INVESTIGATIONS INTO U.S. TELECOMS AND SPY AGENCIES

CHINA’S BRAND OF ECONOMIC-TECHNO-NATIONALISM

STATE-BACKED CHEAP CREDIT FOR EMERGING MARKETS

HUAWEI AND CHINA’S DIGITAL BELT AND ROAD INITIATIVE

HOW THE NEOLIBERAL MODEL BACKFIRED WITH HUAWEI

HUAWEI AND THE QUEST FOR CHIP SELF-SUFFICIENCY

Chapter 11: Tradecraft, Stealth and Technology

THE DISTRACTIONS OF THE U.S. WAR ON TERROR

THE TECHNOLOGY THAT FOUND BIN LADEN

THE TECHNOLOGY THAT KILLED BIN LADEN

CHINESE TRADECRAFT AND HELICOPTER STEALTH TECHNOLOGY

OPERATION ‘BYZANTINE HADES’

FIFTH-GENERATION FIGHTER JETS

SKUNKWORKS LEGACY FEEDBACK LOOP MEETS CHINA TRADECRAFT

A NEW ‘STEALTH’ INNOVATION RACE DRIVEN BY AI

THE RISE OF THE DRONES

Chapter 12: Data, Biotech and Geopolitics

THE ELEMENTS OF DATA GEOPOLITICS

WHAT IS DATA AND WHY IS IT IMPORTANT?

TECHNO-AUTHORITARIANISM AND SURVEILLANCE CAPITALISM

GENETIC DATA AND NATIONAL SECURITY

THE BIOSECURITY–GENOME TECHNOLOGY FEEDBACK LOOP

PHARMACOGENOMICS AND TECHNO-NATIONALISM

DATA CAPITALISM IN THE DIGITAL COMMONS

USER-GENERATED CONTENT

ORIGINAL DATA SUPPLIERS

THE HUMAN GENOME AND DATA CAPITALISM

AMERICAN SCI-TECH DATA HEGEMONY

DATA INTERMEDIARIES

THE DIFFERENT REGULATORY LANDSCAPES AROUND THE WORLD

DATA GEOPOLITICS, SOFT POWER AND INFORMATION WARS

THE CAMBRIDGE ANALYTICA MILESTONE

HOW DATA ANALYTICS SHAPE THE GEOPOLITICAL LANDSCAPE

RUSSIAN INFLUENCE CAMPAIGNS IN SOCIAL MEDIA

THE SPREAD OF INFORMATION WARS

SOCIAL MEDIA INFLUENCERS AND BLOGGERS

PLATFORM DIPLOMACY

INTELLIGENCE AGENCIES RELYING ON PRIVATE COMPANIES

GOVERNMENT DEMANDS FOR DATA ACCESS

Chapter 13: The AI Arms Race

AI DESIGNS A BREAKTHROUGH DRUG

AI AND THE WEAPONS OF WAR

AI AND CYBERWARFARE

AI SUPERPOWERS: THE U.S. VERSUS CHINA

AI MISINFORMATION, DEEPFAKES AND NARRATIVE WARS

AI AND CHIP WARS

Chapter 14: Quantum Technologies

WHAT IS QUANTUM COMPUTING AND WHY DOES IT MATTER?

QUANTUM SUPREMACY AND LIMITATIONS

QUANTUM TECHNOLOGIES AND TECHNO-NATIONALISM

POTENTIAL SECTORS AND PRACTICAL APPLICATIONS OF QUANTUM COMPUTING

REINVENTING PUBLIC KEY CRYPTOGRAPHY

PATENT FILINGS AS A BENCHMARK

QUANTUM KEY DISTRIBUTION (QKD)

THE RACE BETWEEN COMPANIES

TECHNO-NATIONALISM AND THE FUTURE OF QUANTUM TECHNOLOGIES

EXPORT CONTROLS AND RING-FENCING OF STRATEGIC ECOSYSTEMS

TECHNO-DIPLOMACY AND QUANTUM TECHNOLOGY

QUANTUM ETHICS, STANDARDS AND RULES

Chapter 15: Hypersonic Speed

CHINA’S HYPERSONIC TECHNOLOGY SNAPSHOT

‘CARRIER KILLER’ MISSILES

THE ROLE OF AI

THE DARPA ANSWER

Chapter 16: The Great Undersea Cable Decoupling

GEOPOLITICS, DATA AND UNDERSEA CABLES

THE TECHNOLOGY AND COMPETITORS

TECHNO-DIPLOMACY AND UNDERSEA CABLES

THE SEA-ME-WE-6

STATES AND FIRMS IN THE GREY ZONE

CABLE SABOTAGE AND WARFARE

Chapter 17: Space-Based Internet

TRENDS IN SATELLITE TECHNOLOGY AND SPACE-GEOPOLITICS

LOW EARTH ORBIT SATELLITES

A REVOLUTION IN SMALLSAT TECHNOLOGY AND MANUFACTURING

SPACEX AND THE ROCKET REVOLUTION

THE MILITARISATION OF SPACE-BASED INTERNET

THE GREY ZONE: BLURRING THE LINE BETWEEN DEFENCE AND COMMERCE

EXPORT CONTROLS, SANCTIONS AND BIFURCATED GLOBAL VALUE CHAINS

STARLINK INTERNET AND THE RUSSIA–UKRAINE WAR

LETHAL EYES, EARS AND THE DRONE REVOLUTION

OPEN-SOURCED WAR IN THE DIGITAL GLOBAL COMMONS

THE GREY ZONE: STATE VERSUS FIRMS

THE RISE OF SPACE MONOPOLIES

A MULTILATERAL RULES FRAMEWORK FOR SPACE?

