Surface engineering is an emerging technology to design antiviral surfaces, especially in the wake of COVID-19 pandemic. However, there is yet no general understanding of the rules and optimized conditions governing the virucidal properties of engineered surfaces. The understanding is crucial for designing antiviral surfaces. Previous studies reported that the drying time of a residual thin-film after the evaporation of a bulk respiratory droplet on a smooth surface correlates with the coronavirus survival time. Recently, we [Chatterjee et al., Phys. Fluids. 33, 021701 (2021)] showed that the evaporation is much faster on porous than impermeable surfaces, making the porous surfaces lesser susceptible to virus survival. The faster evaporation on porous surfaces was attributed to an enhanced disjoining pressure within the thin-film due the presence of horizontally oriented fibers and void spaces. Motivated by this, we explore herein the disjoining pressure-driven thin-film evaporation mechanism and thereby the virucidal properties of engineered surfaces with varied wettability and texture. A generic model is developed which agrees qualitatively well with the previous virus titer measurements on nanostructured surfaces. Thereafter, we design model surfaces and report the optimized conditions for roughness and wettability to achieve the most prominent virucidal effect. We have deciphered that the optimized thin-film lifetime can be gained by tailoring wettability and roughness, irrespective of the nature of texture geometry. The present study expands the applicability of the process and demonstrates ways to design antiviral surfaces, thereby aiding to mitigate the spread of COVID-19.
Surface engineering is an emerging technology to design antiviral surfaces, especially in the wake of COVID-19 pandemic. However, there is yet no general understanding of the rules and optimized conditions governing the virucidal properties of engineered surfaces. The understanding is crucial for designing antiviral surfaces. Previous studies reported that the drying time of a residual thin-film after the evaporation of a bulk respiratory droplet on a smooth surface correlates with the coronavirus survival time. Recently, we [Chatterjee et al., Phys. Fluids. 33, 021701 (2021)] showed that the evaporation is much faster on porous than impermeable surfaces, making the porous surfaces lesser susceptible to virus survival. The faster evaporation on porous surfaces was attributed to an enhanced disjoining pressure within the thin-film due the presence of horizontally oriented fibers and void spaces. Motivated by this, we explore herein the disjoining pressure-driven thin-film evaporation mechanism and thereby the virucidal properties of engineered surfaces with varied wettability and texture. A generic model is developed which agrees qualitatively well with the previous virus titer measurements on nanostructured surfaces. Thereafter, we design model surfaces and report the optimized conditions for roughness and wettability to achieve the most prominent virucidal effect. We have deciphered that the optimized thin-film lifetime can be gained by tailoring wettability and roughness, irrespective of the nature of texture geometry. The present study expands the applicability of the process and demonstrates ways to design antiviral surfaces, thereby aiding to mitigate the spread of COVID-19.
The ongoing COVID-19 pandemic caused by the SARS-CoV-2 (referred to as coronavirus
hereafter) has created a huge health and an economic crisis throughout the world. The
disease spreads via respiratory droplets, a fact which is well-documented.
Researchers have devoted significant attention in investigating and analyzing the different
routes of disease transmission and their relative importance. The governing transport mechanism for the virus to attack a target
is its rotational diffusivity. The
spread of infection can be airborne, i.e., via aerosol, and the persistence of the aerosols
plays a significant role in determining the transmission probability. Apart from airborne
transmission, the virus-laden droplets can also deposit on a surface forming fomite, which
serves as secondary source of transmission upon touch. Several measures to mitigate the disease transmission have been
studied and demonstrated by the researchers across the globe. Face masks and face shields
have been found to be the most effective ways to stop the disease spread through the aerosol
route of transmission. To reduce the risk of infection through fomite route,
sanitization of surfaces was recommended by the WHO. In addition, Chen et al. demonstrated a new way of deactivating coronavirus by
applying cold atmospheric plasma (CAP). However, in many circumstances, it may be
inconvenient to disinfect a contaminated surface by frequent sanitization/CAP processing.
