Skip to main content

Thank you for visiting nature.com. You are using a browser version with limited support for CSS. To obtain the best experience, we recommend you use a more up to date browser (or turn off compatibility mode in Internet Explorer). In the meantime, to ensure continued support, we are displaying the site without styles and JavaScript.

The Young-Feynman controlled double-slit electron interference experiment

Abstract

The key features of quantum mechanics are vividly illustrated by the Young-Feynman two-slit thought experiment, whose second part discusses the recording of an electron distribution with one of the two slits partially or totally closed by an aperture. Here, we realize the original Feynman proposal in a modern electron microscope equipped with a high brightness gun and two biprisms, with one of the biprisms used as a mask. By exciting the microscope lenses to conjugate the biprism plane with the slit plane, observations are carried out in the Fraunhofer plane with nearly ideal control of the covering of one of the slits. A second, new experiment is also presented, in which interference phenomena due to partial overlap of the slits are observed in the image plane. This condition is obtained by inserting the second biprism between the two slits and the first biprism and by biasing it in order to overlap their images.

Introduction

Recent advances in electron optics, nanotechnology and specimen preparation have resulted in many studies on the experimental realization of the double-slit thought or gedanken experiment, which was described by Feynman as containing all of the mysteries of quantum mechanics1,2, using single free electrons.

The Young-Feynman experiment consists of three parts. The first part involves the observation of interference fringes in a double slit setup3,4,5,6 and their build-up using single electrons7,8. Two beam interference patterns can be observed using a Möllenstedt-Düker electron biprism9,10, which has proved to be the most versatile method for carrying out interferometry and holography experiments (see, e.g.11,12,13 for reviews). The build-up of two beam Fresnel interference fringes using single electrons was first demonstrated using an electron biprism as a wavefront beam splitter14,15. The second part of the Young-Feynman experiment involves a comparison of electron distributions recorded before and after one of the slits is closed16. Its analysis leads to the idea of the probability amplitude. It has been performed in a controlled manner by stopping one of the two beams in the Fraunhofer image of an electron biprism17 or in the Fresnel image of two slits8. The third part of the Young-Feynman experiment, which has subsequently been renamed the which-way (or which-path) experiment, aims at demonstrating that interference phenomena disappear when the setup is modified to obtain information about which slit the electron passes through. First experiments in this direction have been carried out by preparing nano-slits and depositing a layer of amorphous material using modern nanotechnology tools on one18 or both19 of them. Inelastic scattering in the material can be regarded as a dissipative process during the interaction, which is responsible for the localization mechanism20,21.

Here, we focus on the second part of the Young-Feynman experiment, which refers to the change in the interference pattern when one of the two slits is partially or totally obstructed in a controllable way. It is then possible to observe the transition of the diffraction pattern from the two- to the one-slit configuration, highlighting the wave-particle duality of the electrons. Although conceptually and mathematically simple, at least from the point of view of wave optical analysis22,23, its experimental realization is a very challenging task that requires advanced technology and instrumentation, as demonstrated by the partial success of former attempts8,17. After describing the drawbacks of former setups, we show how they can now be overcome by using a modern electron holography microscope that is equipped with two electron biprisms and a high brightness gun and how a new version of the experiment, in which the fringes are observed in the image instead of the Fraunhofer plane, can be realized.

Analysis of Earlier Experiments

We first recall a few basic concepts in electron optics and microscopy. In general, the illumination system comprises an electron source followed by a system of condenser lenses, which demagnify the source, so that partial coherence does not blur the desired interference phenomena. As a result of the small de Broglie wavelength of high energy electrons, a further system of magnifying lenses is necessary so that interference fringe details can be resolved by an electron detector in the final recording plane. This plane can be optically conjugate to the observation plane OP, which can be the specimen plane if a gaussian image is desired, or the Fraunhofer diffraction plane (coincident with the back focal plane of the imaging lens for plane wave illumination) if a diffraction image is desired. The possibility of continuously varying the excitations of the electron lenses also allows planes in the Fresnel region between these two primary planes to be imaged.