Chapter 18: The Twenty-First-Century Space Race

THE COMMERCIALISATION OF SPACE

THE NEW SPACE MARKETS

EMERGING SPACE INDUSTRIES

SPACE ROBOTS

THE RISE AND RISE OF SPACEX

SEMICONDUCTORS AND THE TWENTY-FIRST-CENTURY SPACE RACE

NEOLIBS VERSUS TECHNO-NATIONALISTS

TECH START-UPS

THE MILITARISATION OF SPACE

THE BIFURCATION OF SPACE RESEARCH

DE-RISKING AEROSPACE GLOBAL SUPPLY CHAINS

RE-SHORING

SPACE BLOCS

Chapter 19: Drones, Robots and Autonomous Weapons

THE RISE OF THE MACHINES

INFLECTION POINTS

THE RUSSIA–UKRAINE WAR

TURKISH AND IRANIAN DRONES

KAMIKAZE IN A BACKPACK

THE SHIFT TO LETHAL AUTONOMOUS WEAPONS

THE ETHICAL DILEMMA OF LETHAL AUTONOMOUS SYSTEMS

PART III: Climate, Cleantech and Agritech

Chapter 20: Climate Change and Geopolitics

THE GEOPOLITICS OF ENERGY INFRASTRUCTURE

THE CLEANTECH ARENA

CLIMATE COMPETITION IN EMERGING MARKETS

CHINA’S INFRASTRUCTURE-FOR-RESOURCES DEALS

VALUES-DRIVEN INFRASTRUCTURE PROJECTS

MULTILATERAL INFRASTRUCTURE ALLIANCES

THE DIGITAL INFRASTRUCTURE NEXUS

CHINA’S ISLAND-BUILDING DIPLOMACY

Chapter 21: The Geopolitics of Electric Vehicles

THE CORE AREAS OF EV TECHNO-NATIONALISM

TWENTY-FIRST-CENTURY ELECTRIFICATION OF THE AUTOMOTIVE INDUSTRY

NEW REGULATIONS AND FUNDING

THE EV ECOSYSTEM AND COMPOSITION OF EVs

THE SIMPLICITY OF ELECTRIC MOTORS

CHINA: EV TECHNO-NATIONALIST GROUND-ZERO

CHINA’S DOMINANCE OF RARE EARTH MATERIALS

ACCELERATED DECOUPLING IN RARE EARTHS SUPPLY CHAINS

THE RE-SHORING AND RING-FENCING OF RARE EARTHS

CHINA’S DOMINANCE OF LITHIUM-ION BATTERIES AND RELATED SUPPLY CHAINS

CRITICAL COMPONENTS AND MINERALS

THE GEOGRAPHIC RING-FENCING OF LI-ION BATTERY PRODUCTION

A STORY OF CHINA’S EV BATTERY TECHNO-NATIONALISM

FORCED RELIANCE ON CHINESE SUPPLIERS

AMERICA AND EUROPE’S EV SUBSIDIES, INITIATIVES AND TECHNO-NATIONALIST ROAD MAP

U.S. EV TECHNO-DIPLOMACY

EMERGING EV FRAGMENTATION AND CLUSTERS

Chapter 22: Semiconductors and Electric Vehicle Wars

THE BLURRING OF AUTOMOTIVE AND TECHNOLOGY COMPANIES

THE CHALLENGES OF ‘DUAL-USE’ EV TECHNOLOGIES

CROSS-BORDER MICROCHIP INNOVATION

FOREIGN VENTURE CAPITAL IN A GEOPOLITICAL CONTEXT

AN EV SOFTWARE AND HARDWARE OPEN PLATFORM

SILICON CARBIDE AND GALLIUM NITROGEN CHIPS

CONNECTED CARS AND NATIONAL SECURITY RISKS

SUBSIDIES FOR THE EV–SEMICONDUCTOR NEXUS

THE ROAD AHEAD

Chapter 23: Food Security and Techno-Nationalism

FOOD PROTECTIONISM ON THE RISE

THE ‘FRIEND-SHORING’ OF FOOD SUPPLY CHAINS

TECHNOLOGY AND FOOD SECURITY

PRECISION AGRICULTURE

VERTICAL FARMING

LABORATORY-GROWN PROTEIN

AGRITECH AND INDUSTRIAL ESPIONAGE

WATER SCARCITY AND TECHNOLOGY

THE GEOPOLITICS OF WATER SCARCITY

PART IV: Innovation, Academia, Alliances and Diplomacy

Chapter 24: Techno-Nationalism on Campus

THE CHANGING ACADEMIC LANDSCAPE

ACADEMIC RING-FENCING

MIDDLE-COUNTRY UNIVERSITIES

STUDENT NATIONALITIES

CHINA’S THOUSAND TALENTS PROGRAMME AND ACADEMIC ESPIONAGE

RULE FRAMEWORKS AND RESEARCH SECURITY

SCREENING THE SOURCES OF FUNDING

THE MILITARY AND ACADEMIA

Chapter 25: Chip Schools

PURDUE’S SILICON MOMENT

THE RISE OF THE NATIONAL CHIP HUBS

CHIP SCHOOL WEST: ARIZONA STATE UNIVERSITY

ACADEMIC CROSS BORDER FRIEND-SHORING

TAIWAN’S GLOBAL TALENT DEVELOPMENT STRATEGY

A WORLDWIDE SHORTAGE OF TALENT

Chapter 26: The Innovation Horse Race

GOVERNMENT ACTIVISM: WHY IT MATTERS

PUBLIC–PRIVATE PARTNERSHIPS

R&D AND THE PARADIGM SHIFT

MILESTONES OF CHINESE TECHNO-NATIONALISM

A BRIEF REFLECTION ON THE BENEFITS OF INDUSTRIAL POLICY

THE ORIGINS OF AMERICA’S CHIP POLICIES

Chapter 27: India Rising?

INDIA’S FERTILE ECONOMY AND TECHNOLOGY LANDSCAPE

ACCELERATED DECOUPLING FROM CHINA

INDIA’S DIGITAL LANDSCAPE

SOFTWARE AND ENGINEERING RESEARCH & DEVELOPMENT (ER&D)

THE PAIN-OF-DOING-BUSINESS IN INDIA

SMARTPHONES AND GEOPOLITICAL INFLUENCE

BUILDING WORLD-CLASS CLUSTERS WITH LOCAL MANUFACTURERS

PRINTED CIRCUIT BOARD ASSEMBLY AND SEMICONDUCTORS

Chapter 28: Fragmented Finance

CENTRAL BANK-BACKED DIGITAL CURRENCIES

IDEOLOGY AND DIGITAL CURRENCY: A CLASH OF CIVILISATIONS

DIGITAL DYSTOPIA

NEW ACCOUNTING STANDARDS AIMED AT CHINESE COMPANIES

THE U.S. OUTBOUND INVESTMENT TRANSPARENCY ACT

INTERNATIONAL BANKS CAUGHT BETWEEN BEIJING AND WASHINGTON

CHINA PUNISHES HSBC

TECHNO-NATIONALISM AND FINTECH DECOUPLING

SOVEREIGN WEALTH FUNDS AND GEOPOLITICS

Chapter 29: Techno-Diplomacy and the Road Ahead

FROM FTAs TO MINI-LATERAL ARRANGEMENTS

THE CHIP 4 ALLIANCE (FACT OR FICTION)

THE INDO-PACIFIC ECONOMIC FRAMEWORK

THE AUKUS TRILATERAL SECURITY AGREEMENT

THE QUADRILATERAL SECURITY DIALOGUE (QUAD)