This fact marks the need to fabricate surfaces with virucidal properties,
i.e., surface properties by virtue of which the virus cannot survive longer on them and the
deposited viral load decays rapidly. For example, it was previously demonstrated that polycations of
polymer surfaces cause rapid viral disintegration. However, the applicability of such coating technology is
limited by lack of durability and less mechanical stability, which demands design of more
robust antiviral surfaces.Since the aqueous phase of the respiratory droplet serves as a medium for survival of
enveloped virus such as coronavirus, the dynamics of the droplet plays an important role in
deciding the transmission probability. In particular, evaporation determines the eventual
fate of the droplet, and thereby it is correlated with the survival timescale of the
virus. It has been
demonstrated that the time decay of virion concentration is correlated with the volume loss
of the respiratory droplet due to evaporation. For this reason, the virus survival and infection spread are related
to the environmental condition, e.g., ambient temperature and relative humidity. To this extent, recently,
Bhardwaj and Agrawal established
that by considering a surrogate droplet of pure water, the drying timescale of the droplet
and a residual thin film after the evaporation of the bulk droplet are correlated with the
decay timescale of virus titer on different surfaces. While the evaporation of the bulk
droplet is much faster [∼O(s)], which is governed by the diffusion of liquid–vapor (LV)
outside the droplet, the evaporation of
the residual thin film is governed by the disjoining pressure and is a much slower process
than the former. Therefore, the lifetime
of the residual thin-film contributes to the maximum portion of virus survival time, and
attention should be devoted to look at the evaporation rate of the residual thin-film to
analyze the virus survival time on the surface in question. More recently, Chatterjee
et al. demonstrated
that the evaporation rate of the residual thin-film is much faster on porous surfaces than
impermeable surfaces, making the porous media lesser susceptible to virus survival. The
aforesaid faster evaporation rate was attributed to the modification of the effective
solid–liquid (SL) interfacial area due to the presence of horizontally oriented fibers and
void spaces on porous surfaces, which leads to an enhancement in the energy required to form
unit area solid–liquid interface, and thereby resulting in an augmented disjoining pressure
within the thin-film.Motivated by the aforementioned facts, the authors of the present manuscript analyze the
drying of a respiratory droplet and residual thin-film on physically textured surface with
varying wettability. In particular, it is imperative to explore the effect of surface
texturing on the effective solid–liquid interfacial area, and thereby the resultant
thin-film evaporation rate. On the other hand, wettability of the underlying surface would
additionally contribute to the thin-film evaporation rate by virtue of its influence on the
excess energy within the film. Tailoring
wettability was previously found to be a promising tool for curbing the risk of
infection; however, its coupling with
surface texture remains unknown. The motivation further arises from the fact that surface
modification and engineering are learnt to be a contemporary and yet emerging technology to
achieve antiviral surfaces. While
there have been several previous efforts to design antibacterial surfaces by surface
engineering, Hasan et
al. made a valuable
contribution in this direction by fabricating nanostructured surfaces by wet-etching to
induce antiviral properties, and they monitored the virus titer at
different times after the surfaces were exposed to viral inoculum. They found that the
structured surfaces are much lesser conducive to virus survival as compared to flat
surfaces. However, their study was limited to aluminum surfaces, and how one can control the
texture to achieve optimized virucidal effects remained an unanswered question. In view of the above, the distinction of
the present study is that it aims at answering the following specific research questions.
(1) What is the combined effect of wettability and surface texture on the evaporation
dynamics of the residual thin-film? The insights would be useful in advancing the
fundamental knowledge in the field. This is because the physics of thin-liquid films on
solid surfaces has engaged the researchers to study variety of phenomena, e.g., formation of films, stability or instability of the
thin-film under different conditions, the effect of surface heterogeneity on the instability and
pattern of thin-films, and subsequent
dewetting mechanism and patter formations, and their molecular origin has been extensively studied both
numerically and by experiments. Thus, the thin-film evaporation mechanism
on textured surfaces and understanding the factors governing it are fundamental research
questions. (2) From the COVID-19 point of view, is there any optimum condition of
wettability and surface roughness in which the drying rate is the highest? (3) How one can
tailor these factors in order to achieve the maximum virucidal effects? Finding answers of
the above research questions would have important implications. This is because our previous
study demonstrated that the
impermeable materials are more susceptible to coronavirus survival than the porous
materials. Thereby, the present study is an attempt to tailor the impermeable surfaces for
making them lesser conducive to virus survival.