In the first experiment in which an electron biprism was used as an interferometry device17, a biprism was inserted in the normal specimen plane, where it could be biased in a specimen holder with contacts connected to an external voltage source. Two beam interference fringes could be observed in the observation plane OP, which was situated in the Fresnel region with respect to the biprism, as the standard gaussian image only showed its bare dark shadow. In order to stop one of the two beams passing to the left and right of the biprism, it was necessary to use an aperture A, which was inserted in a region where they were widely separated, corresponding approximately to the back focal plane of the imaging lens (i.e., the Fraunhofer plane), as shown in Fig. 1(a).

Figure 1
figure1

Controlled two beam experiment using an electron biprism. (a) Schematic diagram. (b) Simulated line profile across a Fraunhofer image of the biased electron biprism. (c) Corresponding Fresnel diffraction pattern in the observation plane OP. (d) Fraunhofer image of the biased electron biprism with an aperture A stopping the left beam. (e) Fresnel image of the complementary half-plane, with the fringes in the geometrical shadow region amplified by a factor of 10.

As a result of the features of the electron microscope that was used17, in which the aperture A was the selected area aperture, it was necessary to form the diffraction image of the biprism in this plane by working in the “low angle diffraction” mode24 by weakly exciting the standard objective lens (which then acted as a condenser lens) and using the following lens, the so-called diffraction lens, as an imaging lens. By changing the excitation of this lens, it was also possible to image a Fresnel plane, with the interference fringes in the overlapping region. This was not a real plane, as shown in Fig. 1 (for reasons of clarity), but a virtual plane in the actual experiment.

From the point of view of the interpretation and simulation of the results, it should be noted that not all of the experimental details are included explicitly in the simulations, which are usually referred to the object space with plane wave illumination. As the dimensions of the biprism and the slits are much larger than atomic dimensions, spherical aberration can be neglected and the standard theory of paraxial imaging, which has been described for both light optics22,25 and electron optics23,26, can be applied. When the process of image formation is described in the object space, propagation from the object to the Fraunhofer plane (i.e., the back focal plane of the imaging lens) can be described by a Fourier transform, while that from the back focal plane to the image plane can be described by an inverse Fourier transform. The effect of observing a Fresnel plane is accounted for simply by multiplying the spectrum by a quadratic phase factor23,25. This approach is also useful for numerical calculations, which make use of Fast Fourier Transforms. Here, Mathematica software27 was used to perform simulations.

Figure 1(a) illustrates the electron biprism setup that was used by Matteucci and Pozzi17. It involved the use of an aperture A to stop one of the two beams passing to the left and right of the biprism in a region where they were widely separated, corresponding approximately to the Fraunhofer plane behind the imaging lens. However, when the Fraunhofer image in this setup (Fig. 1(b)) is analyzed in detail, a weak system of diffraction fringes is found to be present in addition to the two bright spots that correspond to the two tilted half planes to the left and right of the biased biprism. These diffraction fringes are responsible for a modulation of the diffraction envelope of the corresponding two beam Fresnel interference image in the observation plane OP (Fig. 1(c)). As a result, even though aperture A in the Fraunhofer plane is able to completely block one of the spots, it fails to remove the faint fringes that originate from the Young diffracted waves at the edges of the biprism and the electrons are therefore not completely stopped (Fig. 1(d)). Both the simulation shown in Fig. 1(e) and the experiment17 show faint interference fringes (amplified by a factor of ten in Fig. 1(e)), primarily in the region of the geometrical shadow, where the intensity is expected to decrease continuously with distance for an opaque half plane22. The simulations start from the transmission function of the electron biprism23. Its Fourier Transform gives the Fraunhofer diffraction image shown in Fig. 1(b), while its Fresnel transform (which is obtained by multiplying the Fraunhofer diffraction image by the Fresnel factor) gives the image shown in Fig. 1(c). If an aperture is inserted in the Fraunhofer plane, then it cuts part of the Fraunhofer image (Fig. 1(d)) and its effect on the corresponding Fresnel image is shown in Fig. 1(e). A further drawback of this setup, which was used in previous experiments, was that experimental control over aperture A was not accurate enough to allow part of the diffracted spot to be intercepted, meaning that only open and closed states could be realized.

