TY - JOUR

T1 - A classical to quantum transition via key experiments

AU - Scholz, Ruediger

AU - Wessnigk, Susanne

AU - Weber, Kim Alessandro

N1 - Funding Information: This work has been supported by DQ-mat (SFB1227).

PY - 2020/9

Y1 - 2020/9

N2 - This paper presents an educational concept for promoting quantum teaching and learning via an educational structured quantum optical experiment. The experiment is designed to demonstrate the striking differences between classical physics and quantum physics, for example quantum interference of unbreakable photons (the ability of probabilities to interfere due to a phase sensitive superposition of states) and quantum nonlocality (there is no way to locate photonic states without a fundamental loss of information about the characteristics and a complete change of the state). For this proposal, we developed an experimental setup straightforward enough to be used in advanced physics courses even in secondary school student labs. To explain, or in a more quantum-semantic way, to interpret the experimental results quantitatively, we provide an appropriately rigorous quantum optical theory. Our model combines Laplace statistics (to access the statistical behaviour of photon counting) and basic vector calculus to calculate probabilities from the phase sensitivity of probability amplitudes. This article aims to contribute to further discussion and empirical research into novel teaching strategies for a more deeply conceptual approach to quantum theory.

AB - This paper presents an educational concept for promoting quantum teaching and learning via an educational structured quantum optical experiment. The experiment is designed to demonstrate the striking differences between classical physics and quantum physics, for example quantum interference of unbreakable photons (the ability of probabilities to interfere due to a phase sensitive superposition of states) and quantum nonlocality (there is no way to locate photonic states without a fundamental loss of information about the characteristics and a complete change of the state). For this proposal, we developed an experimental setup straightforward enough to be used in advanced physics courses even in secondary school student labs. To explain, or in a more quantum-semantic way, to interpret the experimental results quantitatively, we provide an appropriately rigorous quantum optical theory. Our model combines Laplace statistics (to access the statistical behaviour of photon counting) and basic vector calculus to calculate probabilities from the phase sensitivity of probability amplitudes. This article aims to contribute to further discussion and empirical research into novel teaching strategies for a more deeply conceptual approach to quantum theory.

KW - conceptual change

KW - interferometry

KW - Key Experiment

KW - knowledge in pieces

KW - quantum optics

KW - quantum physics

KW - single-photon experiment

UR - http://www.scopus.com/inward/record.url?scp=85092902410&partnerID=8YFLogxK

U2 - 10.1088/1361-6404/ab8e52

DO - 10.1088/1361-6404/ab8e52

M3 - Article

AN - SCOPUS:85092902410

VL - 41

JO - European journal of physics

JF - European journal of physics

SN - 0143-0807

IS - 5

M1 - 055304

ER -