Sheldon Anthony IO

Quantum Computing-as-a-Service (QCaaS) is an exciting opportunity for many people and organizations who want to harness the power of quantum technology. Quantum computers are very expensive, fragile, and difficult to operate. They require specialized hardware, software, and expertise that is not widely available or accessible. Cloud-based quantum computing services will offer access to quantum computers over the internet, allowing users to run their own programs and experiments on remote quantum devices without having to own or maintain their own. According to Gartner, by 2023, 95% of organizations researching quantum computing strategies will utilize QCaaS.^[1] 

Quantum computers are incredibly powerful machines, but they are also incredibly delicate. They require specialized environments that are cooled to near absolute zero, shielded from magnetic fields, and kept in a high vacuum. In addition to the logistical challenges, quantum computers are also prone to errors. This is because they are sensitive to even the slightest disturbances from their environment. As a result, quantum computers require frequent calibration to ensure that they are functioning properly. In an article published by CNET, operating a quantum computer costs $3,000 to $5,000 per hour, according to Jean-Francois Bobier, an analyst at Boston Consulting Group. ^[2] This makes them difficult and expensive to own and maintain, and it is not feasible for most organizations.

Mitsubishi is a Japanese conglomerate that operates in various industries, such as trading, finance, energy, machinery, chemicals, and automobiles. Mitsubishi Chemical’s mission is to create innovative solutions globally based on our core values of Sustainability, Health and Comfort, striving for the well-being of people, society and our planet Earth. The lithium atom is one of the lightest atoms on the periodic table. Its properties make it ripe for generating energy in combination with other elements. This blend of light weight and big energy potential is the key to its starring role in most 21st-century battery chemistry. Now consider today’s electric vehicles, powered by lithium-ion cells that have been improved, incrementally, for decades. But the lithium-ion batteries in any electric vehicle are still the heaviest part of the car. All that extra weight limits the potential of vehicle performance. By contrast, the promise of lithium-oxygen batteries, on paper, isn’t incremental at all. It’s a leap in how much energy a battery could produce versus how much it weighs. In theory, lithium-oxygen could be used for a more lightweight battery that can go much further with a single charge. The IBM Quantum team was approached by Qi Gao at Mitsubishi Chemical and Professor Naoki Yamamoto at Keio University to model and study the complex mechanism for lithium superoxide rearrangement, a key chemical step in lithium-oxygen batteries. Their collaboration lays the groundwork for simulating – and eventually, investigating a problem connected to a real-world application on a quantum computer. The research triumvirate of Mitsubishi Chemical, Keio University, and IBM Quantum is working to better understand lithium-oxygen’s potential as an energy source by using new algorithms that take advantage of quantum computing. Running a new breed of algorithms, within quantum’s completely new hardware environment and software, has already yielded quantitatively correct computational results of complicated chemical reaction in the discharge process of lithium-oxygen battery. Furthermore, by looking at molecular fundamentals through a new lens, researchers are also trying to mine new insights, and observe phenomena that are not generally accepted as known or expected.^[3] 

As a business owner, you should consider using QCaaS as a smart and strategic way to leverage quantum computing for your business. QCaaS can help you save time, money, and effort while enhancing your productivity, efficiency, and creativity. QCaaS can also help you gain a competitive edge in your industry, by enabling you to solve complex and challenging problems that are beyond the reach of classical computers. According to Next Move Strategy Consulting, the QCaaS market is expected to grow from USD 4 million in 2019 to USD 13 million in 2024, at a compound annual growth rate (CAGR) of 26.8%. ^[4] This indicates that more and more businesses are adopting QCaaS as a viable and convenient option for quantum computing. QCaaS can help you solve complex and challenging problems that are beyond the reach of classical computers, such as optimization, simulation, machine learning, and cryptography.

Before you start using QCaaS, you should have a clear idea of what you want to achieve with quantum computing, and what are your expectations from this technology. You should also assess your current capabilities and resources, such as your data, infrastructure, skills, and budget. This will help you determine whether QCaaS is suitable and feasible for your business, and how to use it effectively and efficiently. There are many providers and platforms that offer QCaaS, such as IBM, Amazon, Google, Microsoft, and others. Each provider and platform has its own advantages and disadvantages, such as the type, size, quality, availability, and performance of the quantum devices, the pricing and policies of the services, the features and functionalities of the software, and the support and feedback of the experts. You should compare and evaluate the different options available, and choose the one that best suits your needs and preferences. You should also consider the interoperability and compatibility of the provider and platform with your existing cloud infrastructure and services. Quantum computing is a new and complex technology that requires a lot of learning and experimentation. You should familiarize yourself with the basic concepts and principles of quantum physics, quantum algorithms, quantum programming languages, quantum devices, quantum simulators, quantum encryption methods, etc. You should also try out different quantum programs and experiments on remote quantum devices, and observe their results and performance. You should also learn from other users and experts in the quantum community, who can share their experiences and insights with you. You should also keep yourself updated with the latest developments and advancements in quantum research and development. Once you have learned and experimented with QCaaS, you can start developing your own applications and solutions for your business, using quantum computing capabilities such as optimization, simulation, machine learning, and cryptography. You can also integrate your quantum applications with your existing cloud infrastructure and services, such as data storage, processing, security, and analytics. You can then deploy and manage your quantum solutions across different environments and platforms, such as web, mobile, desktop, etc. You should also monitor and evaluate your quantum solutions regularly, and make improvements or adjustments as needed.