Figure 2(a) shows the closest previous setup to the original Feynman proposal. This experiment was realized by Bach and co-workers8 on a dedicated electron optical bench and aimed to intercept electrons passing through one of two slits by using a movable mask M. However, as the mask could not be in the same plane as the slits but had to be placed some distance below them in the Fresnel region, it intercepted not the slits but their image in the mask plane (Fig. 2(b)). Observations were carried out by recording the Fraunhofer pattern of the slits (Fig. 2(c)). When the mask edge was exactly below the edge of the right slit (Fig. 2(d)), i.e., when all of the corresponding electrons should have been intercepted from the point of view of geometrical optics, a large fraction of them was still found to contribute to the Fraunhofer image, which displayed two beam interference fringes (Fig. 2(e)). These detrimental effects can be seen both in the experimental images of Bach and co-workers and in simulations reported in the Supplementary Information of their paper8. The simulations shown in Fig. 2 were carried out using their experimental parameters and confirm their results. The object transmission function is now that of two slits. The image is propagated to the aperture plane by multiplying the Fraunhofer image (Fig. 2(c)) by the Fresnel factor, resulting in Fig. 2(b). By taking into account the effect of the aperture (Fig. 2(d)), the original Fraunhofer image is modified, as shown in Fig. 2(e).

Figure 2
figure2

Controlled diffraction experiment with two slits and a mask M in the Fresnel region below the slits. (a) Scheme. (b) Fresnel image of the two slits in the plane of the mask M. (c) Corresponding Fraunhofer image. (d) Fresnel image of two slits with the mask M positioned exactly at the edge of the geometrical image of the right slit. (e) Corresponding Fraunhofer image.

The Ideal Controlled Beam Interference Experiment in the Fraunhofer Plane

A solution to the previous drawbacks and to the realization of a clear controlled beam interference experiment can be achieved by using an extra lens after the slits to form a magnified image of the slits instead of the Fraunhofer image. If an aperture is placed in such an intermediate image plane, which is conjugate to the object plane of the slits, then the ideal situation can be realized. The aperture acts as a virtual mask in the object plane, which can be used to cover one of the slits precisely, avoiding the detrimental effects that result from its placement in the Fresnel region.

A more detailed set up is shown in Fig. 3, which shows that the image of the two-slit specimen is focused by the objective lens in the intermediate image plane, where a biprism wire can be used as a very sharp mask. In the back focal plane of the intermediate lens, a Fraunhofer image is formed, followed, along the optical axis, by a gaussian image in the image plane. Both of these planes can be imaged by suitably exciting the remaining imaging lenses of the microscope, which are not shown in Fig. 3. The electron optical requirements that are necessary for realizing this experiment can now be satisfied, as described below.

Figure 3
figure3

Sketch of the experimental setup (left) and of the corresponding ray path (right) for the ideal controlled two beam interference experiment in the Fraunhofer plane. An intermediate image of the two slits is formed by the objective lens in a plane in which a metallic wire, which is completely opaque to the electron beam, can be positioned with high accuracy to modify the electron transmittance through one of the two slits in a controlled way, acting in this way as a very sharp movable mask.. The position of the wire can be checked with the microscope in image mode. By switching the microscope to diffraction mode, it is possible to record the intensity in the Fraunhofer plane, thereby showing the fringe pattern of the Young-Feynman two slit experiment as a function of wire position, i.e., of the electron path localization.