BILATERAL TECHNO-DIPLOMACY

AI ETHICS AND THE PROMISE OF OPEN-SOURCED PLATFORMS

THE GREAT REORGANISATION WILL GO ON

Notes

INTRODUCTION: MY CHINA LESSONS

CHAPTER 1: TECHNO-NATIONALISM

CHAPTER 2: THE TECHNOLOGY FEEDBACK LOOP

CHAPTER 3: PARADIGM SHIFT AND PARADOX

CHAPTER 4: THE IN-CHINA-FOR-CHINA GREY ZONE

CHAPTER 5: DE-RISKING AND DECOUPLING

CHAPTER 6: EXPORT CONTROLS

CHAPTER 7: SEMICONDUCTOR GROUND ZERO

CHAPTER 8: CHINA’S SEMICONDUCTOR PROBLEM

CHAPTER 9: RE-SHORING CHIP MANUFACTURING TO AMERICA

CHAPTER 10: THE WAR AGAINST HUAWEI

CHAPTER 11: TRADECRAFT, STEALTH AND TECHNOLOGY

CHAPTER 12: DATA, BIOTECH AND GEOPOLITICS

CHAPTER 13: THE AI ARMS RACE

CHAPTER 14: QUANTUM TECHNOLOGIES

CHAPTER 15: HYPERSONIC SPEED

CHAPTER 16: THE GREAT UNDERSEA CABLE DECOUPLING

CHAPTER 17: SPACE-BASED INTERNET

CHAPTER 18: THE TWENTY-FIRST-CENTURY SPACE RACE

CHAPTER 19: DRONES, ROBOTS AND AUTONOMOUS WEAPONS

CHAPTER 20: CLIMATE CHANGE AND GEOPOLITICS

CHAPTER 21: THE GEOPOLITICS OF ELECTRIC VEHICLES

CHAPTER 22: SEMICONDUCTORS AND ELECTRIC VEHICLE WARS

CHAPTER 23: FOOD SECURITY AND TECHNO-NATIONALISM

CHAPTER 24: TECHNO-NATIONALISM ON CAMPUS

CHAPTER 25: CHIP SCHOOLS

CHAPTER 26: THE INNOVATION HORSE RACE

CHAPTER 27: INDIA RISING?

CHAPTER 28: FRAGMENTED FINANCE

CHAPTER 29: TECHNO-DIPLOMACY AND THE ROAD AHEAD

Acknowledgements

Index

End User License Agreement

List of Illustrations

Chapter 1

Figure 1.1 Foundational and Strategic Technologies of the Twenty-first Centu...

Chapter 2

Figure 2.1 Richard Arkwright’s Coveted Spinning Frame.

Figure 2.2 Alexander Hamilton’s Report of Manufacturers Presented to the U.S...

Figure 2.3 Portrait of Samuel Slater, Father of the American Manufacturing S...

Figure 2.4 Portrait of Alexander Hamilton, America’s First Secretary of the ...

Figure 2.5 Illustration, The Techno-nationalist Feedback Loop.

Figure 2.6 Cornelius Corneliszoon’s 1593 Wind-powered Sawmill.

Figure 2.7 ENIAC, the first digital computer, developed for the U.S. Army at...

Figure 2.8 The Manhattan’s Project’s Atomic Bomb, at Los Alamos, in 1945....

Chapter 5

Figure 5.1 Made-In-China 2025 List of Priority Technologies.

Chapter 7

Figure 7.1 Apple’s Chips Stacked with Billions of Transistors.

Figure 7.2 Semiconductors: The Foundational Technologies.

Figure 7.3 The Chip Manufacturing Process.

Figure 7.4 ASML DUV Photolithography Machine.

Figure 7.5 ASML EUV Photolithography Machine.

Chapter 9

Figure 9.1 Partial List of New Chip Fabs in the U.S (Announced and In Progre...

Chapter 10

Figure 10.1 Backside of the Huawei Mate 60 Smartphone, Showing Camera Lens....

Figure 10.2 The Kirin 9000 7-nanometre Chip, Designed by HiSilicon and Fabri...

Chapter 11

Figure 11.1 US Military Bell Invictus Helicopter with the latest Stealth Tec...

Figure 11.2 Frontal View of a US Airforce F-35 Stealth Fighter.

Chapter 13

Figure 13.1 Countries Ranked by their Artificial Intelligence (AI) Capacity.

Figure 13.2 The IBM Blue Gene Supercomputer.

Chapter 14

Figure 14.1 How Quantum Computing Works.

Figure 14.2 Quantum Computing versus Classical Computing.

Figure 14.3 Practical Applications of Error-Free Quantum Computing.

Chapter 15

Figure 15.1 China’s Dong Feng 27 Hypersonic Missile.

Figure 15.2 Artist Rendition of Northrop Grumman’s Scramjet Hypersonic Engin...

Chapter 16

Figure 16.1 Undersea Cable Networks.

Chapter 17

Figure 17.1 Low Earth Orbit (LEO) Satellite Constellation.

Figure 17.2 LEO CubeSats and SmallSats: Compact and Inexpensive.

Chapter 18

Figure 18.1 The SpaceX Falcon 9 Heavy Rocket.

Figure 18.2 Payload for the NASA-SpaceX Psyche 16 Asteroid Mining Mission.

Figure 18.3 A SpaceX Rocket First Stage Landing Upright after Returning to E...

Figure 18.4 Payload of Starlink LEO Satellites on Top of a SpaceX Falcon 9 R...

Figure 18.5 The Secretive X37-B Autonomous Robotic Orbital Space Plane: Reus...

Chapter 19

Figure 19.1 The Turkish Aerospace Industries Anka-3 Combat Drone.

Figure 19.2 Iranian Shahed 136 Drones, and Arash-2 Long Distance Drone.

Figure 19.3 Drone Swarms (Artist Rendition).

Figure 19.4 The US Airforce MQ-9 Reaper Killer Drone made by General Atomics...

Figure 19.5 Dorothy Engelhardt, Director, Unmanned Systems, Deputy Assistant...

Chapter 20

Figure 20.1 Floating Chinese-built Solar Farm in a Hydro-power Reservoir.

Chapter 21

Figure 21.1 Electric Car and Lithium Batteries.

Chapter 23

Figure 23.1 Editing the DNA of Plants for Hardier, Climate Change Resistant ...

Chapter 27

Figure 27.1 Map of India’s Traditional Technology Hubs.

Chapter 28

Image 28.1 Photograph of Meng Wanzhou, the CFO of Huawei who was placed unde...

Chapter 29

Figure 29.1 Digital Democracies Equal Approximately 50% of Global GDP (PPP B...

