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Contact Share By James Quach 18 March 2026 3 min read You’re late for an important appointment. Just as you are leaving your house, you realise your phone is flat. Imagine you could charge it almost instantly by exploiting the strange rules of quantum physics. That’s the promise of quantum batteries. My colleagues and I at CSIRO have developed [the world’s first quantum battery prototypes](https://www.nature.com/articles/s41377-026-02240-6) – and the direction the technology has taken is surprising. ### Collective quantum effects You may have heard of the peculiar [quantum effects](https://www.nist.gov/blogs/taking-measure/5-concepts-can-help-you-understand-quantum-mechanics-and-technology-without) of superposition and entanglement, which allow mostly very tiny objects to behave very strangely. They could also allow quantum computers to solve problems conventional computers cannot. One strange feature of the quantum world is what are called “collective effects”. They are what give quantum batteries their unique properties. Under the right circumstances, the storage units of quantum batteries don’t act individually, but behave collectively. In a counterintuitive twist, this means the units charge faster together than if they were charging alone. Let’s say your quantum battery has N storage units, and each unit takes one second to charge. Collective effects mean that if all units are charged at once, each unit will take only 1∕√N seconds to charge. This means that the bigger your quantum battery, the less time it takes to charge. If it doubles in size, charging will take just a little more than half as long. It is as if each unit somehow knows there are other units around, and their presence makes the unit charge faster. Strange, right? This is radically different from how conventional batteries work, where bigger batteries typically take longer to charge. That’s why it might take an hour to charge your mobile phone, but your electric car needs all night.  A quantum battery fabricated in CSIRO's quantum fabrication lab ### Building a quantum battery The idea of a quantum battery was just a theoretical curiosity for a long time. But back in 2018, I set out to demonstrate that they could actually be built. In 2022, working with colleagues in the United Kingdom and Italy, we built a [quantum battery prototype](https://www.science.org/doi/10.1126/sciadv.abk3160) using an organic microcavity – a kind of tiny, complicated multi-layer sandwich of several different materials that traps light in a particular way. And we were able to show for the first time the exotic behaviour where larger quantum batteries really do take less time to charge. In fact, we were able to demonstrate that the charging time decreases as 1∕√N, where N was the number of molecules in our battery. The more molecules we included, the faster the battery charged — exactly as theory had predicted. One thing this first prototype didn’t have was a way to extract the energy out of it. To do this, [in our latest study](https://www.nature.com/articles/s41377-026-02240-6), published in the journal Light: Science & Applications, we added extra layers into our device that converted the energy into an electrical current. This marks a major step towards a practical quantum battery.  CSIRO’s clean lab for engineering prototype quantum batteries ### Progress still to be made So, why aren’t we seeing quantum batteries in stores? Well, the capacity of quantum batteries is still tiny (a few billion electron-volts), and the time they hold their charge is fleetingly short (a few nanoseconds). This means quantum batteries are too small to power conventional devices such as your mobile phone, at least for now. But quantum batteries might be perfect for powering quantum devices such as quantum computers. In fact, quantum batteries could be the [exact solution](https://journals.aps.org/prx/abstract/10.1103/l39v-jwwz) quantum computers need to work at bigger scales and become practical. While we don’t have practical quantum batteries yet, we are currently working on ways to scale up our prototype’s size and extend how long it can hold its charge. We hope to create a hybrid design that combines the exceptional charging speed of the quantum battery with the long storage time of the classical battery. The progress we’ve made is a testament to the century of theoretical work done by quantum scientists before us. Our first prototype’s battery charge lasted nanoseconds. The Wright brothers’ first plane flight lasted little longer. Progress takes time – but quantum batteries are certainly on our horizon. This article is republished from *The Conversation* under a Creative Commons license. Read the [original article](https://theconversation.com/a-world-first-quantum-battery-charges-faster-when-it-gets-bigger-but-its-tiny-and-only-lasts-nanoseconds-276755). Dr James Quach leads CSIRO's Quantum Batteries Team. 