Theoretical formulation

The conceptual formulation of ST-SPPs is best understood by visualizing their spectral representation on the surface of the light-cone. For (2 + 1)D pulsed optical fields restricted to one transverse dimension x in addition to the axial dimension z, the light-cone is the geometric representation of the dispersion relationship involving the transverse wave number k_x (or spatial frequency), the longitudinal wave number k_z, and the temporal frequency ω. In free space, the light-cone is $k_x^2+k_z^2={\left(\frac{\omega }{c}\right)}^2$ , and that for an SPP at a metal-dielectric interface is $k_x^2+k_z^2=k_{\mathrm{SPP}}^2\left(\omega \right)$ ; where c is the speed of light in vacuum, $k_{\mathrm{SPP}}=\frac{\omega }{c}\sqrt{\frac{{ϵ}_{\mathrm{m}}{ϵ}_{\mathrm{d}}}{{ϵ}_{\mathrm{m}}+{ϵ}_{\mathrm{d}}}}$ , and ϵ_m and ϵ_d are the relative permittivities of the metal and dielectric, respectively (Fig. 1a). In free space, where a (2 + 1)D pulsed beam (or wave packet) takes the form of a light-sheet that is uniform along y and localized along x, its spectral support is a two-dimensional (2D) region on the surface of the free-space light-cone (Fig. 1a). Such a light-sheet undergoes diffractive spreading with free propagation. A conventional SPP wave packet is a (2 + 1)D surface wave with finite transverse-spatial extent along x in addition to surface localization along y, whose spectral support in turn corresponds to a 2D region on the surface of the SPP light-cone (Fig. 1a)^35,48. This conventional SPP wave packet undergoes both diffractive spreading in space and dispersive spreading in time.

Ideal STWPs are pulsed beams that propagate rigidly in linear media without diffraction or dispersion, and whose propagation characteristics can be tuned largely independently of the material parameters^23,28. Rather than the 2D spectral support on the free-space light-cone associated with conventional pulsed light sheets, the spatiotemporal spectrum of an STWP is restricted to a 1D curve (a conic section) at the intersection of the light-cone with a plane that is parallel to the k_x-axis and makes an angle θ with the k_z-axis (Fig. 1b)²⁸. This plane, $\omega -{\omega }_{\mathrm{o}}=\left(k_z-k_{\mathrm{o}}\right)c\tan \theta$ , results in a straight-line spectral projection onto the $\left(k_z,\frac{\omega }{c}\right)$ -plane, which indicates a fixed group velocity $\tilde{v}=c\tan \theta$ and the absence of dispersion to all orders⁴⁹; here ω_o is a fixed carrier frequency, and $k_{\mathrm{o}}=\frac{{\omega }_{\mathrm{o}}}{c}$ is its associated wave number. Moreover, the one-to-one association between ω and ∣k_x∣ guarantees diffraction-free propagation of the time-averaged intensity²³. Similarly for ST-SPPs, their spectral support as shown in Fig. 1b is also a 1D curve at the intersection of the SPP light-cone with the plane $\omega -{\omega }_{\mathrm{o}}=\left(k_z-k_{\mathrm{o}}^{\prime }\right){\tilde{v}}_{\mathrm{SPP}}\tan \theta$ , where ${\tilde{v}}_{\mathrm{SPP}}$ is the group velocity of a plane-wave pulsed SPP at ω = ω_o, and $k_{\mathrm{o}}^{\prime }$ is the SPP wave number at ω_o³⁵. The spectral projection onto the ( $k_z,\frac{\omega }{c}$ )-plane for the ST-SPP is also a straight line, indicating that – in addition to being diffraction-free – ST-SPPs propagate dispersion-free at a group velocity $\tilde{v}={\tilde{v}}_{\mathrm{SPP}}\tan \theta$ despite the intrinsic GVD associated with freely propagating SPPs (Fig. 1b)³⁵.