Guide

Cover

Table of Contents

Title Page

Copyright

Dedication

List of Illustrations & Diagrams

Begin Reading

Notes

Acknowledgements

Index

End User License Agreement

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Techno-Nationalism

How It’s Reshaping Trade, Geopolitics and Society

This edition first published 2025

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List of Illustrations & Diagrams

LIST OF FIGURES

Figure 1.1

Foundational and Strategic Technologies of the Twenty-first Century

Figure 2.1

Richard Arkwright’s Coveted Spinning Frame

Figure 2.2

Alexander Hamilton’s Report of Manufacturers Presented to the U.S. House of Representatives in 1791

Figure 2.3

Portrait of Samuel Slater, Father of the American Manufacturing System

Figure 2.4

Portrait of Alexander Hamilton, America’s First Secretary of the Treasury

Figure 2.5

Illustration, The Techno-nationalist Feedback Loop

Figure 2.6

Cornelius Corneliszoon’s 1593 Wind-powered Sawmill

Figure 2.7

ENIAC, the first digital computer, developed for the U.S. Army at the University of Pennsylvania, during the Second World War

Figure 2.8

The Manhattan’s Project’s Atomic Bomb, at Los Alamos, in 1945

Figure 5.1

Made-In-China 2025 List of Priority Technologies

Figure 7.1

Apple’s Chips Stacked with Billions of Transistors

Figure 7.2

Semiconductors: The Foundational Technologies

Figure 7.3

The Chip Manufacturing Process

Figure 7.4

ASML DUV Photolithography Machine

Figure 7.5

ASML EUV Photolithography Machine

Figure 9.1

Partial List of New Chip Fabs in the U.S (Announced and In Progress, 2024)

Figure 10.1

Backside of the Huawei Mate 60 Smartphone, Showing Camera Lens

Figure 10.2

The Kirin 9000 7-nanometre Chip, Designed by HiSilicon and Fabricated by Semiconductor Manufacturing International Corporation (SMIC) for the Huawei Mate 60 Smartphone

Figure 11.1

US Military Bell Invictus Helicopter with the latest Stealth Technology

Figure 11.2

Frontal View of a US Airforce F-35 Stealth Fighter

Figure 13.1

Countries Ranked by their Artificial Intelligence (AI) Capacity

Figure 13.2

The IBM Blue Gene Supercomputer

Figure 14.1

How Quantum Computing Works

Figure 14.2

Quantum Computing versus Classical Computing

Figure 14.3

Practical Applications of Error-Free Quantum Computing

Figure 15.1

China’s Dong Feng 27 Hypersonic Missile

Figure 15.2

Artist Rendition of Northrop Grumman’s Scramjet Hypersonic Engine

Figure 16.1

Undersea Cable Networks

Figure 17.1

Low Earth Orbit (LEO) Satellite Constellation

Figure 17.2

LEO CubeSats and SmallSats: Compact and Inexpensive

Figure 18.1

The SpaceX Falcon 9 Heavy Rocket

Figure 18.2

Payload for the NASA-SpaceX Psyche 16 Asteroid Mining Mission

Figure 18.3

A SpaceX Rocket First Stage Landing Upright after Returning to Earth

Figure 18.4

Payload of Starlink LEO Satellites on Top of a SpaceX Falcon 9 Rocket

Figure 18.5

The Secretive X37-B Autonomous Robotic Orbital Space Plane: Reusable for Military and Intelligence-related Missions

Figure 19.1

The Turkish Aerospace Industries Anka-3 Combat Drone

Figure 19.2

Iranian Shahed 136 Drones, and Arash-2 Long Distance Drone

Figure 19.3

Drone Swarms (Artist Rendition)

Figure 19.4

The US Airforce MQ-9 Reaper Killer Drone made by General Atomics

Figure 19.5

Dorothy Engelhardt, Director, Unmanned Systems, Deputy Assistant Secretary of the Navy (Ships), Christens the Orca XLUUV Test nAsset System during a Ceremony April 28, 2022, in Huntington Beach, California

Figure 20.1

Floating Chinese-built Solar Farm in a Hydro-power Reservoir

Figure 21.1

Electric Car and Lithium Batteries

Figure 23.1

Editing the DNA of Plants for Hardier, Climate Change Resistant Food

Figure 27.1

Map of India’s Traditional Technology Hubs

Figure 29.1

Digital Democracies Equal Approximately 50% of Global GDP (PPP Basis)

LIST OF IMAGES

Image 28.1

Photograph of Meng Wanzhou, the CFO of Huawei who was placed under house arrest in Canada, for three years, for the alleged involvement in U.S. Export Controls Violations

PART IThe Elements of Techno-Nationalism

Introduction: My China Lessons

Since the opening of China to foreign commerce in the late 1970s, Beijing’s central planners have presided over the largest and most rapid transfer of wealth in human history. It was primarily Western companies that made this possible, as a decades-long torrent of money and technology flowed into China’s state-centric economic system.

The numbers are staggering. If we count official foreign direct investment (FDI) figures along with estimates of unofficial capital flows via offshore financial centres—such as Hong Kong, the Cayman Islands and the British Virgin Islands—at least US$6 trillion flowed into China over a 30-year time frame.1,2

That is a conservative estimate. If we factor in forced technology transfer and stolen intellectual property just from American private and public entities, the number comes to at least US$10 trillion, or more than half the value of China’s entire gross domestic product (GDP) in 2023.

The U.S. Trade Representative (USTR) has estimated that China’s forced technology-transfer practices cost the U.S. economy hundreds of billions of dollars more per year, while agencies such as the National Bureau of Economic Research claim that China’s ongoing cyberattacks on U.S. companies drain off billions more.

These vast transfers of wealth were feasible because of the spread of powerful and affordable new technologies, combined with the Chinese Communist Party’s (CCP) iron-willed and methodical pursuit of its modernisation goals.

I would come to learn all these things first hand, as my professional career landed me right in the middle of this historical inflection point. I arrived in Hong Kong in 2003 as an American expat, two years after China’s accession to the World Trade Organization (WTO). I would eventually become a partner at KPMG, the global accounting and consultancy firm, and would take over as the regional head of its Asia Trade and Customs Practice.

In my work, I provided multinational companies with advice on their global operations, which often meant that, for economic and practical reasons, their supply chains would pass through China. There were foreign trade zones to manage and a host of cross-border transactions to monitor. There were customs duties, indirect taxes and trade agreements to optimise.

After China’s successful accession to the WTO, companies ramped up their investments and began directing higher-valued activities into China. By 2017, according to PWC, the global consultancy, about 80% of the corporate R&D money spent in China came from foreign multinationals, most of them American and European.

During my tenure in Hong Kong, global trade hit a historic high. Except for the year following the global financial crisis, in 2009, seven out of my first eight years on the job yielded double-digit growth rates in the value of world trade. And between the U.S. and China, the annual value of bilateral trade in goods and services had crossed the US$ half-trillion threshold.

