Abstract
We look beyond the standard time-average approach and investigate optical forces in the time domain. The formalism is developed for both the Abraham and Minkowski momenta, which appear to converge in the time domain. We unveil an extremely rich – and by far unexplored – physics associated with the dynamics of the optical forces, which can even attain negative values over short time intervals or produce low frequency dynamics that can excite mechanical oscillations in macroscopic objects under polychromatic illumination. The magnitude of this beating force is tightly linked to the average one. Implications of this work for transient optomechanics are discussed.
© 2022 Optica Publishing Group under the terms of the Optica Open Access Publishing Agreement
1. Introduction
Electromagnetic forces produced by light acting on physical objects have received significant research attention ever since the observation of comet tail bending by Kepler in the 17th century [1]. The resulting effect stems from momentum exchange between photons and physical objects. The human eye perceives this force as being static and is described as optical "pressure" [2,3], "pulling" [4–8] or "trapping" [9–23], all terms associated with a static behavior. This perception is illustrated in Fig. 1(a) where a rectangular rod attached to the wall is illuminated at frequency $\omega _0$ and consequently experiences constant optical pressure.
However, the electromagnetic wave theory predicts that the momentum carried by an electromagnetic wave includes not only a static momentum but also a part that oscillates in time. This has been discussed in classical works [24–29].
The presence of the oscillating component of the optical force can be easily understood by analyzing the instantaneous value of the Poynting vector for a monochromatic plane wave at the frequency $\omega _0$ [30]:
At first sight, such oscillations are not easy to observe. Indeed, if the excitation frequency is high (GHz and higher), those oscillations are too far from the mechanical resonance of the oscillator (typically in the kHz-MHz range) and their amplitude becomes negligible. To overcome this issue, we will show that two waves with slightly different frequencies $\omega _0$ and $\omega _1=\omega _0+\Omega$ can be used ($\Omega <<\omega _0$). Together, they produce a beating effect that induces mechanical oscillations at the beating frequency $\Omega$. Such an idea was experimentally realized in a cavity via the dynamical backaction effect [31,32], which essentially appears through the beating of the pump wave with the Stokes or anti-Stokes components induced by the mechanical mode of the cavity. This can lead to either enhancement of the mechanical oscillations [33–36] or rather efficient oscillation quenching [37].
Alternatively, an optical wave can be modulated with the mechanical frequency $\Omega$, such that a signal of the form $A\cos (\Omega t)\cos (\omega _0 t)$ can effectively drive the mechanical oscillator, leading to the experimental observation of mechanical oscillations even at the macroscopic scale [38–40].
Optical forces in the time domain are also very important for trapping experiments where optical pulses are used as incident illumination [24,41–53]. Besides, some very challenging ideas of using complex-valued frequency excitation have emerged recently to control the optical force in the time-domain [54,55].
The optical forces were studied in great details in experiments on radiation pressure exerted on muons, protons, atoms, molecules and larger particles with single frequency light [56] and multi-frequency illuminations [57]. The two-[38,58–62] and four-wave [63] illuminations showed that an increased optical force can be achieved, thus overcoming the limit on the optical force imposed by the spontaneous emission rate factor [57]. It is interesting to note that concepts related to complex-frequency illumination or forces appearing under transient illumination discussed above are of multi-scale nature and can be realized in a very broad range of frequencies, including acoustics [64–66].
On looking through the literature, we notice that several previous studies undertook the analysis of the optical force in the time domain, but at a certain point always shifted their focus to the time average force [67–69] or, alternatively, use numerical approaches to find the force in the time domain [44,70–75]. To the best of our knowledge, only a few publications conducted analytical studies of the optical force evolution. Very recent paper employs the signal theory to derive the imaginary part of the Maxwell stress tensor, which is responsible for the oscillating optical force and torque [76]. The optical force is studied under two-wave excitation acting on a half-space [40] and on cylinders [77], and a systematic analytical study of the time evolution of the optical force has not yet been reported.