We show in Fig. 2 (first row) the spectral support for a conventional SPP wave packet on the SPP light-cone (Fig. 2a), its spectral projections onto the $\left(k_x,\frac{\omega }{c}\right)$ and $\left(k_z,\frac{\omega }{c}\right)$ planes (Fig. 2b, c), along with the out-of-plane field profile (Fig. 2d). We assume a separable Gaussian spectrum in space and time, and take into account the temporal bandwidth Δ λ ≈ 110 nm (FWHM) utilized in our experiments (Methods). Crucially, the phase front for this conventional SPP wave packet is orthogonal to the propagation axis z (Fig. 2d).

Fig. 2 Spectral representation of SPPs and ST-SPPs. [Images not available. See PDF.]

The first row corresponds to a conventional SPP wave packet with Δx = 9 μm; the second to a striped ST-SPP with λ_x = 10 μm; the third to a subluminal ST-SPP with Δx = 5 μm; and the fourth to a superluminal ST-SPP with Δx = 5 μm. (a) The spectral support on the surface of the SPP light-cone $k_x^2+k_z^2=k_{\mathrm{SPP}}^2$ in $\left(k_x,k_z,\frac{\omega }{c}\right)$ -space (shown in red). b The projection of the spectral support in a onto the $\left(k_x,\frac{\omega }{c}\right)$ -plane. This spectral projection is invariant upon coupling the field from free space to the metal-dielectric interface (as a consequence of conservation of energy and transverse momentum). The gray band corresponds to the bandwidth Δω of the laser pulse used in our experiments, and the dashed horizontal line is at $\frac{{\omega }_{\mathrm{o}}}{2\pi }\approx 375$ THz (λ_o ≈ 800 nm in free space). c The spectral projection onto the $\left(k_z,\frac{\omega }{c}\right)$ -plane after implementing $k_z\to k_z-k_{\mathrm{o}}^{\prime }-\frac{\mathrm{\Omega }}{{\tilde{v}}_{\mathrm{SPP}}}$ for clarity, where Ω = ω−ω_o. The panel to the right shows the group velocity of the wave packet $\tilde{v}=\frac{d\omega }{d{k}_z}$ normalized to ${\tilde{v}}_{\mathrm{SPP}}$ . The spectral range on the vertical axis corresponds to the bandwidth of the laser pulse. d The calculated out-of-plane real part of the field distribution E_y(x, y, z; t) at y = 0 and t = 0 (Methods). The black curves on the left and bottom are cross-sections at z = 0 and x = 0, respectively. The right panels show magnified views of the dashed squares in the left panel, highlighting the structure of the phase fronts.

Producing an ideal ST-SPP with a bandwidth Δ λ = 110 nm is prohibitive, as can be understood by considering a so-called ‘striped ST-SPP’ whose spatial profile results simply from the interference of a pair of plane waves with fixed spatial frequencies  ± k_x (i.e., the field takes the transverse form $\cos k_{x}x$ )⁴². Consequently, a striped ST-SPP is separable with respect to space and time, and it thus does not offer the possibility of tuning the group velocity (indeed, its group velocity is $\tilde{v}\approx {\tilde{v}}_{\mathrm{SPP}}$ ; Methods). We plot in Fig. 2a–c (second row) the spectral support for a striped ST-SPP, which is the intersection of iso-∣k_x∣ planes with the SPP light-cone. The out-of-plane field is separable, extended and periodic along x (with period λ_x ≡ 2π/k_x = 10 μm), and its phase front is orthogonal to the z-axis, leading to a lattice-like spatial distribution at any instant t (Fig. 2d).

