2.1.

Evanescent Waves

In the work of Bethe,¹¹ it was demonstrated that when a plane wave impinges on a flat surface with a round aperture of dimension significantly smaller than the wavelength, $\lambda$, the transmitted radiation field has the same form as if the aperture itself were a radiating dipole. In particular, for large distances from the aperture, the intensity falls off with inverse square of the distance to the center

Although Bethe’s solution addressed the inconsistencies of the scalar field diffraction by solving the full vector formalism of Maxwell’s equations, we will use the angular spectrum of the scalar theory.¹² One assumes a propagating wave function $\psi$ of wavelength $\lambda$ satisfying Helmholtz’s (stationary) equation

Time-independent plane wave solutions have the form

A general solution is a superposition of plane wave solutions

The constraint on ${\overrightarrow{k}}^2=k^2$ allows us to solve one component of the wave number in terms of the other two, and write the whole expression as an integral over the remaining two components

In light of the comments above, we arrive at the following connection between superresolution and evanescent waves: spatial frequencies greater than the wave number describe fine details with characteristic size smaller than the wavelength. These high-frequency elements of the spectrum will not excite propagating modes but rather will lead to evanescent, decaying modes. Subwavelength apertures, protrusions, etc. belong to the category of fine detail, which have high-frequency content. To see this explicitly, consider the canonical example of a circular aperture of radius $a$. For an incoming plane wave at normal incidence, the value of the field at $z=0$—just beyond the screen—is taken to be a constant value within the aperture, and zero outside

In each case the spatial frequency distribution is given by the Fourier transform, in accordance with Eq. (9). For the circular aperture, the Fourier transform of the circ-function is the well-known Airy function

These profiles are shown in Fig. 2 for two radius values: 0.6 and $0.2\mu \mathrm{m}$.

Fig. 2

Spatial frequency profiles for circular aperture wave functions. Apertures radius: $a_1=0.6\mu \mathrm{m}$, $a_2=0.2\mu \mathrm{m}$. The corresponding first minima of the profiles are located at $k_{\perp 1}=z_1/a_1=6.4{\mu \mathrm{m}}^{-1}$ and $k_{\perp 2}=z_1/a_1=19{\mu \mathrm{m}}^{-1}$. Illumination wavelength is $\lambda =0.5\mu \mathrm{m}$ ($k=2\pi /\lambda =12{\mu \mathrm{m}}^{-1}$). $z_1=1.22\pi$ is the first zero of the first Bessel function.

Both profiles are characterized by a central lobe or disc bounded by the first zero, and smaller side lobes of decaying amplitude. The location of the lobes is determined by the zeros of $\hat{\psi }$ function, i.e., for $k_{\perp 1}=z_1/a_1=6.4{\mu \mathrm{m}}^{-1}$ and $k_{\perp 2}=z_1/a_2=19{\mu \mathrm{m}}^{-1}$, where $z_1=1.22\pi$ is the first zero of the first Bessel function $J_1(z)$.

Considering now an incident wavelength $\lambda =0.5\mu \mathrm{m}$ ($k=2\pi /\lambda =12{\mu \mathrm{m}}^{-1}$) such $k_{\perp 1}<k<k_{\perp 2}$. According to Fig. 2, the incident wave will pass through the $0.6\text{-}\mu \mathrm{m}$ radius aperture as a propagating wave while it will pass through the $0.2\text{-}\mu \mathrm{m}$ radius aperture as a decaying wave. Conversely, apertures of radius below $z_1/k=0.32\mu \mathrm{m}$ will lead to a spatial decay of the incident wave.

The intensity is proportional to the square of the field in Eq. (8); the total intensity is obtained by integrating over the plane $z=0$. By Parseval’s theorem, this is equal to the square of the integral of the Fourier transform distribution Eq. (11) over all spatial frequencies. For the circular aperture, the central peak contains $\sim 84\%$ of the total intensity. In both cases, the overwhelming majority of spatial frequencies are concentrated within the central peak, and thus it is justified to focus on its location as characterizing the distribution of the frequencies. For the circular aperture, the central peak corner is defined by the first zero ($z_1$) of the Bessel function

So, the smaller the aperture the larger is the cutoff frequency.

To understand the connection with evanescent waves, we consider the extent of the Fourier Transform relative to the cutoff frequency signaling the transition between propagating modes and decaying modes. When the width of the main peak increases beyond this cutoff, the frequency distribution will include decaying modes. Reciprocally, the more the aperture size decreases, the more the decaying modes are excited.

For our simulated photodetector, the radius $a$ is 75 nm so the cutoff spatial frequency for the decaying mode behavior will be $k_{\perp }^{*}=z_1/a=51.1{\mu \mathrm{m}}^{-1}$, i.e., a cutoff wavelength ${\lambda }^{*}$ of 123 nm.

2.2.

