2020-08-31 15:57:00

A Quantum Leap in Our Understanding of the Quantum World, After Half a Century

2020-08-31 15:57:00 | Share this post:

As a physical theory for predicting observations at the (subatomic) microscopic level, quantum theory is essentially impeccable. However, on the applicability of the theory at the macroscopic scale, there is still hardly any agreement among the physics community. In particular, scientists have long known that if Nature is to conform to the predictions of quantum theory (at all scales), then some commonly held beliefs would have to give way. There is, however, again no consensus on what should be dismissed.

 

Through international collaboration with Griffith University, Australia, Associate Professor Yeong-Cherng Liang, a member of QFort showed that even if we drop one of the 4 premises used in establishing the existing no-go result due to Bell, we still have an incompatibility between quantum predictions and 3 widely-held beliefs. This marks an important breakthrough, after half a century, in our understanding of the world depicted by quantum theory. The scientific findings have since been published in the world-leading peer-reviewed journal Nature Physics in mid-August.

 

Associate Professor Yeong-Cherng Liang

 

Liang said, "Since the 1960s, physicist John Bell already showed that if quantum theory is to be universally applicable, we would have to give up one or more physical principles that most people would take for granted. More precisely, in the language of the present work, the following 4+1 premises cannot hold true simultaneously: (1) Absoluteness of Observed Events: an observed event is a real, single, event, rather than being well-defined only with respect to individuals (2) No superdeterminism: an observer could choose his/ her measurements in a way that is independent of the system to be measured (3) Locality: given sufficient knowledge of the past, local measurement outcome cannot be correlated with measurements carried out in a spacelike separated manner (4) Outcome independence: even given the outcome of a spacelike separated measurement, theoretical probability of a local measurement outcome does not change (5) Universal validity of quantum theory: quantum theory is universally valid in its prediction of outcome probabilities."

 

Liang drew the following analogy “We may envisage 5 food ingredients that individually make an excellent pot of soup with a similar flavor, but when put together, they result in something that has an awful taste.” He added, “We have no idea why this is so nor the culprit that should be disposed of to salvage the food.” To appreciate the significance of this work, he further remarked that one needs to first get acquainted with the world depicted by quantum theory: “observation” or “measurement” is a crucial aspect of the theory. He said "The general view is that states of affairs are only determined after a measurement. To some extent, this is responsible for the peculiar Schrödinger’s cat, which is both “dead” and “alive”, and the famous question by Einstein on whether one really believed that the moon was not there when no one looked at it."

 

Also predicted by the theory is the notion of “incompatible properties”. For example, in the quantum world, the position and the momentum of a particle represent a set of incompatible properties, i.e., they are not simultaneously well-defined. This is highly counterintuitive when seen from our day-to-day experience. Take a moving car as an example. If this were to be a “quantum car”, then we would only be able to measure precisely the car’s velocity or its position but never both at the same time.

 

Returning to the seminal discovery by Bell, Liang remarked, “A rejection of (1) denies, to some extent, the existence of an objective world external to oneself. This means that when scientists explore Nature, they may also have to specify to whom this Nature is defined. Absurd! Premise (2) is an implicit assumption of the scientific method: if we could not freely decide which property of a system we would like to determine, how can we go about determining the properties of each individual system, and how could we do a medical trial for COVID-19 treatments?” He further clarified, “Einstein’s theory of relativity, which most physicists would hold fast, has provided the basis for premise (3). Due to the success of quantum theory, many physicists would also tend to believe in assumption (5), i.e., on the universal applicability of quantum theory. Consequently, most people have presumably opted to give up premise (4) in view of Bell’s no-go theorem."

 

However, this international collaboration showed that even if we assume only (1), (2), (3), and (5), we would still obtain a contradiction. This is shocking to all those who feel that they have found a way out by rejecting premise (4). After all, premise (4) was not at all involved in the strengthened no-go result. Who then is the culprit? Long ago, the Hungarian physicist Eugene Wigner already raised his doubt on the universal validity of quantum theory. Indeed, the present work has exploited a thought experiment that he proposed decades ago. To some physicists, this has provided further evidence to reject the hypothesis that “quantum theory is applicable at the macroscopic scale”, i.e., the theory has to be revised somehow. There are also a number of physicists who believe that premise (1), i.e., the absoluteness of observed events, has to be given up. Even though the present work does not tell us which of these premises is to be given up, it still marks important progress in the development of theoretical physics as it puts further nontrivial constraints on how all future physical theories that are empirically adequate. In fact, apart from this theoretical finding, the team has also carried out a microscopic experiment showing that strong correlations invalidating the simultaneous validity of premise (1), (2), and (3) can in principle be carried out.

 

Also worth noting are the interesting remarks from one of the team leaders behind this collaboration, “Our dream experiment is one where the ‘friend’ is a human-level artificial intelligence program running on a massive quantum computer. I think that would be a pretty convincing test of whether quantum theory fails for observers, or whether one of the three fundamental assumptions is false. But that’s probably decades away.” said Prof. Howard Wiseman from Griffith University. He added, “It has long been recognized that quantum computers will revolutionise our ability to solve hard computational problems. What we didn’t realise until we started this research is that they may also help answer hard philosophical problems -- the nature of the physical world, the mental world, and their relationship.”

 

Source: NCKU News Center 

 

Further Reading

This Twist on Schrödinger’s Cat Paradox Has Major Implications for Quantum Theory

> Quantum Paradox Points to Shaky Foundations of Reality

> Quantum Paradox Suggests the Fabric of Our Reality Is Inconstant

 

     

Share this post:

Related articles

量子記憶體高效檢測法 成大研究登國際指標期刊《PRX Quantum》

2022-05-24 08:00:00

Research Highlights

量子記憶體(Quantum memory)檢測效能重要突破!國立成功大學前沿量子科技研究中心主任陳岳男與博士後研究員古煥宇,攜手歐亞跨國團隊發展新穎的「量子網路中記憶體之效能檢測」方法,提出判定合格量子記憶體的新方向,有助臺灣掌握量子...

Read More

革命性超穎介面光學:跨足基礎物理與應用科學的突破

2023-11-13 15:00:00

Research Highlights

近期,成大光電系的吳品頡副教授在瞬間高光譜影像與非厄米超穎介面系統的任意偏振態控制這兩個領域取得的長足的進展,兩項研究成果接續發表在國際頂級學術期刊Nature Communications。品頡表示,這兩個研究工作都是跨團隊的合作,...

Read More

下世代超輕薄可捲曲晶片 張景皓團隊找出可撓式奈米科技關鍵

2022-07-19 11:40:00

Research Highlights

超輕薄,可捲曲,豐富應用性的晶片不再是夢想。國立成功大學物理系副教授兼成大前沿量子科技研究中心張景皓與其團隊,共同分析「石墨烯」材料,發現捲曲後有新的獨特應用功能性,為此與團隊投入研究,從無到有,建立起基礎物理(量子態)模型。研究成果...

Read More

NCKU Transnational Research Team Develops First All-electric Spin Transistor

2015-02-05 11:13:00

Research Highlights

Scientists have long been puzzled by the spin-field-effect transistor (spin FET) and great efforts have been put in...

Read More