Nothing Compares to Q: Why Quantum Computing Will Redefine Our World | HackerNoon

The first time I tried to explain quantum computing to my parents, I failed spectacularly.

I told them it was like using magic to solve math. My mom asked if that meant the computer could help someone win the lottery. My dad thought it sounded like nonsense.

And you know what? They’re not entirely wrong.

Quantum computing might sound strange at first, but it’s based on real science that pushes the limits of what we thought computers could do.

Instead of working with just 0s and 1s like regular computers, quantum systems can hold multiple states at once. They use particles that stay connected across distance and process information in completely new ways.

This allows them to solve problems that would take today’s fastest supercomputers millions of years in a much shorter time.

So, it does sound like nonsense until you realize it’s already happening.

Why Regular Computers Aren’t Enough Anymore

The computers we use today, from your smartphones to the server farms running OpenAI, are built on binary codes. 0s and 1s. These systems use this code to interpret operational commands and user input, then deliver an appropriate response to the user.

But as we try to solve more complex problems in areas like AI, climate science, drug development, and cybersecurity, classical computers are struggling to keep up. They need more processing power, energy, time, and cost.

Quantum computing provides a new path forward.

Training advanced AI models like GPT-4 is expensive and resource intensive on a massive scale. There are thousands of GPUs running non-stop for weeks, burning through energy and money at an unsustainable rate. And this extends beyond artificial intelligence.

Try simulating how a few molecules behave in a new drug, and even the fastest supercomputers will struggle. Why? Because the number of possible interactions grows exponentially, and classical systems have to check each one, step by step.

In short, the more complex the problem, the sooner we reach a limit. Classical computing wasn’t designed to handle this scale, but quantum computing can.

How Quantum Computing Really Works

A quantum computer uses quantum mechanics to handle information in a totally different way compared to regular computers.

Rather than use bits that are either 0 or 1, quantum computers use quantum bits called qubits. These qubits can be both 0 and 1 at the same time.

Imagine flipping a coin and having it land on both heads and tails at the same time. This happens because of a property called superposition.

Qubits can also be entangled. This is when the state of one qubit is instantly tied to another, no matter their distance. Entanglement allows quantum computers to work on many things together at the same time.

Quantum computers use special operations (quantum gates) to change and control qubits so they explore many possible solutions to a problem all at once.

When the computer measures the qubits, they settle on one answer. This is, of course, much faster than classical computers, which find answers by checking each possibility one by one.

It’s okay if you’re still a bit confused. You’re not supposed to intuitively grasp quantum mechanics; even Einstein wasn’t a fan.

But simply put, a quantum computer doesn’t solve problems step by step. It explores every possible solution path at once, collapses to the right answer, and moves on.

And while the systems are still noisy and error-prone, quantum computing is improving fast.

Companies like IBM, IonQ, PsiQuantum, and Rigetti are already making real progress toward scaling fault-tolerant logical qubits and building clusters capable of powering useful quantum computing applications.

Once we crack that threshold, the dominoes fall.

Is Quantum Computing Only About Speed?

Most people think quantum computing will just make things faster. And sure, it will. But more importantly, it will change what’s computable.

There are certain problems that classical computers simply cannot solve in any practical timeframe.

For instance;

• Optimizing logistics across a global supply chain with trillions of permutations.
• Predicting how a new drug molecule will behave in the human body.
• Simulating nuclear fusion reactions to build clean energy.
• Cracking the cryptography that secures our online lives (or replacing it with quantum-proof encryption).

These aren’t tasks we can wait longer to solve. They’re intractable, but quantum computing makes them tractable.

Some of the other advantages of quantum computing over classical computers include:

1. Quantum Uses Way Less Energy Than You’d Think

Quantum is energy efficient. Quantum computers could do the same work as today’s supercomputers using far less energy.

A classical supercomputer can suck down as much energy as a small town, but quantum computers will do the same job with as little energy as what a coffee maker uses.

As the world builds more AI systems, electric vehicles, and smart infrastructure, Quantum could become a low-energy alternative that also processes faster.

2. Quantum interacts powerfully with AI.

If you think AI is at its peak now, wait till it gets quantum steroids.

These technologies complement each other. Quantum algorithms can exponentially accelerate AI training and inference. Meanwhile, AI is already helping improve quantum error correction and circuit design.

It’s a virtuous cycle: AI helps to improve quantum systems while the quantum system improves the efficiency and speed of AI. Together, they can unlock use cases we can’t fully imagine yet.

Imagine an AI model that can simulate global climate systems down to the square meter. Or personalize cancer treatment plans by running millions of biological permutations in minutes. We’re not that far off.

Who Wins the Quantum Race?

Spoiler alert: this is about power.

China is pouring billions into national quantum programs. The EU isn’t far behind. The U.S. is betting big on private sector leadership, and to be fair, the startup ecosystem is alive and kicking.

This race could give each side economic leverage, cybersecurity dominance, drug pipelines, and defense. Whoever gets to scalable, fault-tolerant quantum first, wins.

So, What Should You Do?

Quantum computing won’t replace your laptop tomorrow. It won’t magically solve climate change. And no, it won’t help you win the lottery.

The truth is, quantum computers have only been proved as a better alternative than classical computers in the lab, not in the real world yet.

Quantum bits are still extremely fragile, and are affected by tiny environmental changes, which would make them prone to errors.

But with time, it can redefine what problems are solvable, and who gets to solve them.

So read up. Follow the qubit count. Watch the startups. If you’re a developer, start playing with quantum simulators. If you’re a founder, start thinking about what your product would do if computers were no longer a limitation.

The next generation of breakthroughs won’t be built despite quantum. They’ll be built because of it.