Figure 4(a,c,e,g) shows experimental Fraunhofer images, which were recorded using a camera at the end of a post-column Gatan imaging filter (GIF) in Lorentz mode, in order to have a sufficiently long camera length to image the interference fringes within the central maximum of the diffraction envelope. It is interesting that the weak single slit diffraction fringes in the perpendicular (vertical) direction are nearly square, as the lengths of the slits are nearly equal to their separation (e.g.6). Focused images of the slits, which are shown in Fig. 4(b,d,f,h), were recorded both before and after recording the diffraction images, in order to detect any drift of the biprism. In Fig. 4(b), the right slit is completely open and a standard two beam interference image is obtained. In Fig. 4(d), the biprism has been moved in such a way that the right slit is approximately half open, whereas in Fig. 4(f) only a small fraction of the electron beam is allowed to pass through the right slit. In Fig. 4(h), the right slit is completely blocked, the interference fringes have disappeared completely and only the diffraction image of the open left slit remains.

Figure 4
figure4

Two slit controlled electron beam experiment, showing the use of a mask placed in the conjugate plane of the slits to progressively cover the right-hand slit (right) and its effect on the corresponding Fraunhofer diffraction image (left).

The changes in the contrast and shape of the fringes in Fig. 4 can be examined more quantitatively by taking line scans across the central maximum of the diffraction envelope, as shown in Fig. 5. The decreasing contrast and intensity of the curves corresponds to the decreasing width of the covered slit. The line scans show that the fringe contrast is approximately 0.5 when the slits are both open, presumably because the electron beam illumination was not perfectly coherent. The observed contrast reduction can be simulated by introducing incoherent plane wave illumination with a gaussian distribution over a semi-angle of 2.8 10−6 rad. Figure 6 shows the result of convoluting the intensities of perfectly coherent images for two one-dimensional slits (with widths of 36 nm and a separation of 496 nm) with this angular distribution for partial coverages of the right slit of 0, 0.5, 0.8 and 1. The agreement with the experimental results is satisfying. Further details are reported in the Supplementary Information.

Figure 5
figure5

Line scans measured across the central maxima in the experimental Fraunhofer patterns shown in Fig. 4.

Figure 6
figure6

Simulated line scans of the Fraunhofer patterns generated assuming incoherent plane wave illumination with a gaussian distribution over a semi-angle of 2.8 10−6 rad.

A Controlled Beam Interference Experiment in the Image Plane

In the previous section, the electron microscope was essentially used as an electron optical bench, in order to bring the mask (biprism) plane conjugate to the slit plane and to capture the Fraunhofer diffraction image of the slits on the detector. Another intriguing experiment can be realized by recording interference fringes in the plane of the slits (i.e., the object plane) instead of in the Fraunhofer plane, as shown in Fig. 7. As the microscope used in the present study is equipped with two electron biprisms28,29, the first of which serves as a mask, the second biprism can be used in the same way as in a standard off-axis electron holography setup11, in order to overlap wavefunctions passing on its left and right side in the image plane (conjugate to the object plane). We believe that the paradoxical question of which slit the electron is passing through is even more emphasized by this setup, where the two slits are imaged together.

Figure 7
figure7

Sketch of the experimental setup for the ideal controlled two beam interference experiment in the image plane. Just as in Fig. 3, an intermediate image of the two slits is formed by the objective lens in a plane in which a metallic wire (the unbiased first biprism wire, shown in blue), which is opaque to the electron beam, can be positioned with high accuracy and acts as a very sharp movable mask. In this case, it is possible to locally modify the electron transmittance through both slits. A biased biprism (shown in red), which is positioned in a plane above the second intermediate image plane and held at an applied voltage with respect to ground, acts as a wavefront division interferometric device. The resulting tilted wavefronts are overlapped in the observation plane, which is conjugate to the detector plane, by the remaining lenses of the microscope. Interference fringes are observed, except in the shadow of the mask, where electron path localization is achieved by absorption from the first wire.