Subwavelength Imaging

We next present a brief discussion of the impact of evanescent waves on image resolution. Returning to Eq. (7), which relates the field at $\overrightarrow{r}=({\overrightarrow{r}}_{\perp },z)$ to its spatial frequency components at $z=0$, we can define the factor

The OTF Eq. (14) changes from a propagating phase to an exponential decay factor, which suppresses the frequencies for above $k_{\perp }$

The OTF thus acts as a low-pass filter directly in frequency space. The larger the distance $z$ the more drastically it cuts off the high frequencies and the more the resulting image will be blurred.

For a subwavelength aperture of given radius $a$, it is possible to estimate the maximum distance at which detection is practical. Equivalently, for a given detection distance, it is possible to estimate the minimum-sized aperture detectable.

The starting point is Eq. (17) and the characterization of the frequency distribution by the central peak contained within the cutoff limit $k_{\perp }^{*}$ is defined in Eq. (12). Suppression of frequency ${\overrightarrow{k}}_{\perp }$ is significant when

At large distances this reduces to the usual diffraction criterion

At small distances, however this becomes

So that resolution is bounded only by the minimum separation of the detector from the sample, and is independent of the wavelength.

For completeness, we include an expression for maximum estimated distance to detect an aperture of radius $a$

Stated otherwise, the notion of wavelength is fundamentally a property of propagating, oscillating fields; evanescent modes are closer in nature to electrostatic fields. By measuring the sample at increasingly smaller distances, the exponential suppression can be mitigated, and the detector approaches sampling the precise field profile of the source.

2.3.

Electrical Device Modeling

The device couples a variety of physical phenomena to achieve detection of incoming radiation: the incoming electromagnetic wave is described by Maxwell’s equations, the electronic transport and charge distribution within the silicon is determined by the drift-diffusion equations for electrons and holes in a semiconductor coupled to Poisson’s equation, and these are augmented by statistical mechanics to describe the effect of doping on the carrier charge population. The interaction between the radiation and the silicon—photo-detection—involves indirect and direct interband transitions. This interaction occurs primarily within the Schottky junction that develops between the silicon bulk and the aluminum surface; the electronic properties of this junction reflect primarily the phenomenon of thermionic emission between the two materials. We will present here the differential equations in the bulk, and the boundary conditions, which are applied to the numerical algorithm to simulate these phenomena.

When a metal is brought in contact with an extrinsic semiconductor, a similar situation results, provided that the Fermi level of the metal is lower than that of the semiconductor, for $n$-type doping (in our case study). Electrons then diffuse from the semiconductor to the metal creating a depletion layer. In the simulation, the Schottky barrier junction between the aluminum and the silicon is realized as a boundary condition on the potential. This is possible because for a junction between a metal and a nondegenerately doped semiconductor the built-in potential falls, to good approximation, entirely on the side of the semiconductor. The metal, with its high density of states, can provide a space charge of almost arbitrarily high density. A very thin layer of charge is thus sufficient to neutralize an impinging field. The potential drop, which is proportional to the width, is thus much smaller on the metal side. At a junction between a metal and nondegenerately doped semiconductor, the metal acts essentially as an extremely highly doped semiconductor. For $n$-type-doped silicon, for instance, the metal acts as if it were $p$-type, accepting electrons and accumulating them in a thin surface layer as described above. We can thus make the approximation that the potential $\varphi$ takes the value it has in the bulk of the metal, on the boundary of the semiconductor, and falls to the bulk semiconductor value entirely within the semiconductor. As a quantitative analysis, one starts with the decomposition of the chemical potential into an internal component and an external component

The “external” component is an electrostatic contribution due to space charge accumulation, in this case the depletion layer

The “internal” component is determined by the band structure—in particular the conduction band edge $E_{\mathrm{c}}$ and the valence band edge $E_{\mathrm{v}}$—together with the Fermi level. For a nondegenerated semiconductor, for instance, the electrons are well described as an ideal gas obeying Boltzmann statistics; the latter contribution is the diffusion potential. This gives

Identifying the difference of the total chemical potential with the external bias, ${\mu }_{\text{total},\mathrm{m}}-{\mu }_{\text{total},\mathrm{s}}=qV$ gives the following boundary condition for the semiconductor potential $\varphi$:

One should note that in Comsol, the electrical potential is defined relatively to the metal vacuum level. In the simulation, we thus used the relation

The Schottky-junction is a heterojunction; there is a discontinuity in the band structure. As described above, the formation of a depletion layer leads to band bending; a potential barrier between the semiconductor and the metal is the result. Ideally, for an $n$-type semiconductor, the energy barrier height is defined¹³

The electronic behavior can be analyzed using the model of thermionic emission from the semiconductor to the metal. In this model, the current is found by using Boltzmann statistics to compute the average velocity as a thermal sum over all energies higher than the barrier. The barrier changes with the external bias $V$ and thus the velocity and hence the current $I$ depends on the external bias. The result is given by

3.1.