A broadband ST-SPP is composed of a multiplicity of cosine SPPs with different k_x, each of which is associated with a prescribed ω, such that k_z is maintained in a linear relationship with ω. However, maintaining this linear relationship between k_z and ω over a large temporal bandwidth Δ ω is prohibitive for SPPs because the curvature of the SPP light-line dictates a large accompanying spatial bandwidth Δ k_x. Indeed, even if $\tilde{v}$ it remains within 1% of ${\tilde{v}}_{\mathrm{SPP}}$ , we still need $\frac{\mathrm{\Delta }{k}_x}{k_{\mathrm{o}}}\approx 0.23$ (with the parameters used in our experiments below) to maintain the spatiotemporal spectrum of an ideal ST-SPP over the large bandwidth Δ λ ≈ 110 nm used here. Because our experimental scheme conserves the spatial bandwidth Δ k_x from free space to the surface-bound field, a large numerical aperture is required. We define $k_x\left(\lambda \right)=\frac{2\pi }{\lambda }\sin \left\{\phi \left(\lambda \right)\right\}=\frac{2\pi }{{\lambda }_x}$ in free space, where λ is the free-space wavelength, φ(λ) is the its propagation angle with the z-axis, and ${\lambda }_x=\lambda /\sin \phi \left(\lambda \right)$ is the transverse period of the field along x. Our system is limited to a maximum angular acceptance ${\phi }_{\max }\approx \pm 5^{\circ }$ , a numerical aperture (NA) of  ≈ 0.09, which restricts the minimum spatial feature size to  ≈ 9 μm which falls considerably short of the requirement for an ideal ST-SPP over Δ λ = 110 nm. To address this challenge, we have implemented a compromise regarding the structure of the realized ST-SPP with respect to an ideal ST-SPP: (1) we maintain the one-to-one correspondence between ∣k_x∣ and ω that is necessary for diffraction-free propagation; (2) we maintain control over the group velocity $\tilde{v}$ of the ST-SPP away from that for a conventional SPP ${\tilde{v}}_{\mathrm{SPP}}$ in both the subluminal ( $\tilde{v}<{\tilde{v}}_{\mathrm{SPP}}$ ) and superluminal ( $\tilde{v}>{\tilde{v}}_{\mathrm{SPP}}$ ) regimes; however (3) we allow the spectral projection onto the $\left(k_z,\frac{\omega }{c}\right)$ -plane to be curved such that it lies in the $\left(k_z,\frac{\omega }{c}\right)$ -plane between the SPP light-line and the linear spectral projection for an ideal ST-SPP (Fig. 2c). Consequently, we can operate with the available system NA, but at the cost of vouchsafing the complete elimination of GVD. This is a minimal disadvantage in light of the short SPP propagation distance limited by ohmic losses.

The spectral support of the realized ST-SPP is still a 1D curve on the surface of the SPP light-cone, but this curve results from the intersection of the SPP light-cone with a curved planar surface (rather than a plane) designed to yield a V-shaped spectral projection onto the $\left(k_x,\frac{\omega }{c}\right)$ -plane⁵⁰. For a subluminal ST-SPP ( $\tilde{v}<{\tilde{v}}_{\mathrm{SPP}}$ ), this projection takes the form $\omega -{\omega }_{\mathrm{U}}=c\mid k_x\mid \tan \alpha$ , where ${\omega }_{\mathrm{U}}={\omega }_{\mathrm{o}}+\frac{\mathrm{\Delta }\omega }{2}$ is the maximum frequency, ω < ω_U, α is the angle with the k_x-axis, and $\tan \alpha <0$ . For a superluminal ST-SPP ( $\tilde{v}>{\tilde{v}}_{\mathrm{SPP}}$ ), we have $\omega -{\omega }_{\mathrm{L}}=c\mid k_x\mid \tan \alpha$ , where ${\omega }_{\mathrm{L}}={\omega }_{\mathrm{o}}-\frac{\mathrm{\Delta }\omega }{2}$ is the minimum frequency, ω > ω_L, and $\tan \alpha >0$ . In both cases, ω_o is the central frequency, so that ${\omega }_{\mathrm{o}}-\frac{\mathrm{\Delta }\omega }{2}<\omega <{\omega }_{\mathrm{o}}+\frac{\mathrm{\Delta }\omega }{2}$ . This curved surface remains parallel to the k_x-axis, but its projection onto the $\left(k_z,\frac{\omega }{c}\right)$ -plane is no longer a straight line and is instead a curve that remains closer to the SPP light-line than in the case of the ideal ST-SPP (to remain within the system NA). The analytical relationship between ST-SPP group velocity $\tilde{v}$ and the angle α is derived in Methods. The GVD coefficient for a conventional SPP wave packet in this case is 2.5 × 10³ fs²/mm, and is 2.5 × 10³, 2.3 × 10², and 2.0 × 10² fs²/mm for a striped ST-SPP (with λ_x = 10 μm), a subluminal ST-SPP (with α = −64.5^∘), and a superluminal ST-SPP (with α = 64. 5°), respectively.