We carried out experiments at 300 kV (corresponding to a de Broglie electron wavelength of 1.97 pm) using slits of the same width and separation as before, but with a length of 2 μm. The lower biprism was inserted between the slits, so that it was in the opaque region between them and could not be seen. Figure 8(a) shows the two edges of the lower biprism marked by dashed lines. As it is positioned above the slit image plane, when a bias is applied to it the two half-planes on its left and right sides shift in perpendicular directions, as shown by arrows. When a suitable potential is applied to the lower biprism, the two slits are brought to a partial (Fig. 8(b)) or nearly total (Fig. 8(c)) overlap. In the overlap region, interference fringes appear. Partial transparency of the upper biprism at 300 kV results in the presence of interference fringes in the regions that are shadowed by the upper biprism (where one beam is left).

Figure 8
figure8

(a) Controlled electron beam interference experiments in image space recorded using two electron biprisms. The lower biprism, which is located in the dark region between the slits and positioned some distance above the slit image plane, is marked by dashed lines that indicate its edges. The arrows show the displacement of the two halves of the image when a bias is applied to the lower biprism. The upper biprism crosses the slits at an angle and is in a conjugate image plane to them. Partial (b) and total (c) overlap of the two slits is achieved when the bias applied to the lower biprism is increased, resulting in the formation of two beam interference fringes.

Unfortunately, as the lower biprism is necessarily located in the Fresnel region below the two slits and the upper biprism, diffraction effects due to its sharp edges cannot be avoided. Moreover, selective filtering of the spatial frequencies by the lower biprism is responsible for the presence of ghost images of the edges of the upper biprism11,30, which can be seen more clearly in a dynamic way in the form of a movie in the Supplementary Information. Nevertheless, it is possible to identify single image areas where fringes from two slit interference are present and areas with no (or only faint) interference fringes where the slits are blocked by the upper biprism.

Conclusions

We have shown how the second part of the Young-Feynman experiment, which leads to the physical concept of the probability amplitude, can be realized by using a modern electron microscope as a versatile electron optical bench and nanotechnology preparation methods to fabricate slits at the submicron level. Two versions of the experiment have been presented, one of which corresponds closely to the original proposal and is free from artefacts that plagued previous experiments, while the other is realized by using two electron biprisms to overlap the slits in the image plane.

Methods

The experiments that are reported here were carried out in an FEI Titan 60–300 transmission electron microscope equipped with a high brightness electron gun, a Lorentz lens, a Gatan imaging filter (GIF), a 2048 × 2048 pixel charge-coupled device camera and two rotatable electron biprisms after the specimen plane. The microscope was operated primarily at an accelerating voltage of 60 kV (corresponding to a de Broglie electron wavelength of 4.87 pm) because the biprism wire was not completely opaque to 300 kV electrons. The lens excitations were chosen so that the upper biprism was in the first conjugate intermediate image plane. It could then be carefully aligned and displaced to obscure one of the slits either partially or totally, thanks to its very sharp edge when compared with the roughness of standard apertures.

The slits were designed so that they could be covered completely by the shadow of the upper electron biprism. They were fabricated using focused ion beam milling in a dual beam workstation (FEI Strata DB 235 M) on a commercial silicon nitride membrane window with a 200-μm-thick Si frame and a 100 μm × 100 μm square window that comprised a bilayer of 200 nm of silicon nitride and a further 100-nm-thick Au film. In order to open the slits, a 9 pA Ga ion beam with a nominal spot size of 10 nm was scanned over two 30 nm × 480 nm boxes that were spaced 500 nm apart for 4 s for each box. As a result of the dimensions of the slits and the angular deflections that are involved, the lenses can be considered to be ideal and their geometrical and chromatic aberrations can be considered to be negligible.

Note added during review

In the final stage of the review process, we became aware of a recently published paper by Harada et al.31 on interference experiments with asymmetric double slits, which were aimed at categorisation of the electrons. As their experiments were carried out using a 1.2 MV field emission electron microscope, the biprisms that were used as slits were not completely opaque to the electrons, as required in the experiments reported in the present work, in which the required opacity was achieved only at a very low accelerating potential of 60 kV.

References

  1. 1.

    Feynman, R. P., Leighton, R. B. & Sands, M. L. The Feynman lectures on physics, vol. 3 (Addison-Wesley Pub. Co, Reading, Mass., 1963).