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By James Quach 18 March 2026 3 min read You’re late for an important appointment. Just as you are leaving your house, you realise your phone is flat. Imagine you could charge it almost instantly by exploiting the strange rules of quantum physics. That’s the promise of quantum batteries. My colleagues and I at CSIRO have developed [the world’s first quantum battery prototypes](https://www.nature.com/articles/s41377-026-02240-6) – and the direction the technology has taken is surprising. ### Collective quantum effects You may have heard of the peculiar [quantum effects](https://www.nist.gov/blogs/taking-measure/5-concepts-can-help-you-understand-quantum-mechanics-and-technology-without) of superposition and entanglement, which allow mostly very tiny objects to behave very strangely. They could also allow quantum computers to solve problems conventional computers cannot. One strange feature of the quantum world is what are called “collective effects”. They are what give quantum batteries their unique properties. Under the right circumstances, the storage units of quantum batteries don’t act individually, but behave collectively. In a counterintuitive twist, this means the units charge faster together than if they were charging alone. Let’s say your quantum battery has N storage units, and each unit takes one second to charge. Collective effects mean that if all units are charged at once, each unit will take only 1∕√N seconds to charge. This means that the bigger your quantum battery, the less time it takes to charge. If it doubles in size, charging will take just a little more than half as long. It is as if each unit somehow knows there are other units around, and their presence makes the unit charge faster. Strange, right? This is radically different from how conventional batteries work, where bigger batteries typically take longer to charge. That’s why it might take an hour to charge your mobile phone, but your electric car needs all night. A quantum battery fabricated in CSIRO's quantum fabrication lab ### Building a quantum battery The idea of a quantum battery was just a theoretical curiosity for a long time. But back in 2018, I set out to demonstrate that they could actually be built. In 2022, working with colleagues in the United Kingdom and Italy, we built a [quantum battery prototype](https://www.science.org/doi/10.1126/sciadv.abk3160) using an organic microcavity – a kind of tiny, complicated multi-layer sandwich of several different materials that traps light in a particular way. And we were able to show for the first time the exotic behaviour where larger quantum batteries really do take less time to charge. In fact, we were able to demonstrate that the charging time decreases as 1∕√N, where N was the number of molecules in our battery. The more molecules we included, the faster the battery charged — exactly as theory had predicted. One thing this first prototype didn’t have was a way to extract the energy out of it. To do this, [in our latest study](https://www.nature.com/articles/s41377-026-02240-6) , published in the journal Light: Science & Applications, we added extra layers into our device that converted the energy into an electrical current. This marks a major step towards a practical quantum battery.  CSIRO’s clean lab for engineering prototype quantum batteries ### Progress still to be made So, why aren’t we seeing quantum batteries in stores? Well, the capacity of quantum batteries is still tiny (a few billion electron-volts), and the time they hold their charge is fleetingly short (a few nanoseconds). This means quantum batteries are too small to power conventional devices such as your mobile phone, at least for now. But quantum batteries might be perfect for powering quantum devices such as quantum computers. In fact, quantum batteries could be the [exact solution](https://journals.aps.org/prx/abstract/10.1103/l39v-jwwz) quantum computers need to work at bigger scales and become practical. While we don’t have practical quantum batteries yet, we are currently working on ways to scale up our prototype’s size and extend how long it can hold its charge. We hope to create a hybrid design that combines the exceptional charging speed of the quantum battery with the long storage time of the classical battery. The progress we’ve made is a testament to the century of theoretical work done by quantum scientists before us. Our first prototype’s battery charge lasted nanoseconds. The Wright brothers’ first plane flight lasted little longer. Progress takes time – but quantum batteries are certainly on our horizon. This article is republished from *The Conversation* under a Creative Commons license. Read the [original article](https://theconversation.com/a-world-first-quantum-battery-charges-faster-when-it-gets-bigger-but-its-tiny-and-only-lasts-nanoseconds-276755). Dr James Quach leads CSIRO's Quantum Batteries Team.