By the mid-2000s, incredibly, Walmart, the world’s largest retailer, was importing so much from China that it accounted for more than 11% of China’s annual exports, according to the Brookings Institution.3

Meanwhile, as foreign money and technology continued to pour into China, so did international talent. The professional services industry, composed of management consultants, accountants, tax planners, head-hunters, academics and lawyers, quickly soaked up the economic opportunities. Large consulting firms such as Accenture, KPMG, PWC and McKinsey became fixtures in China’s business landscape.

Scholars have yet to fully gauge the magnitude of influence that consultancies had in accelerating the growth of China. In just over four decades, firms like mine served up a menu of mostly neoliberal economic advice to thousands of companies—and to Chinese government entities—as foreign money saturated Beijing’s centrally planned landscape, funding greenfield sites, joint ventures and technology transfers. This transformed China into the world’s largest manufacturing and supplier base and made it the world’s top exporter.

I did not fully understand it at the time, but in my position, I was simultaneously enabling history’s most remarkable period of trade and globalisation and, unwittingly, contributing to the eventual upending of the Western-led rules-based order.

THREE IMPORTANT LESSONS

Soon after settling into life in Hong Kong, my worldview became conflicted. I arrived as a true internationalist: As the son of a U.S. diplomat, I had grown up in eight countries on three continents, studied international relations in college and my first job had been with U.S. Customs at one of the world’s busiest trading ports—Los Angeles.

From my desk in LA, as a trade specialist, I watched the phenomenon of globalisation unfold, from the late 1980s until the late 1990s, when I left the government for the enterprising world of consulting.

From Hong Kong, I began to witness, close up, the incongruities (incompatibilities, actually) between China Inc.’s nonmarket economy and Western laissez-faire capitalism.

Over time, three lessons emerged from what I will call ‘my China classroom’.

The first lesson was that most foreign business executives naively construed geopolitics and business as separate issues. Most Western CEOs had no understanding (and still do not) of the resoluteness of China’s five-year plans and the CCP’s longstanding quest to achieve Chinese self-sufficiency.

The truth was, Beijing had been pre-emptively decoupling from its chief benefactors, playing the ‘long game’, as Rush Doshi would call it, by shrewdly calculating what it could extract from others and how to prevent them from taking from the Middle Kingdom.

My second lesson taught me how deeply nationalism had permeated the business landscape. Most of my Chinese colleagues and friends (regardless of whether they had been educated in the West) quietly harboured a deep-rooted sense of national pride and grievance.

I learned about the ‘Century of Humiliation’ narrative, which posits that for eight centuries, from the Han dynasty to the early modern period in the nineteenth century, China had been the world’s largest, wealthiest and most sophisticated world power. It was the European colonial empires and China’s next-door neighbour and long-time tormentor, Imperial Japan, that brought its global prominence to an end.

The Century of Humiliation, from 1849 until 1949, as it is widely taught to school children, ushered in a series of catastrophes, including the Opium Wars with Britain and the ravages of the Sino-Japanese Wars. Seven decades after the ascension of Mao and the CCP in 1949, these themes continue to influence China’s policymaking.

Other similarly influential views had seeped into the national narrative. Not surprisingly, one was the unapologetic call for ‘China’s Return to Greatness’, with the underlying theme that China was reclaiming its rightful place again at the top of the world order.

Parallel to this were increasing references to the ‘decline of America and the West’. When the global financial crisis hit in 2007–2008, it emboldened China’s technocrats even further. With the meltdown of financial markets and the symbolic collapse of Lehman Brothers, the 158-year-old Wall Street investment bank, the Western economic model came under further disregard.

These themes are harnessed by the modern-day communist party to stoke righteous indignation and invigorate nationalist policies. This has been a decades-long campaign, starting in the classroom and buttressed by a barrage of carefully crafted and censored narratives across the Internet, on millions of blogs, and on influencer platforms. Present day Western business executives are shocked to learn that China’s ‘Millennial’ generation (born 1981–1994) and ‘Generation Z’ (1995–2010) are far more nationalistic than their parents.

Foreigners who have not worked and lived in China simply do not understand the extent to which nationalism fuels the ‘return-to-greatness narrative’ and, in turn, how it is driving modern policies around economic nationalism and China’s quest towards self-reliance.

Here, intellectually, is where I committed a common mistake made by Westerners. I tried to dismiss these narratives as sentimentalist and assumed they would fade away as China integrated with the West.

How could they not? To experience China as a foreigner in the early 2000s was to be an ambassador for all the good things that free trade and cross-border exchange could offer. Surely a rising tide would lift all ships, as John F. Kennedy had said.

I did not fully realise it at the time, but to witness the beginnings of great power competition during my early years in China changed me from an avowed internationalist to a practical realist. Meanwhile, the paradox of the Free World’s economic entanglement with China would grow more complicated and more challenging with the passage of time.

I can trace my realisation of this paradox to a single defining moment, late one night in Shanghai, in 2004, when I strolled down an almost empty Nanjing Road West, under razor-edged high rise buildings and towering electric billboards. The immense scale of it was exhilarating, but I knew I was living dangerously; there was something vaguely dystopic and foreboding about that moment.

What happened next? I pushed these thoughts out of my mind, and, myopically, turned my attention back to my work.

Consider that at the time, America was still hanging on to the last vestiges of its so-called ‘unipolar’ moment. We were a little over a decade removed from the Cold War triumph over the former Soviet Union, which had collapsed in 1991. The Cold War had been the central fixture of international relations for more than 40 years, and we had won.

Before I moved to China, during a decade-long career at U.S. Customs, I had administered and enforced American antidumping and countervailing duty laws, import quotas and other laws designed to pommel Japan into geopolitical submission. Recall that Japan, in the 1980s and 1990s, was perceived as a threat to American economic hegemony. The lesson here was that by the late 1990s Washington had won that geopolitical competition as well, and Japan was already slipping into its so-called ‘lost decades.’ Would not China fall in line too?

My worldview, at the time, had been sustained by a steady diet of neoliberalism. In the mid 1990s I took a sabbatical from Customs to attend the London School of Economics. There, I was influenced by the writings of Francis Fukuyama, who wrote about the triumphs of liberal democracy and free markets and the inevitable retreat of authoritarianism. I was drawn to Kenichi Ohmae’s book, The Borderless World which inspired me to become an international trade consultant and was a big reason I eventually ended up in China.

Ohmae, who had been a partner at McKinsey, the elite consultancy, sold me and countless others on the promises of global trade and the unlimited potential of unrestrained ideas, goods and people crossing borders. And what better place to be during the heady years of globalisation than in Hong Kong, right on the doorstep of China’s growing economic juggernaut?

The third and most consequential lesson was about the pivotal role that technology would play in the coming great power rivalry between Washington and Beijing.

China’s elite had gone all-in on leveraging technology for the Middle Kingdom’s return to greatness, thanks to China’s second greatest gift (after epic inflows of foreign investment) which was the Fourth Industrial Revolution (4IR). A treasure trove of new, accessible technologies had become the new game-changer. From Beijing’s perspective, the great geopolitical power shift would rely upon continual access to leading-edge technology.