    Google Scholar 

  2. 2.

    Crease, R. P. The prism and the pendulum: the ten most beautiful experiments in science. (Random House, New York, 2003).

    Google Scholar 

  3. 3.

    Jönsson, C. Elektroneninterferenzen an mehreren künstlich hergestellten Feinspalten. Zeitschrift für Physik 161, 454–474 (1961).

    ADS  Article  Google Scholar 

  4. 4.

    Jönsson, C. Electron diffraction at multiple slits. Am. J. Phys. 42, 4–11 (1974).

    ADS  Article  Google Scholar 

  5. 5.

    Frabboni, S., Gazzadi, G. C. & Pozzi, G. Young’s double-slit interference experiment with electrons. Am. J. Phys. 75, 1053–1055 (2007).

    ADS  Article  Google Scholar 

  6. 6.

    Frabboni, S., Frigeri, C., Gazzadi, G. C. & Pozzi, G. Two and three slit electron interference and diffraction experiments. Am. J. Phys. 79, 615–618 (2011).

    ADS  Article  Google Scholar 

  7. 7.

    Frabboni, S. et al. The Young-Feynman two-slits experiment with single electrons: Build-up of the interference pattern and arrival-time distribution using a fast-readout pixel detector. Ultramicroscopy 116, 73–76 (2012).

    CAS  Article  Google Scholar 

  8. 8.

    Bach, R., Pope, D., Liou, S.-H. & Batelaan, H. Controlled double-slit electron diffraction. New J. Phys. 15, 033018 (2013).

    ADS  Article  Google Scholar 

  9. 9.

    Möllenstedt, G., & H. Düker. Fresnelscher Interferenzversuch mit einem Biprisma für Elektronenwellen. Naturwissenschaften 42(2), 41–41(1955).

  10. 10.

    Möllenstedt, G. & Düker, H. Beobachtungen und Messungen an Biprisma-Interferenzen mit Elektronenwellen. Zeitschrift für Physik 145, 377–397 (1956).

    ADS  Article  Google Scholar 

  11. 11.

    Missiroli, G. F., Pozzi, G. & Valdrè, U. Electron interferometry and interference electron microscopy. J. Phys. E. 14, 649–671 (1981).

    ADS  CAS  Article  Google Scholar 

  12. 12.

    Hasselbach, F. Progress in electron- and ion-interferometry. Reports on Progress in Physics 73, 016101 (2010).

    ADS  Article  Google Scholar 

  13. 13.

    Pozzi, G., Beleggia, M., Kasama, T. & Dunin-Borkowski, R. E. Interferometric methods for mapping static electric and magnetic fields. Comptes Rendus Physique 15, 126–139 (2014).

    ADS  CAS  Article  Google Scholar 

  14. 14.

    Merli, P. G., Missiroli, G. F. & Pozzi, G. On the statistical aspect of electron interference phenomena. Am. J. Phys. 44, 306–307 (1976).

    ADS  Article  Google Scholar 

  15. 15.

    Tonomura, A., Endo, J., Matsuda, T., Kawasaki, T. & Ezawa, H. Demonstration of single-electron buildup of an interference pattern. Am. J. Phys. 57, 117–120 (1989).

    ADS  Article  Google Scholar 

  16. 16.

    Frabboni, S., Gazzadi, G. C. & Pozzi, G. Nanofabrication and the realization of Feynman’s two-slit experiment. Appl. Phys. Lett. 93, 073108–3 (2008).

    ADS  Article  Google Scholar 

  17. 17.

    Matteucci, G. & Pozzi, G. Two further experiments on electron interference. Am. J. Phys. 46, 619–623 (1978).

    ADS  Article  Google Scholar 

  18. 18.

    Frabboni, S., Gazzadi, G. C. & Pozzi, G. Ion and electron beam nanofabrication of the which-way double-slit experiment in a transmission electron microscope. Applied Physics Letters 97(26), 263101 (2010).