We plot in Fig. 2 the spectral representation for the subluminal ST-SPP (third row) and the superluminal ST-SPP (fourth row). Of particular interest is the spatial profile of the out-of-plane field for both ST-SPPs, which is no longer separable as a result of the non-separability of their spatiotemporal spectra. Instead, we observe an X-shaped profile reminiscent of free-space STWPs^49,51. Crucially, the direction of the phase fronts varies across the wave front. In the vicinity of the center x = 0, the phase front is orthogonal to the propagation axis. However, along the branches of the X-shaped profile, the phase fronts are tilted with respect to the z-axis. Crucially, the sign of this phase-front tilt switches between the subluminal and superluminal regimes, and the magnitude of the tilt angle increases with the deviation of $\tilde{v}$ from ${\tilde{v}}_{\mathrm{SPP}}$ ⁵².

Experimental arrangement

We sketch in Fig. 3a the optical arrangement for synthesizing free-space STWPs, launching them into ST-SPPs on a metal-dielectric interface via scattering from a nano-slit, and observing the propagation of surface-bound ST-SPPs via spatially and temporally resolved two-photon fluorescence produced from the interference of the ST-SPP with a free-space reference pulse. We start with pulses from a Ti:sapphire laser oscillator of bandwidth Δ λ ≈ 110 nm (FWHM), center wavelength λ_o ≈ 800 nm, and a 10-fs transform-limited pulse duration (FWHM). However, the measured pulse width at the sample surface is Δ T ≈ 16 fs (FWHM) because of residual chirp in the optical system.

Fig. 3 Experimental arrangement for synthesizing, launching, and observing ST-SPPs. [Images not available. See PDF.]

a Schematic of the setup for synthesizing free-space STWPs, launching them onto the sample, and imaging of the surface-bound field. b Schematic of the sample irradiation configuration. The STWP incidence angle is ψ_ex = −45^∘ to the surface normal, and the reference pulse incidence angle is ψ_ref = 45^∘. c SEM micrograph of the nano-slit milled into the Ag film. The inset shows a section of the nano-slit. d Two-photon fluorescence beat profile I(x, z; τ) at a fixed delay τ for a conventional SPP wave packet launched from the nano-slit. The yellow curve at the bottom is the axial profile I(z; τ) = ∫ dx I(x, z; τ) at a fixed τ. The red arrow at the top indicates the nano-slit location. Dashed orange lines enclose the irradiation area of the excitation, and the dashed green circle encloses that for the reference pulse. e SEM micrograph of the 5-μm-long nano-slit used to launch a conventional SPP wave packet of that width. f The two-photon fluorescence beat pattern (upper panel) after irradiating the nano-slit in (e), and the extracted field U(x, z; τ) (lower panel), both at fixed delay τ ≈ 80 fs (see Supplementary Movies 1 and 2). The dotted black curves correspond to the width of a Gaussian beam of width 5 μm (1/e² full width of the intensity), and serve as a guide for the eye.