I find it more than coincidental that the week after I arrived in Hong Kong, China launched its first astronaut, Yang Liwei, into Earth’s orbit. The Shenzhou 5 mission blasted off from Jiuquan Satellite Launch Centre in Inner Mongolia on October 15, 2003. Since then, this date marks an important milestone for me regarding the twenty-first-century technology race.

At that time, China might as well have been 100 years behind the U.S. in the Space Race. When Shenzhou 5 occurred, it had been almost 40 years since 12 separate American astronauts had walked on the Moon during NASA’s Apollo missions, which ended in 1972.

Yet, in less than two decades since Shenzhou 5, China has all but closed the technology gap between itself and the U.S.

Such were my early China lessons.

I needed to explore these themes further. Clearly, technology-facilitated China’s ambitious five-year plans, as did free markets and foreign businesses. Here, the themes of nationalism and technology stuck with me.

Thus began my motivation for writing this book.

THE ORIGINS OF THIS BOOK

In 2015, I joined the faculty of the National University of Singapore (NUS) as a visiting senior fellow. I was to draw upon my earlier career and focus my research and teaching on global supply chains and trade, with an emphasis on Asia.

Two themes would consistently emerge in my work: geopolitics and technology. Current events made these topics impossible to ignore. The technology revolution was not just fundamentally innovating and transforming global value chains and commerce, it was also at the centre of a great power competition that was spilling over into the business landscape.

In 2016, Donald Trump was elected the forty-fifth U.S. president, and my work on what I began to categorise as ‘techno-nationalism’, took on a new sense of purpose. U.S. tariff hikes on Chinese goods, for example, the weaponisation of semiconductor supply chains and Washington’s all-out campaign to stop Huawei—the Chinese telecommunications equipment manufacturer—and other Chinese tech firms from capturing foreign market share became the focus of my research.

I designed a series of MBA courses at the NUS Business School that dealt with the challenges of sanctions, export controls and other technology-transfer restrictions in supply chains. In my curriculum, I pushed my students to navigate around these obstacles and figure out how to mitigate risks and spot new opportunities in this shifting landscape.

The same year that Trump was elected, I began co-teaching a course, Trade Policy and Global Value Chains, with Professor Razeen Sally at the Lee Kuan Yew (LKY) School of Public Policy at NUS. Professor Sally and I had been discussing trade and political economy for a long time, going all the way back to our time together, in 1995, at the London School of Economics.

The world had changed significantly by the time we started teaching our course at NUS. Each year, as U.S.–China geopolitical tensions continued to escalate, we welcomed into our programme another cohort of diplomats, lawyers, journalists and others from around the world. It became clear that geopolitics was reshaping the international trade landscape, more than anything else, and it seemed that this was the topic everyone needed to discuss.

In 2019, three years into Prof Sally’s and my course at the NUS LKY School, I became a research fellow at the Singapore-based Hinrich Foundation, a trade-focused think tank.

The first Hinrich Foundation paper I authored was entitled ‘Semiconductors at the Heart of the U.S.–China Tech War’.4 It was initially published in January 2020, about a year ahead of what would soon become a full-blown American tech war. I chose to employ the term ‘techno-nationalism’ in that report, a powerful juxtaposition of words that the academic and statesman Robert Reich had used, more than 35 years earlier.

What started as an analysis of the global semiconductor sector quickly morphed into a string of dozens of other research publications, all of which highlighted ‘twenty-first-century techno-nationalism’ across a range of industries and dimensions.

Meanwhile, to satisfy the growing demand for public discourse, I was publishing articles related to techno-nationalism in Forbes, Nikkei Asia, the Diplomat and other media platforms. The demand for public discussion grew by the day. With the Trump sanctions and other China-related actions, I began fielding regular requests from global media.

Such are the origins of this book.

Chapter 1Techno-Nationalism

This book is about how governments pursue technology as a power multiplier and how tech-competition between nations is reshaping global affairs in the twenty-first century.

Call it ‘techno-nationalism;’ a mindset that equates the technological prowess of a state’s chosen actors with the strength of its national security, its economic prosperity and its social stability. Techno-nationalism seeks to attain competitive advantage for its stakeholders, on a local and global scale, and to leverage this advantage for geopolitical gain.

This is not a new phenomenon. As long as there have been nation-states, especially with the evolution of modern states in seventeenth- and eighteenth-century Europe, governments have sought to harness the power of technology to advance their interests.

It was the French writer, Antoine de Saint-Exupéry, who famously wrote: ‘Every nation is selfish, and every nation considers its selfishness sacred’.

The twentieth century saw firsthand the effects of techno-nationalism with two of the bloodiest, most definitive wars in history, a forty-year Cold War between America and the former Soviet Union, a race in space and to the Moon, a nuclear arms race, the rise of computers and artificial intelligence, and the beginnings of geopolitical competition linked to the semiconductor.

Robert Reich used the term ‘techno-nationalism’ in a piece for The Atlantic in 1987, in which he reflected on its paradoxical nature. At the time, the U.S. political establishment had stymied the sale of Fairchild Semiconductor Corporation to Fujitsu, a Japanese company. Washington had singled out Japan’s technological prowess as a threat to U.S. economic hegemony.

Make no mistake: Twenty-first century techno-nationalism is on a scale and level of significance that is orders of magnitude greater than that of the twentieth century.

Consider the differences. During its rise in the 1980s as an economic juggernaut, Japan was a liberal democracy. It followed a constitution, largely imposed by the U.S. after Japan’s defeat in World War II, that prohibited the expansion of its military—in fact, Japan relied upon the U.S. for its security needs—and Tokyo certainly had no ideological or geopolitical aims of displacing America as the leader of the rules-based international order. None of these things can be said about the rise of China. Its pervasive techno-nationalist apparatus and the rapid build up of its military, combined with the ideology of ‘socialism with Chinese characteristics’ has become a direct challenge to the existing Western rules-based order. Great power competition is on full display.

At the centre of techno-nationalism are six core elements, or behaviours, each of which effects a wide swathe of the international landscape. They are:

The ‘weaponisation’ of supply chains

Strategic decoupling and ‘de-risking’

Re-shoring, near-shoring and friend-shoring

State-funded innovation and talent wars

Tech-diplomacy, strategic partnerships and tech alliances

Tradecraft and ‘hybrid cold war’

We will discuss all these things extensively throughout this book. But first, we must identify the key categories of ‘foundational’ technologies, of which there are twelve.

Technology

Description

Advanced Materials

Composite materials, coatings and chemicals that enable heat resistance, strength, reduced weight, stealth, superconductivity, and improved performance. Includes smart ‘self-healing’ materials; explosives and energetic materials, novel metamaterials, advanced magnets, processed rare earths and minerals.