Photodetector Structure Simulation

The NSOM photodetector device is simulated as a truncated conical structure of $1.54\text{-}\mu \mathrm{m}$ height, $1\text{-}\mu \mathrm{m}$ bottom radius, and a 75-nm top radius (Fig. 3). The material is defined as $n$-type silicon crystal. Since Comsol software is based on finite elements calculation, a high density mesh of vertices is necessary to define the shape with enough resolution. To form a Schottky diode, a $1\text{-}\mu \mathrm{m}$-high surface of the structure from the top is defined as metal (Al) contact, where the bias voltage is applied respective to the grounded bottom.

Fig. 3

NSOM 3-D truncated conical-shaped photodetector device structure. The main parameters are: height is $1.54\mu \mathrm{m}$, top radius is 75 nm, and bottom radius is $<1\mu \mathrm{m}$.

In the simulated device, the contact area defined as the truncated cone surface is

3.2.

Preliminary Electrical Characterization

As a first attempt to check the physical consistency of the device simulation as a Schottky diode, the I–V curve is simulated without illumination at 300 K (Fig. 4). The current range is limited to 500 nA to keep a reasonable current density (lower than $10\mathrm{A}/{\mathrm{cm}}^2$). An exponential fit perfectly matches the I–V curve with an exponential factor of $27{\mathrm{V}}^{-1}$. This value is different from the calculated value from Eq. (35), i.e., $38.5{\mathrm{V}}^{-1}$ and may be related to the nonplanar geometry of the device.

Fig. 4

Simulated I–V curve without illumination at 300 K and exponential fit.

Then, we simulated the distribution of the electron current density in Fig. 5 at forward bias of 0.25 V. The scale of the current density is coherent with current values as shown in Fig. 4.

Fig. 5

Electron current density ($\mathrm{A}/{\mathrm{m}}^2$) without illumination for a forward bias of 0.25 V.

Since a diode photodetector is generally biased at reverse voltage, we investigated the distribution of the minority carriers (holes) concentration at $-0.5\mathrm{V}$ relative to the grounded bottom electrode, without illumination, as shown in Fig. 6. As observed there, the holes are accumulated at the top and at the $1\text{-}\mu \mathrm{m}$-height surface contact of the device. At the surface, max of the log concentration is 11.

Fig. 6

Simulated distribution of the holes concentration without illumination for a reverse bias of $-0.5\mathrm{V}$.

Further analysis was conducted for a reverse bias of $-0.5\mathrm{V}$ using several electrical simulations: distribution of the electron concentration showing the expected depletion region below the surface (Fig. 7) and the silicon electric potential $\varphi$ (Fig. 8) is defined by Eq. (32).

Fig. 7

Simulated distribution of the electron concentration showing the extension of the depletion area for a reverse bias of $-0.5\mathrm{V}$ without illumination.

Fig. 8

Simulated distribution of the electric potential for a reverse bias of $-0.5\mathrm{V}$. Metal work function for the Schottky contact is 4.72 eV.

3.3.

Influence of the Illumination

Simulation of light illumination applied at the top aperture of the truncated conical shape is shown in Fig. 9. A wavelength $\lambda$ of 550 nm was used to study the simulated distribution of and the minority carrier’s (holes) concentration under illumination power of 0.1 W as shown in Fig. 10. Also, in Fig. 10 we can see the small increases in the holes (minority carriers) concentration due to illumination. The max log of concentration is 11.5 at the top, when compared with 11 without illumination (Fig. 6).

Fig. 9

Illumination coupled to the top of the truncated conical shape. Wavelength is 550 nm.

Fig. 10

Distribution of holes concentration showing changes in depletion size area. Bias voltage $-0.5\mathrm{V}$ under illumination power 0.1 W and $\lambda =550\mathrm{nm}$.

3.4.

Evanescent Decay of the Radiation Field

As discussed above, radiation transmitted through a subwavelength aperture is expected to decay with distance depending on the distance $z$ relative to the aperture radius $a$. Indeed, at large distance ($z\gg a$), the field behaves like a classic propagating wave and decays as a square law expressed in Eq. (1). But, at short distance $z\lesssim a$ the radiation will decay as an exponential law as mentioned by the OTF expression [Eq. (17)]. In addition, optical absorption by the silicon will also lead to an exponential decay of the intensity within the device, according to the Beer–Lambert rule. Figure 11 shows the behavior of the electric field as a function of the distance $z$ along the central axis of the device for several wavelengths (50 and 300 nm) in air and silicon media. It is observed that the 50 nm does not present decay in air medium, since it is not influenced from the diffraction phenomena from the 150-nm aperture. However, it presents a clear decay in the silicon medium due to Beer–Lambert law (for such wavelengths the absorption is very small, about 10 nm). For 300 nm, there is a similar decay in air and silicon, mainly due to the diffraction from the aperture of 150 nm (evanescent wave), so Beer–Lambert law is less influencing. The difference in the electrical field amplitudes between the wavelengths seems to be caused by the difference in the energy, since the energy is a function of the wavelength ($\sim 1/\lambda$), and of the squared electrical field. Under such conditions, the 50 nm has bigger amplitude than the 300 nm in the air.

Fig. 11

Decay of the incident electric field for two different wavelengths: 50 and 300 nm, respectively, below and above the diffraction limit (for a circular aperture of 75 nm radius).