Observation of SPPs and ST-SPPs

Calculating the SPP and ST-SPP electric-field distributions

The calculated profiles of the out-of-plane electric fields for the SPPs and ST-SPPs plotted in Fig. 2d assume a 100-nm-thick Ag film on a Si substrate, with a 30-nm-thick PMMA coating clad with free space. The SPP dispersion curve k_SPP(ω) was calculated using a model proposed by Pockrand⁶¹, and employed the dielectric function for Ag proposed by Rakic et al.⁶². The measured refractive index of PMMA is n ≈ 1.53 at the operating wavelength. We take the pulse spectrum to be $\tilde{E}\left(\omega \right)$ , which is the Fourier transform of the pulse profile $E\left(t\right)=\int d\omega \tilde{E}\left(\omega \right)e^{-i\omega t}$ . We assume a Gaussian profile in time:

1

In general, the out-of-plane field is given by:

2

The second row in Fig. 2 corresponds to a striped ST-SPP. The spatiotemporal spectrum is once again separable $\tilde{\psi }\left(k_x,\omega \right)=\left\{\delta \left(k_x-k_{x\mathrm{o}}\right)+\delta \left(k_x+k_{x\mathrm{o}}\right)\right\}\tilde{E}\left(\omega \right)$ . The electric-field distribution is thus given by:

3

The third and fourth rows in Fig. 2 correspond to subluminal and superluminal ST-SPPs, respectively. The spatiotemporal spectrum is no longer separable, in which ω and ∣k_x∣ are in one-to-one correspondence after selecting a value for the angle α. The field distribution for the ST-SPP is given by:

4

Relationship between the spectral tilt angle θ and the opening angle α

We define the axial group velocity $\tilde{v}$ of the ST-SPP in the usual way as $\tilde{v}={\left(\frac{d{k}_z}{d\omega }{\mid }_{{\omega }_{\mathrm{o}}}\right)}^{-1}$ . For the V-shaped spectra realized here (Fig. 2a, b, third and fourth rows), tuning the opening angle α varies θ, and thus in turn $\tilde{v}$ . For subluminal ST-SPPs we have $\omega -{\omega }_{\mathrm{U}}=c\mid k_x\mid \tan \alpha$ , where ${\omega }_{\mathrm{U}}={\omega }_{\mathrm{o}}+\frac{\mathrm{\Delta }\omega }{2}$ is the upper temporal frequency in the spectrum, ω < ω_U and $\tan \alpha <0$ (−90^∘ < α < 0). The axial wave number is $k_z\left(\omega \right)=\sqrt{k_{\mathrm{SPP}}^2\left(\omega \right)-k_x^2\left(\omega \right)}$ , and we make use of a Taylor expansion for k_SPP(ω): $k_{\mathrm{SPP}}\approx k_{\mathrm{o}}^{\prime }+\frac{\mathrm{\Omega }}{{\tilde{v}}_{\mathrm{SPP}}}+\frac{1}{2}{k}_2{\mathrm{\Omega }}^2$ , where ${\tilde{v}}_{\mathrm{SPP}}$ and k₂ are the group velocity and GVD coefficient for a plane-wave pulsed SPP, respectively, and $k_x^2\left(\omega \right)={\left(\frac{\mathrm{\Omega }-\mathrm{\Delta }\omega /2}{c\tan \alpha }\right)}^2$ . We can thus write $k_z=\sqrt{A+2B\mathrm{\Omega }+C{\mathrm{\Omega }}^2}$ , where: $A=k_{\mathrm{o}}^{\prime 2}-\frac{{\left(\mathrm{\Delta }k\right)}^2}{4{\tan }^2\alpha }$ , $B=\frac{k_{\mathrm{o}}^{\prime }}{{\tilde{v}}_{\mathrm{SPP}}}+\frac{\mathrm{\Delta }k}{2c{\tan }^2\alpha }$ , $C=k_{\mathrm{o}}^{\prime }{k}_2+\frac{1}{{\tilde{v}}_{\mathrm{SPP}}^2}-\frac{1}{c^2{\tan }^2\alpha }$ , and $\mathrm{\Delta }k=\frac{\mathrm{\Delta }\omega }{c}$ . We now have the following expression for the group velocity:

5

6

For the superluminal ST-SPP we have $\omega -{\omega }_{\mathrm{L}}=c\mid k_x\mid \tan \alpha$ , where ${\omega }_{\mathrm{L}}={\omega }_{\mathrm{o}}-\frac{\mathrm{\Delta }\omega }{2}$ is the lower temporal frequency in the spectrum, ω > ω_L and $\tan \alpha >0$ (0 < α < 90°). The coefficients A and C are identical to those for the subluminal ST-SPP, and $B=\frac{k_{\mathrm{o}}^{\prime }}{{\tilde{v}}_{\mathrm{SPP}}}-\frac{\mathrm{\Delta }k}{2c{\tan }^2\alpha }$ , so that the group index for the ST-SPP is:

7

Synthesizing free-space STWPs

The light source used in our experiments is a custom-built Ti:sapphire laser oscillator with a transform-limited pulse duration of 10 fs, center wavelength λ_o = 800 nm, FWHM-bandwidth Δ λ ≈ 110 nm, a repetition rate 90 MHz, and average power  ≈ 400 mW. The spectrum is measured via a spectrometer (Ocean Optics HR4000) after coupling to an optical fiber with diameter 200 μm. Because of residual chirp accumulated through various optical components such as lenses, gratings, and the SLM, the pulses are not transform-limited, and instead have a pulse duration of Δ T ≈ 16 fs at the sample surface. The pulse width is estimated by a home-built auto-corrrelator⁵⁵.

A portion of the laser power (20%) is reserved for subsequent use as a reference pulse. The remainder of the laser power (80%) is directed by a beam splitter to an optical system for synthesizing STWPs built along the lines described in ref. ²⁸. The spectrum of the femtosecond pulse is spatially resolved by a grating (300 lines/mm), collimated by a cylindrical lens L_c (focal length f = 250 mm), and directed to a 2D phase-only, reflective SLM (Hamamatsu X13138-07). Each wavelength λ occupies a column of the SLM, along which the SLM imparts a spatial phase distribution $\pm \frac{2\pi }{\lambda }\sin \left\{\phi \left(\lambda \right)\right\}x$ . The overall 2D phase distribution imparted to the wave front corresponds to each wavelength being deflected by a prescribed propagation angle  ± φ(λ) to yield the target relationship between k_x and λ. The reflected phase-modulated, spectrally resolved wavefront is directed to a second grating (identical to the first), whereupon the pulse is reconstituted to produce an STWP, which is then directed to the sample to excite an ST-SPP.

Sample fabrication

The sample was prepared by first depositing a 100-nm-thick Ag layer on a Si substrate via sputtering. The nanoslit structure was then milled into the Ag surface using a focused ion beam. The dimensions of the nanoslit are as follows: width w = 170 nm, depth h = 100 nm into the Ag layer, and extending across the sample by a length L = 200 μm (Fig. 3c). These were used to excite the ST-SPPs, including the striped ST-SPPs, and the subluminal and superluminal ST-SPPs (Figs. 4,  6, and 5). This nano-slit was also used to excite the conventional plane-wave SPP wave packet (Fig. 3d). A second set of nano-slits was prepared with the same dimensions w and h, but with length L = 5 μm (Fig. 1e). These nano-slits were used to excite conventional SPP wave packets with 5-μm-wide transverse profiles (Fig. 3f).

The full sample area was spin-coated with a 30-nm-thick poly(methyl methacrylate) (PMMA) layer doped with a laser dye (coumarin 343). The thickness of the coating was measured by spectral ellipsometry (Uvisel plus), from which we estimated an uncertainty in the coating thickness of  ~ 5 nm. This in turn results in an uncertainty in estimating the SPP group velocity of  ~ 0.1 × 10⁸ m/s.