Advanced Manufacturing

Nano-scale manufacturing, atomic layer deposition, additive manufacturing, AI enabled production, advanced manufacturing robotics.

Artificial Intelligence (AI)

Machine learning, including neural networks and deep learning, ‘cognitive’ machines, natural language processing, including large language models (LLMs) with speech and text recognition and cognition, advanced algorithms and high-performance super-computing.

Aerospace

Reusable rocketry and space vehicles for transportation and habitation, deep space exploration; satellites, ballistic missiles, hypersonic aircraft and missiles, autonomous unmanned spacecraft.

Biotechnology

Biological manufacturing and synthetic biology, vaccines, genetic engineering and pharmacogenomics, germ warfare and DNA weaponisation.

Connectivity & Communications

5G and 6G wireless broadband, the Internet-of-Things (IoT), space-based Internet and low earth orbit (LEO) constellations, neuromorphic computing, and brain-computer interfaces (BCI); Light-Fidelity (Li-Fi) communications.

Energy

Electric batteries, photovoltaics and supercapacitors, biofuels, nuclear fission and fusion technologies, directed energy (lasers); hydrogen and ammonia power.

Propulsion

Nuclear thermal rockets, plasma drives, and hypersonic engines. Underwater propulsion systems including super cavitation drives and magnetohydrodynamic propulsion.

Quantum

Computing, sensing (which includes light, motion, temperature, pressure) and communication, including quantum key distribution (QKD).

Robots & Drones

Includes unmanned, autonomous aerial vehicles (UAV) and unmanned underwater vehicles (UUVs); drone swarms and machine biomimicry (machines that copy natural design for efficiency of locomotion, dexterity and lethality), ground-based military robots; and all manner of remotely operated and autonomous machines.

Sensing, Timing & Navigation

Includes biomimetic and neuromorphic sensors; ultra-stable oscillators and optical clocks; satellite-based augmentation systems and light and detection ranging (LIDAR).

Semiconductors

Also called ‘chips’ or ‘microchips’, semiconductors are the heart, brains and nerve centres of virtually anything that has an on-off switch. Chips are vital for logic, memory, power and overall functionality.

Figure 1.1 Foundational and Strategic Technologies of the Twenty-first Century.

These are all Fourth Industrial Revolution (4IR) foundational technologies.

Their power-multiplying effects drive economic competition, but more importantly, they determine winners and losers in that most basic of all human preoccupations: warfare. In this regard, nothing has changed for millennia.

These are referred to as foundational technologies because they are an essential ingredient for all other applications of leading-edge tech. Many are interrelated; where there is one there are others. One of these, AI, is especially critical because it is pushing the boundaries of knowledge in research and design, engineering, manufacturing, medicine, communications, operations and management, and, of course, the many different aspects of national defence.

More fundamentally, none of the above technologies are possible without access to semiconductors. This is why these tiny microchips find themselves at the centre of every element of techno-nationalist competition.

We will discuss all these technologies in separate chapters and how techno-nationalism is affecting their development and use.

It is important to note that technology, by itself, is not deterministic. In other words, those who create it must choose how to use it, whether for good or for evil. As we will see, however, virtually every technology can be used for both commercial and military purposes, thus we encounter the ‘dual-use’ dilemma—a challenge to businesses, traders, innovators and policymakers.

THE POWER OF THE STATE

Nation-states are the most powerful and influential actors in the international system. We begin the discussion about techno-nationalism, therefore, by recognising that a small number of states wield inordinate amounts of power.

Consider that in 2022, the Group of 7 (G7) countries—the U.S., Japan, Germany, France, the U.K., Canada and Italy and the European Union (E.U.), as a non-enumerated member—together with China, accounted for 60% of global GDP.1 Such a disproportionate amount of wealth, as it’s channelled towards techno-nationalist objectives, is profoundly changing the international landscape.

These same countries are now at a historic inflection point. Great power rivalry and modern realpolitik has sparked an onslaught of techno-nationalist policies and agendas.

Technology-oriented spending around the world has been consolidating within a few power centres. Consider that from around 2020 to the end of 2023, the U.S., the European Union and China, alone, budgeted somewhere between US$6–8 trillion in public funding for technology-related initiatives—not counting high-tech military expenditures. Much of this public spending was focused on large infrastructure projects that emphasised digital connectivity, AI, computing, and automation, as well as sustainable energy, clean transportation and sustainable manufacturing.

In 2023, China, by itself, spent just under US$1 trillion on clean energy development.2 Special emphasis went to electric vehicles (EVs), batteries, high-speed rail, electricity grids, energy storage, solar and wind power.

Semiconductors and AI are now the most publicly contested technologies, with hundreds of billions of dollars being spent collectively in China, the U.S., South Korea, Japan,3 Taiwan and the E.U. But the implications of losing out on cleantech are just as serious, as these technologies are also important geopolitical power multipliers, as we will discuss in Part III of this book.

In the big picture, China, America and the E.U.’s technology-related expenditures, together, account for more than the combined tech-budgets of a hundred of the world’s less developed countries, and a large chunk of so-called middle tier nations, such as India or Malaysia.

These numbers become more consequential when we factor in the additive value of tax breaks and other incentives offered through public–private partnerships (PPP), which are designed to pile private investments on top of government funding.

In the U.S., for example, less than two years after the passage of the CHIPS and Science Act4 in 2022—which budgeted US$280 billion for leading-edge technology, including US$52 billion in funding for semiconductor R&D and chip production—private industry had already invested more than US$300 billion towards new chip fabrication projects.5

A sizeable chunk of this new private money came from Taiwan Semiconductor Manufacturing Company (TSMC), the largest and most advanced microchip manufacturer in the world, largely in response to Washington’s diplomatic arm-twisting.6

These are the early rounds of funding. The CHIPS Act will require more infusions of capital over the next decade-plus. It is fortunate for techno-nationalists, then, that semiconductors have been deemed an essential element of national security. America’s spending on defence exceeds the annual military budgets of at least the next 10 largest countries, combined.7 In 2022, for example, it accounted for around 40% of all the world’s defence spending.

Thus, putting semiconductor production (or any other technology) under the national security umbrella means funding will be available—so long as squabbles in the U.S. Congress do not derail disbursement of future monies.8

Techno-nationalism continues to spill over into climate change policies and the decarbonisation of the global economy. Large-scale capacity-building initiatives in clean technology, such as lithium batteries, electric vehicles (EV) and alternative energy infrastructure, are increasingly a point of contention amongst trading partners.

Here, huge public funding in green initiatives in the U.S., Europe and China will fragment the geopolitical playing field and push it towards regionalisation and localisation. This is not to say, however, that new coalitions of countries will not coalesce around creative, mutually beneficial trading arrangements.