In this paper, we address this shortcoming and provide a comprehensive theoretical study that establishes the foundations for the dynamics of the optical forces in the time domain. We discuss first in Sec. 2. the general formalism that can be used to find the optical forces in the time domain. Next, in Sec. 3. we apply this approach and describe how the simplest possible form of excitation – a plane wave – triggers the optical force in the time domain. To make the analysis as clear as possible and as illustrative as we can, we start by examining the dynamics of the optical force acting on a thin film under normal incidence. Next, in Sec. 4, we study the dynamics of the beating force and derive a simple formula for arbitrary objects. Finally, we analyze the derived formula and discuss possible applications of that beating effect.
2. Optical force in the time domain: general theory
The momentum conservation law is one of the fundamental laws that govern the mechanical motion of physical objects. Newton’s second law states that the first time-derivative of the mechanical momentum $\mathbf {G}_\textrm {mech}(t)$ carried by the system is equal to the mechanical force $\mathbf {F}_\textrm {mech}(t)$ acting on it [78],
The mechanical momentum of an object that is subjected to electromagnetic fields can be calculated by evaluating the total momentum $\mathbf {G}_\mathrm {tot}(t)$ stored within the object minus the momentum stored in the electromagnetic waves $\mathbf {G}_\mathrm {e.m.}(t)$ travelling inside the object [27]: The time derivative of the mechanical momentum can thus be written as Maxwell’s equations provide explicit relations for the time derivatives of the total and electromagnetic momenta in Eq. (4) based on the electric and magnetic fields $\mathbf {E}(\mathbf {r},t)$ and $\mathbf {H}(\mathbf {r},t)$. Let us assume that the object under study is nonmagnetic, has a homogeneous dielectric permittivity $\varepsilon$ and is placed in vacuum. We further assume that $\varepsilon$ has negligible dispersion over the frequency range considered. In this case, the time derivative of the total momentum can be rewritten in terms of the surface integral as [27,79,80],3. Optical force in the time domain under monochromatic illumination
3.1 Average and oscillating components
Let us consider harmonic electromagnetic fields with a frequency ${{\omega }_{0}}$. In this case, one can find the average mechanical force ${{\left \langle {{\mathbf {F}}_\mathrm {mech}}(t) \right \rangle }_{T}}$ (averaging is performed over a period $T=2\pi /{{\omega }_{0}}$ of the wave ) that can be calculated by evaluating the Maxwell stress tensor,
3.2 Optical force acting on a film under normal incidence
In this section, we analyze the average and oscillating components of the mechanical optical force for a plane wave impinging at normal incidence on a film of thickness $d$, as illustrated in Fig. 2. The frequency of the wave is ${{\omega }_{0}}$, which corresponds to the wavelength $\lambda _0 =2\pi c/{{\omega }_{0}}$.
Finding the evolution of the optical force using Eqs. (13)–(14) requires the knowledge of the electric and magnetic fields at every point inside and on the surface of the volume of the film. To find the force, we seek for the electric and magnetic fields in the bulk as well as on the boundaries of the film analytically by matching the boundary conditions at the interfaces of the film, which is assumed to be infinite in the $xy$-plane, see Fig. 2. We present here the reflection ($r_f$) and transmission ($t_f$) coefficients.
It follows that the total oscillating mechanical force can be written as
3.3 Model validation
To validate this model, we first consider the rather trivial case of a film with refractive index ${{n}_\mathrm {film}}=1$ (vacuum), Fig. 3(a). In this case, the reflection and transmission coefficients are $\left | {{r}_{f}} \right |=0$ and $\left | {{t}_{f}} \right |=1$. Consequently, we expect a vanishing mechanical force (${\mathbf {F}}_\mathrm {mech}(t)={{\mathbf {F}}_\mathrm {mech}^\mathrm {M}}(t)={{\mathbf {F}}_\mathrm {mech}^\mathrm {A}}(t)=0$ in Eqs. (23)–(24)). Hence, no momentum is transferred to the mechanical force, and the total momentum of the system is stored in the propagating electromagnetic wave ($d{\mathbf {G}}_\mathrm {tot.osc.}(t)/dt=d{{\mathbf {G}}_\mathrm {e.m.}}(t)/dt$), as can be seen from the dynamics of the force components presented in Fig. 3(b).