  19. 19.

    Frabboni, S., Gazzadi, G. C., Grillo, V. & Pozzi, G. Elastic and inelastic electrons in the double-slit experiment: A variant of Feynman’s which-way set-up. Ultramicroscopy 154, 49–56 (2015).

    CAS  Article  Google Scholar 

  20. 20.

    Egerton, R. F. Limits to the spatial, energy and momentum resolution of electron energy-loss spectroscopy. Ultramicroscopy 107, 575–586 (2007).

    CAS  Article  Google Scholar 

  21. 21.

    Egerton, R. F. Electron energy-loss spectroscopy in the TEM. Reports on Progress in Physics 72(1), 016502 (2008).

    ADS  Article  Google Scholar 

  22. 22.

    Born, M. & Wolf, E. Principles of optics: electromagnetic theory of propagation, interference and diffraction of light. 4th edn. (Pergamon Press, Oxford, 1969).

    Google Scholar 

  23. 23.

    Pozzi, G. Particles and waves in electron optics and microscopy. vol. 194 of Advances in imaging and electron physics. (Academic Press, New York, NY, 2016).

  24. 24.

    Ferrier, R. P. Small angle electron diffraction in the electron microscope. In Barer, R. & Cosslett, V. E. (eds) Advances in Optical and Electron Microscopy, vol. 3, 155–217 (Academic Press, New York, 1969).

  25. 25.

    Goodman, J. W. Introduction to Fourier optics. 2nd edn. (McGraw-Hill, New York, 1996).

    Google Scholar 

  26. 26.

    Glaser, W. Grundlagen der Elektronenoptik. (Springer, Wien, 1952).

    Google Scholar 

  27. 27.

    Wolfram, S. The Mathematica book. 4th edn. (Wolfram Media, Champaign, IL, 1999).

    Google Scholar 

  28. 28.

    Harada, K., Tonomura, A., Togawa, Y., Akashi, T. & Matsuda, T. Double-biprism electron interferometry. Appl. Phys. Lett. 84, 3229–3231 (2004).

    ADS  CAS  Article  Google Scholar 

  29. 29.

    Harada, K., Akashi, T., Togawa, Y., Matsuda, T. & Tonomura, A. Variable interference azimuth angle in double-biprism electron interferometry. Jpn. J. Appl. Phys. 44, L636 (2005).

    ADS  CAS  Article  Google Scholar 

  30. 30.

    Faget, J. Interférences des ondes électroniques: application à une méthode de microscopie électronique interférentielle. Revue d’Optique 40, 347–381 (1961).

    CAS  Google Scholar 

  31. 31.

    Harada, K. et al. Interference experiment with asymmetric double slit by using 1.2-MV field emission transmission electron microscope. Sci. Rep. 8, 1008 (2018).

    ADS  Article  Google Scholar 

Download references

Acknowledgements

This project has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement No. 823717-ESTEEM3.

Author information

Affiliations

Authors

Contributions

G.P. and S.F. conceived the idea; G.C.G. fabricated the double slit specimens; A.H.T., C.B.B., E.Y. and R.E.D.-B. discussed and performed the experiments; all of the authors discussed the results and contributed to the text of the manuscript.

Corresponding author

Correspondence to Amir H. Tavabi.

Ethics declarations

Competing Interests

The authors declare no competing interests.

Additional information

Publisher’s note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Supplementary information

Rights and permissions

Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.

Reprints and Permissions

About this article

Verify currency and authenticity via CrossMark

Cite this article

Tavabi, A.H., Boothroyd, C.B., Yücelen, E. et al. The Young-Feynman controlled double-slit electron interference experiment. Sci Rep 9, 10458 (2019). https://doi.org/10.1038/s41598-019-43323-2

Download citation

Further reading

Comments

By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.

Search

Quick links

Nature Briefing

Sign up for the Nature Briefing newsletter — what matters in science, free to your inbox daily.

Get the most important science stories of the day, free in your inbox. Sign up for Nature Briefing