In America, the Bi-Partisan Infrastructure bill provided a funding conduit for cleantech and green infrastructure that has attracted secondary investors from Europe and Asia. As of 2023, the bill had funded 40,000 different projects worth about US$400 billion.9 Other legislation advancing U.S. strategic policy interests included the massive Inflation Reduction Act (IRA), which aims to raise at least US$300 billion over a decade from corporate taxes, to fund different kinds of cleantech. In the E.U., The Green Deal seeks to raise and invest over US$1 trillion in public and private funding for cleantech initiatives by 2030.10

Meanwhile, the scale of China’s production capacity in green technologies, from EVs to photovoltaic cells, lithium batteries and wind power, dwarfs that of its rivals. This dominance allows Beijing to weaponise these supply chains the same way Washington has weaponised semiconductors.11

All this underscores the trend towards re-shoring, near-shoring and friend-shoring, which involves moving supply chains and activity hubs from overseas back inside national borders or closer to home, within the geographic confines of neighbours and trusted allies. Thus, European, Japanese and North American cleantech sectors look to reduce their dependence on China-sourced supply chains.

The six elements of techno-nationalism have produced a wider set of themes that are unfolding throughout the international landscape. They have instigated a fundamental reorganisation of the global economy, whereby strategic supply chains are bifurcating around U.S. and China-centric technology hubs.

Fuelled by a historic paradigm shift in the ‘West’, this reorganisation and bifurcation is prompting a gradual decoupling from China (beyond so-called ‘de-risking’) which, in turn, has exposed an epic paradox.

States and firms must now operate in a grey zone, where they are both strategic partners and adversaries with home and host governments, depending on where the geopolitical winds are blowing.

As such, as we seek to better understand techno-nationalism, we must take a closer look at each of these trends, below.

THE GREAT REORGANISATION

Techno-nationalism, along with climate change and the lingering effects of COVID-19, has accelerated a general recalibration of the global economy. Put another way: the world is undergoing a reorganisation. This effectively ends 30 years of what has been referred to as ‘hyper-globalisation’, which thrived from the late 1980s to around 2009. In hindsight, hyper-globalisation was a historic anomaly that owed its existence to the convergence of a unique combination of forces.

The first was the rapid diffusion of technologies of the 4IR, which delivered gains in computing power and connectivity along with a simultaneous decline in costs. The result was the lowering of barriers to entry across the global economy to a host of new participants, large and small. The second was the end of the Cold War and the implosion of the Soviet Union in 1991, which led to the brief American unipolar moment and paved the way for the third factor, China’s accession to the WTO in 2001 and its rise to superpower status.

4IR technologies enabled dispersion of global value chains and the offshoring of complex operations to far-flung places, especially China. For Beijing, this was a major power-leveller, and China was able to make up ground on a longstanding power disparity between the ‘West versus the Rest’, a term made famous by the historian Niall Ferguson.

Serendipitous timing of the 4IR, then, allowed the absorption of massive transfers of wealth, knowledge, technology and critical professional expertise, all in record time, and at spectacular scale.

Yet even as the free world became increasingly intertwined with China’s statist economic model, leadership in Beijing was working hard to advance modern history’s most ambitious and comprehensive techno-nationalist agenda.

America’s brief unipolar moment, from the 1990s to the 2010s, is clearly over. As it turned out, it was not just an anomaly, it was a false promise. But the ensuing backlash against China’s rise is fuelled in the West by a strong sense of betrayal (naïve, of course, from a realist’s point of view) which holds that China’s technocrats achieved ascendancy, in no small measure, through deception, stealth and trickery.

Hyper-globalisation began a steady decline with the onset of the global financial crisis of 2008/09. Its unravelling accelerated in 2016 with the BREXIT vote in the U.K. and the election of Donald Trump in the U.S.

There should be no mistake about the primacy of nationalism. We may have convinced ourselves that it went away during the height of globalisation, but that was self-deception.

Consider that during the COVID-19 pandemic from 2019 to 2021—a time, if ever there were one, for nations to come together and fight a common enemy—China, the E.U., the U.S., the U.K. and India all restricted the export of protective gear and medical equipment.12 This was quickly followed by vaccine nationalism and then vaccine diplomacy, with developed nations leveraging their stocks of vaccines as bargaining chips with poorer nations.

After the Russian invasion of Ukraine in 2022, shortages of wheat and other food commodities ensued. Within four months of the start of the war, some 35 nations had resorted to some form of ‘food protectionism’, which included export bans and taxes on critical foodstuffs.13

THE GREAT BIFURCATION

To be clear, the world is not ‘deglobalising’; instead, it is reorganising and reconfiguring around opposing techno-nationalist and geopolitical agendas. That reconfiguration largely involves a bifurcation into two technology blocs—one centred on the U.S. and its allies and the other centred on China. This bifurcation phenomenon is occurring around the twelve categories of foundational technologies, yet, paradoxically, non-strategic goods may see continued or even increased trade, even among rivals, so long as the world is not roiled in conflict. The question is, to what extent will decoupling from China occur before such a conflict arises?

In the physical realm, the tech bifurcation entails the fragmentation and restructuring of well-established supply chains. In the digital realm, the same forces are fracturing cyberspace: increased government intervention and activism are disrupting cross-border data flows and Balkanising the Internet and the platform economy, and this affects everything from banking and finance to social media networks.

No country anywhere can escape this reality. The inevitable outcome is not just a reorientation of the commercial landscape but of geopolitical realignments, as nations coalesce around mutual interests and attempt to navigate around new obstacles.

This has shaken up an already unsteady geopolitical status quo, as rifts widen between the G7 and BRICS countries (Brazil, Russia, India, China and South Africa) over, for example, sanctions on Russia for its invasion of Ukraine.14 By extension, Beijing’s support for Moscow has deepened these rifts, which will have consequences for technology transfer and the who-gets-what in the regrouping of supply chains and strategic partnerships.

Meanwhile, middle-tier countries such as Singapore, India, Vietnam and Mexico will have to navigate a more complicated landscape, even as they have become the destinations of choice for restructured supply chains. China’s path is far from certain, while many of the world’s less-developed countries will feel the brunt of a more fragmented, less inclusive international environment.

But the G7 and a handful of other liberal democracies are undergoing a moment of geopolitical ‘creative destruction’—if I may stretch Joseph Schumpeter’s economic term—and while this will erase some hard-earned gains in trade and commerce in the short term, the reconfiguration of global value chains will also present new growth opportunities for a lot of businesses.

A paradigm shift in the West is displacing an almost dogmatic belief in free markets and has moved the pendulum back in the direction of ‘managed trade’ and those two contentious words: industrial policy