SPP detection

Two wave packets overlap and interfere in the fluorescent polymer layer: the free-space incident reference pulse and the surface-bound SPP. The interference of these two wave packets produces a beat profile that excites two-photon fluorescence. The two-photon-fluorescence emission from the sample surface is collected with an objective lens (M Plan Apo SL20X, Mitutoyo) equipped with a band-pass filter transmitting light in the range 475−495 nm (Semrock, FT-02-485/20-25), followed by a CCD camera (Rolera EM-C2, QImaging). The two-photon fluorescence signal is expected at a wavelength  ≈ 490 nm from the dye used.

In this study, we chose a field of view of approximately 150 × 150 μm, which allowed simultaneous imaging of both the light-SPP coupler and the full extent of the ST-SPP wave packet, while maintaining the spatial resolution required for accurate phase retrieval. As a result, the observation range was primarily limited to approximately 100 μm from the slit, despite the ST-SPPs propagating beyond this distance.

Calculating the SPP intensity profile

The intensity distribution I(x, z; τ) on the sample surface detected by the CCD camera is the time-average of the fourth power of the total electric field⁵⁵:

8

9

Intensity profiles in Fig. 4 were calculated from the two-photon fluorescence signal resulting from the interference of the ST-SPP and the incident free-space conventional reference pulse. The intensity profile was calculated using Eq. (8) and assuming that both the ST-SPP and reference pulses are of width  ≈ 16 fs as determined experimentally.

Removing the background

To extract the field distribution U(x, z; τ) from the measured two-photon fluorescence, we need to experimentally estimate the background constants. This is achieved by changing the delay τ in the path of the reference pulse by 2.7 fs, which corresponds to moving the excitation-reference interference beat profile by the laser carrier wavelength laser λ_o (a phase shift of 2π rad), and carrying out the time-resolved measurements. To obtain the background intensity, we first obtain the time-resolved field U(x, z; τ) from the interference beat profiles, and then obtain their average $Ū\left(x,z;\tau \right)$ evaluated over an optical cycle:

10

Rayleigh range

The intensity distribution of the microscopic fluorescence beat images obtained via two-photon fluorescence are not proportional to the electric field intensity. We estimate the beam waist of the striped ST-SPP by obtaining λ_x by fitting the striped ST-SPP to a sinusoidal distribution along x. For a striped ST-SPP with λ_x ≈ 9.4 μm, the beam waist is 2.15 μm, corresponding to a Rayleigh range z_R ≈ 18.2 μm at a wavelength of 800 nm.

Group-velocity calculation

The two-photon fluorescence beat pattern is formed by the spatial overlap of the SPP propagating at a group velocity $\tilde{v}$ and the reference pulse traveling along the sample surface at a group velocity $\tilde{v}=c/\sin {\psi }_{\mathrm{ref}}$ , where ψ_ref is the reference-pulse incident angle. We need to convert the external relative delay τ between the excitation and reference pulses to the propagation time t of the surface-bound SPP. As the SPP travels after a time t a distance $z_1=\tilde{v}t$ , whereas the delayed reference pulse travels a distance $z_2=\frac{c}{\sin {\psi }_{\mathrm{ref}}}\left(t-\tau \right)$ . For the two wave packets to meet at z₁ = z₂ = z_o, and thus a two-photon fluorescence beat profile to be observed in the vicinity of z_o, we have $\tau =z_{\mathrm{o}}\left(\frac{1}{\tilde{v}}-\frac{\sin {\psi }_{\mathrm{ref}}}{c}\right)$ . This leads to the sought-after conversion $t=\tau {\left(1-\frac{\tilde{v}}{c}\sin {\psi }_{\mathrm{ref}}\right)}^{-1}$ . This conversion between t and τ was used in plotting Fig. 4 and 6b.

Peer review information

: Nature Communications thanks the anonymous reviewers for their contribution to the peer review of this work. A peer review file is available.

Competing interests

The authors declare no competing interests.