Search
A computer data science engineer works on a desktop with screen showing a lot of graphical data.

Quantum computing: Potential business use cases

Know more about how quantum computing is solving complex business challenges, revolutionizing industries qubit by qubit

2024.07.11Maximilian Walz

The quantum leap

Imagine a computer so powerful it can break the toughest code in minutes by exploring all possibilities simultaneously, like checking every door in a mansion at once for the key you found in a hallway. This supercomputer could revolutionize medicine and discover new materials. This isn’t fiction – it’s quantum computing, a groundbreaking technology in the making!

Quantum computing brings endless possibilities!

Unlike our everyday computer that flips bits between 0 and 1, quantum computers harness the eccentricity of quantum mechanics. What is the secret weapon? Qubits! Which can be both 0 and 1 at the same time (also called as superposition). This lets these computers calculate solutions differently than traditional computers, allowing them to solve problems in ways that would take traditional computers centuries.

In the 1980s, Richard Feynman, a visionary physicist, led the quest to unlock the potential of quantum computers. Since then, the race to translate quantum theory into tangible machines has intensified. While significant hurdles persist, quantum computing has transcended the realm of mere aspiration. The realization of large-scale quantum computers remains an ongoing pursuit, yet the potential to transform diverse scientific domains is undeniable.

Quantum technology demonstrates an entirely new computing paradigm, with the potential of tackling extremely complex problems beyond the capabilities of current computers. With its substantial promise and momentum, quantum computing stands out as a key trend. Let’s dive deeper into the extraordinary world of quantum computing through this blog.

Why quantum computing is becoming relevant: Potential use cases

The pursuit of quantum computing supremacy is on, with substantial investments flooding in. Governments, tech giants, and venture capitalists are all actively investing, accelerating the development of this revolutionary technology. But it’s not just an individual endeavor. In this collective effort, collaborations and partnerships are growing between tech companies, research institutions, and even competitors. It’s a shared vision that is driving even rivals to join forces to build quantum machines.

The technological advancements are nothing short of remarkable. Researchers are constantly pushing the boundaries, developing new qubit architectures and error correction techniques. It’s like a child taking baby steps and then, all of a sudden, sprinting across the hall! This progress is both remarkable and unpredictable. Quantum computing has immense potential to disrupt many scientific and technological fields. Here are some key areas where it shows particular promise:

  1. Security threat: Scalable quantum computers can leverage Shor’s algorithm to efficiently crack current encryption standards. This poses a significant geopolitical concern, driving heightened interest in the technology.
  2. Energy efficiency: The unique architecture of quantum computers might offer improved “energy-to-solution” ratios for specific problems compared to classical computers, potentially leading to significant energy savings.
  3. Computational powerhouse: Quantum algorithms enable novel approaches to computationally intractable problems. This has the potential to overcome limitations of classical computing and drive progress in three key areas:
    • Chemical simulation: The current methods for simulating complex quantum systems using classical computers are limited. Quantum algorithms offer the potential to significantly improve simulations, accelerating progress in drug discovery and other fields.
    • Enhanced AI: Research is underway to combine quantum and classical machine learning into hybrid models, aiming to improve training methods, classification accuracy, and overall model performance.
    • Optimization power: Certain quantum paradigms show promise for solving complex optimization problems, often likened to finding a needle in a haystack, with far greater efficiency. This could have a significant impact on optimization across various industries.

An essential point to note is that quantum technology is promising, but it is still at an early stage. Making the construction of large-scale, fault-tolerant quantum computers is a challenge. But research is progressing at a solid speed, and quantum computing has the potential to bring about significant advancements in these fields in the future.

Quantum computing: Where we stand today

Let’s understand where we stand in terms of progress in building a dream quantum machine.

Quantum hardware: Under construction

Imagine building a brand new kind of computer, one that uses the strange rules of the quantum world. That’s where quantum hardware is right now. Researchers are still examining the best way to build these machines; with different approaches such as trapped ions and superconducting qubits being explored. While they’re not ready to replace our laptops yet, there has been impressive progress in creating small-scale quantum computers.

Quantum software: Early days

Just like any computer needs programs to run, quantum computers need special software too. This “quantum software ecosystem” is still in its initial stages. Developers are creating new tools and languages specifically designed for these unique machines. It’s like learning a whole new way to talk to a computer, but with the potential to unlock incredible capabilities.

Policy and regulation: A work in progress

Quantum computing will be a powerful tool; but with great power comes great responsibility. That is why policy and regulation are essential for shaping the future of this technology. Here are some key areas of focus:

  • Security: Quantum computers could potentially crack the encryption codes that safeguard our online information and financial transactions. Governments and tech companies are working together to develop new, quantum-resistant encryption standards to stay ahead of the curve.
  • Competition: The race for quantum supremacy is heating up, with countries and companies vying for dominance. We can see three big blocks emerging: the US & Northern America, Europe, and China. Policymakers are striving to create a level playing environment that fosters innovation while preventing monopolies and engaging in geopolitics.
  • Ethical considerations: Quantum computing could have profound implications for fields such as artificial intelligence and biotechnology. Regulations are being formulated to ensure responsible development and prevention of misuse, such as designing of biological weapons.
  • Standardization: As the technology matures, establishing common standards for hardware and software will be crucial for collaboration and interoperability between different quantum systems. This will enable researchers and businesses to share knowledge and develop applications more efficiently.

A robust policy framework for quantum computing requires the establishment of a dynamic research environment with robust safeguards for emerging security and ethical concerns. This requires a continuous dialogue among policymakers, industry titans, and preeminent ethicists to ensure that this nascent technology is utilized for the benefit of the society as a whole.

Bridging the gap to quantum reality with T-Systems

A strong ecosystem is crucial for the development of quantum computing. This ecosystem encompasses hardware and software developers, as well as researchers and users. By lowering the entry barrier, more people will be able to participate in the quantum computing ecosystem, which will enable them to accelerate the development of the technology and access its full potential quickly.

While the undeniable power of quantum computing is hampered by its inherent complexity, our user-centric, multi-cloud platform fosters accessibility by streamlining the entry barrier. We provide end-to-end solutions that go beyond just the technology, with benefits such as:

  • Get started fast: Don't be intimidated by quantum computing. Our experts will guide you every step of the way, making the unknown a familiar path.
  • Simple to use: Forget complex platforms. Ours is user-friendly for easy access and program execution. Spend less time wrestling with the tech, more time tackling your challenges.
  • Solve real problems: Bridge the gap between quantum power and your industry's needs. Our team translates your classical problems into a quantum format, turning possibilities into solutions.
  • Reliable results: Focus on your problem, not technical glitches. Our platform ensures reliable computations, giving you confidence in your breakthroughs.
  • Collaboration: Collaborate seamlessly on groundbreaking discoveries. Share ideas, develop programs, and revolutionize the field together.

Through our holistic cloud-native approach, we help in developing and modernizing business operations for the quantum era, ensuring a smooth transition and maximizing the benefits. Our team of experts acts as your translator, breaking down complex solutions into actionable steps. Together, we bridge the gap between theory and application, making quantum future a reality for your business.

Our mission: Lowering the entry barrier to quantum computing and strengthening the ecosystem!

About the author
Maximilian Walz, Senior Product Owner - Quantum Computing

Maximilian Walz

Senior Product Owner - Quantum Computing, T-Systems CTO Office

Show profile and articles

Quantum computing: Potential business use cases

We look forward to your opinion

Do you have any ideas, suggestions, or questions on this topic? We cordially invite you to exchange ideas with us. Get in touch with us!
Do you visit t-systems.com outside of India? Visit the local website for more information and offers for your country.