The oscillations amplitude of the electromagnetic momentum part can be found from Eqs. (19)–(20) as $2{{\Sigma }_{0}}\left | \sin (\delta ) \right |/c$ since ${{n}_\mathrm {film}}=1$. Note that this amplitude vanishes for $\delta =q\pi,\text { }q\in \mathbb {N}$, corresponding to ($d=q\lambda _0 /2$). This is related to the fact that the Poynting vector in the film, Eq. (1), is a periodic function with a period equal to $\lambda _0 /2$ when ${{n}_\mathrm {film}}=1$. Consequently, the integration in Eqs. (10)–(11) over a volume with thickness $d=q\lambda _0 /2$ vanishes. In summary, this trivial situation emphasizes the importance of the electromagnetic momentum part, Eqs. (19)–(20), in the calculations of the mechanical force. Indeed, taking into account only the total oscillating component, Eq. (18), we would get a nonzero mechanical force in the considered case, which is unphysical.
3.4 Force acting on a lossless film in air
Let us now consider a 100 nm thick fused silica film, with a refractive index ${{n}_\mathrm {film}}\approx 1.5$ without dispersion or losses (the refractive index data are taken from Ref. [92]). As a matter of fact, dispersive materials bring about additional complications for the definition of the electromagnetic momentum [90]. The reflection coefficient as a function of wavelength for such a film is calculated by enforcing the boundary conditions, see Sec. A of the Supplement 1.
At $\lambda _0 =300$ nm we observe a dip in the reflection, which is associated with the Fabry-Perot destructive interference condition for reflection ($\lambda _0 =2d{{n}_\mathrm {film}}$). For wavelengths above 600 nm the reflection coefficient is close to $\left | {{r}_{f}} \right |\approx 0.3$. For non-vanishing reflection, the electromagnetic momentum can now couple into the mechanical force. The dynamics of the total oscillating, as well as Minkowski and Abraham electromagnetic momenta for $\lambda _0$=800 nm are presented in Fig. 4(b). The total oscillating momentum is clearly not equal to either the Minkowski or the Abraham forms of the electromagnetic momentum. Hence, the mechanical force calculated for both formalisms is nonzero and oscillates in time around the average, Fig. 4(c). From Eqs. (23)–(24) it follows that for a lossless film, the minimum of the mechanical force can be found as $2\frac {{{\Sigma }_{0}}}{c}|{r}_{f}|( |{{r}_{f}}| -1)\mathbf {z}$. From the that it directly follows that the minimum of the optical force is always less than zero since $|{{r}_{f}}|\leq 1$. This result is actually not surprising. One can derive even from the simple consideration of Eq. (1) using the explicit expression of the electric field, Eq. (S.1), that the Poynting vector of the incident field interfering with the reflected field reaches negative values, which can be the origin of the appearance of a negative force. In Ref. [54] a negative optical force acting on a thin film was observed for illumination with a decaying monochromatic wave with complex frequency. It was shown that for short periods of time the instantaneous optical force can attain negative values. In our case we show that the instantaneous optical force can attain negative values even for simple harmonic illumination.
4. Optical force acting on an object under two-wave illumination
In the previous sections we developed the fundamental analysis of the optical force in the time domain under monochromatic illumination. We observed that the optical force was oscillating at $2{{\omega }_{0}}$ - a frequency that is too high for the mechanical oscillator to develop a response. In this section, we aim at decreasing this frequency down to the one accessible for mechanical oscillators. To this end, let us consider an object illuminated by two monochromatic plane waves with frequencies ${{\omega }_{0}}$ and ${{\omega }_{0}}+\Omega$, see the sketch in Fig. 5(a). Here ${{\omega }_{0}}$ is an optical frequency and $\Omega \ll {{\omega }_{0}}$. In the sketch, we also introduce an angle $\theta$ between the two beams for visualization purposes. Hereafter, we consider the case $\theta =0$, for which the analytical expression becomes very simple.
