By Qamar Bashir
Oil has been a dominant force shaping global economies over the past two centuries,
acting as both a maker and breaker of fortunes. Fluctuations in oil prices and supply chain
disruptions have historically been a nightmare for governments worldwide. Low oil
prices in the mid-20th century encouraged the production of large, fuel-inefficient
vehicles, the conversion of coal-based power plants to oil-based ones, and the industrial
shift to oil as a primary energy source. This transition boosted the economies of oil-
producing nations, significantly raising the quality of life for their populations. Once
regarded as an efficient and clean source of energy, oil—often called "black
gold"—evolved into a potent political and security tool for oil-rich nations.
By the mid-1970s, oil-producing countries, especially OPEC members, realized the
political leverage and economic influence they wielded. The 1973 oil embargo, led by
Arab nations, demonstrated how increased oil prices could disrupt global economies and
even trigger regime changes. Oil became a weapon that could bring even powerful
nations to their knees. In response, oil-importing nations began transforming their
industries by developing nuclear power plants and producing fuel-efficient vehicles.
However, their reliance on oil persisted. Devastating nuclear plant disasters, such as
Chernobyl (1986) and Fukushima (2011), shifted the focus towards renewable energy
sources.
Scientists explored several options to reduce dependence on oil, including nuclear fusion,
where hydrogen atoms fuse to form helium, releasing immense energy. However, the
extreme heat generated by fusion reactions proved too intense for any material currently
known to mankind to withstand, making the technology unviable for practical energy
generation. Alcohol-based fuels, like ethanol blends, were also introduced as alternatives,
but motorists often criticized their performance. This compelled scientists to turn to
renewable energy sources such as wind, ocean waves, and solar power as the most
promising avenues for reducing reliance on oil. Among these, solar energy emerged as a
frontrunner, steadily challenging the dominance of "black gold" with increasing
effectiveness.
Recognizing the vast potential of solar energy, countries around the world began making
substantial investments in developing innovative technologies to harness it. Global
investment in solar energy has surged, with China leading at over $100 billion in 2023,
pioneering perovskite-silicon tandem cells with efficiencies exceeding 30%, and
dominating low-cost panel production. The United States follows, investing $56 billion,
achieving breakthroughs like quantum dot solar cells with 39.5% efficiency and advanced
grid-scale storage. India, at $25 billion, excels in agrivoltaics and bi-facial cells (22%
efficiency), while Germany, with $19 billion, advances thin-film solar cells (26%
efficiency) and decentralized storage. Japan, investing $17 billion, developed multi-
junction cells achieving 47% efficiency and floating solar farms.
The global shift to solar energy has enabled significant economic savings by reducing
reliance on oil imports. China leads with annual savings of $13 billion through extensive
solar adoption in industries, followed by the United States at $11 billion due to reduced
oil usage in power generation. India saves $9 billion annually, leveraging solar for rural
electrification and industrial needs, while Germany's $8 billion savings result from
replacing oil-fired power plants. Japan ($6 billion) benefits from residential and industrial
solar systems, and Australia ($4.5 billion) achieves savings through rooftop solar and
large-scale farms. Collectively, the top ten sunshine gold nations save over $60 billion
annually, demonstrating solar energy's role in enhancing energy security and cutting
costs.
If solar cell efficiency continues to improve, reaching consistent 40-50% efficiency in the
coming decades, solar energy could progressively replace oil across various sectors. By
2035, solar could significantly reduce oil demand for electricity generation, which
accounts for 10-15% of current usage, especially with advancements in energy storage
and grid integration. By 2050, with widespread adoption and enhanced technology, solar
could replace 70-80% of global oil demand, particularly in electricity, transportation (via
electric vehicles), and industrial heating. A complete replacement of oil by solar energy is
plausible by the 2060s, contingent on overcoming technological, political, and
infrastructural barriers.
This transition would bring profound economic changes. Oil-importing nations would
save trillions, enhance energy security, and reduce geopolitical risks, while oil-exporting
countries could face severe economic disruptions, necessitating diversification. Global
energy markets would shift towards renewables, fostering job creation in solar industries
but challenging oil-dependent economies. Additionally, transitioning to solar energy
would significantly reduce greenhouse gas emissions, offering environmental and health
benefits.
Good news is that sunshine gold (solar energy) does not hold the same economic and
security value for producing and consuming countries as black gold (oil). For sunshine-
producing countries with abundant sunlight, solar energy offers economic opportunities
through domestic use and export, but unlike oil, it cannot be monopolized or wielded as a
geopolitical weapon. Solar energy’s decentralized nature makes it accessible to many,
reducing the ability of any one country to dominate it.
For sunshine-consuming countries, solar energy provides significant economic benefits
by lowering energy costs and enhancing energy security, reducing reliance on foreign oil.
However, the security value of solar energy will depend on technological advancements,
such as storage and grid infrastructure, and international cooperation.
To foster a win-win situation between sunshine-rich and non-sunshine countries, the
global community must right now prioritize equitable collaboration in renewable energy
development and trade. This would involve cross-border energy sharing through
advanced grids and storage technologies, technology transfer, and joint R&D to adapt
renewables to diverse climates. Establishing global green funds, fair carbon credit
systems, and hybrid energy solutions can ensure financial and energy access equity.
In addition, international cooperation should be emphasized for fair revenue distribution,
capacity building, and private sector engagement, alongside ethical resource management
and community empowerment.
By integrating diverse renewable energy sources, fostering innovation, and strengthening
global climate agreements, the global community should create a sustainable and
inclusive energy future that addresses economic disparities and mutual dependencies.