Let us assume that the illumination conditions (fields amplitude, direction of propagation) are equal for both waves. Let us further assume that the wave ${{\omega }_{0}}+\Omega$ has a phase shift $\varphi$ with respect to the wave ${{\omega }_{0}}$. In the Supplement 1 we carefully analyse the Abraham and Minkowski forms of the force, Eqs. (13)–(14), in the considered case. Our developments show that the total oscillating component $d{{\mathbf {G}}_\mathrm {tot.osc.}}(t)/dt$ is proportional to twice the average force ${{\left \langle {{\mathbf {F}}_\mathrm {mech}}(t) \right \rangle }_{T}}$ created by each of the waves. It is also shown that the electromagnetic momentum of both forms $d{\mathbf {G}}_\mathrm {e.m.}^\mathrm {M}(t)/dt$ and $d{\mathbf {G}}_\mathrm {e.m.}^\mathrm {A}(t)/dt$ are by factor of $\Omega /{{\omega }_{0}}<<1$ smaller than the same for a single-frequency illumination. The latter is not surprising given that the calculation of the electromagnetic momentum requires the calculation of the time derivative of $\textrm {Re}\left ( \mathbf {E}(\mathbf {r},t) \right )\times \textrm {Re}\left ( \mathbf {H}(\mathbf {r},t) \right )$ in Eqs. (7)–(8). For a monochromatic wave, ${{\omega }_{0}}$ appears as a prefactor after differentiation, Eqs. (10)–(11). For two waves, the beating frequency $\Omega$ appears instead of ${{\omega }_{0}}$. Consequently, the electromagnetic momentum contribution can be neglected and the Minkowski and Abraham force are equal to each other ${{\mathbf {F}}_\mathrm {mech}^\mathrm {M}}(t)={{\mathbf {F}}_\mathrm {mech}^\mathrm {A}}(t)={{\mathbf {F}}_\mathrm {mech}}(t)$. Hence, the analytical form of the force takes the form
Let us analyze the implications of Eq. (25). It predicts that for a quarter of the period of the beating frequency $2\pi /(4\Omega )$, the instantaneous mechanical force overcomes the average force and can reach the maximum value of $4{{\left \langle {{\mathbf {F}}_\mathrm {mech}}(t) \right \rangle }_{T=2\pi /{{\omega }_{0}}}}$. In Fig. 5(b) the dynamics of the mechanical force in the time domain is presented for the beating frequency ${\Omega }/{2\pi }=200\text { kHz}$. This frequency corresponds to the typical resonance frequency of an AFM cantilever that is sometimes used in cavity cooling experiments [108]. From this figure and from Eq. (25) we note that the optical force cannot attain negative values in case of two frequency illuminations. Also, the optical force can now overcome the average force by a factor of two for durations in the order of microseconds. This time is sufficient to displace the nanorod from its equilibrium position and possibly even break it. Note that a similar idea of increasing the peak force acting on nanoparticles has been proposed for pulsed illumination, since in that case the different frequency components of the pulse are closely packed, thus increasing the peak optical force [52]. Pulsed illumination was used in the past to rapture the adhesion forces that hold a particle on a surface [42,44].
5. Conclusion
The analytical formalism presented in this work revealed the evolution of the optical force in the time-domain under monochromatic and two-wave illuminations. For the monochromatic case, we highlighted the different elements required to calculate the optical force in the time domain with both the Abraham and Minkowski approaches. Quite interestingly, the two approaches give optical forces with the same magnitude that only differ by a phase shift of $\pi$. The possibility of an instantaneous negative optical force acting on a thin film was also discovered. When a physical system is illuminated with two waves of slightly different frequencies, a relation between the magnitude of the amplitude of the beating force and the magnitude of the average force was established.
Funding
Schweizerischer Nationalfonds zur Förderung der Wissenschaftlichen Forschung (project PZ00P2_193221); European Research Council (ERC-2015-AdG-695206 Nanofactory).
Acknowledgments
We gratefully acknowledge funding from the European Research Council and from the Swiss National Science Foundation.
Disclosures
The authors declare no conflicts of interest.
Data availability
No data were generated or analyzed in the presented research.
Supplemental document
See Supplement 1 for supporting content.
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