THEORY
Background
With an aim to expand the applicability of the process, we first develop a generic
analytical model to understand the thin-film evaporation rate in relation to the virucidal
properties of textured surfaces, based upon the knowledge gained from our previous
study. The model is first
compared with the previously reported virus titer measurements, and a reasonable agreement has been found (cf. Sec. III). Thereafter, we demonstrate model surfaces with
varied texture and wettability, and the optimized condition for achieving the desired
virucidal effects has been analyzed (cf. Sec. IV).
Figure 1 depicts the schematic diagram of the
problem. A respiratory droplet is first deposited on a hydrophilic, textured surface [cf.
Fig. 1(a)]. Depending upon the roughness and
intrinsic wettability of the surfaces, the droplet can remain either in Wenzel or in
Wet–Cassie regime (discussed later in Sec. IV A).
After deposition, the droplet first undergoes diffusion-limited evaporation in either
state [cf. Figs. 1(b) and 1(c)]. Thereafter, a thin residual film is left behind the evaporated
droplet. The formation of the residual thin-film would depend on the regime in which the
previously deposited droplet remained [cf. Figs. 1(d)
and 1(e)]. The different regimes and conditions for
their applicability will be discussed below in line with the model formulation and
results.
FIG. 1.
Schematic of the problem considered in the present work.
Schematic of the problem considered in the present work.
Model for thin-liquid film evaporation on engineered surface
We develop an analytical model for the evaporation mechanism of the thin-liquid film,
which remains after the diffusion-limited evaporation of the bulk droplet, as shown
schematically in Figs. 1(d) and 1(e). The time variation of thickness
h(t) [cf. Figs.
1(d) and 1(e)] of the evaporating thin film
on a smooth solid surface is given by
where ρ is the liquid
density (=1000 kg/m3, for water), and the evaporation mass flux
J is given by
where A,
γ, and R are, respectively, the Hamaker constant of
interaction between liquid–vapor and solid–liquid interfaces, the surface tension of the
liquid (0.072 N/m, for water), and wetted radius. In Eq. (2), = 461.5 J/kg K is the specific gas constant for water
vapor, ρ = 0.023 kg/m3 is the density of water
vapor at ambient, and T = 298 K is the ambient temperature.
Using the values of , ρ, and
T, the prefactor outside the parenthesis of Eq. (2) can be calculated as follows: SI units. The first term within the parenthesis of Eq.
(2) represents the disjoining pressure
P(h) within the film, while the second term is the
Laplace pressure. It was previously shown that the Laplace pressure is one order of magnitude less than
the disjoining pressure for nanometric thin-films and, therefore, can be ignored in Eq.
(2). Hence, neglecting the Laplace
pressure term in Eq. (2) and then
integrating Eq. (1) with respect to time
(t) give h(t) as a function of
t as follows:
Next, the effect of surface modification (both in terms
of wettability and texture) on the evaporation mechanism of the residual thin-film will be
formulated. The equilibrium between the different interfacial energies, namely, the
liquid–vapor (γ), solid–vapor
(γ), and solid–liquid (γ)
interfacial energies in terms of contact angle (θ), is given by the
classical Young's equation
where E is the energy
required to form a unit area of solid–liquid interface. On the other hand, for the case of a film covered surface, the
modified surface energy () reads as
where is the excess energy of the film, which is the derivative
of the disjoining pressure () within the thin-film. Considering that for a nanometric
thin-film γ is one order magnitude less than ; if the quantity is enhanced by a factor λ, then would also be enhanced by the same factor. With this
enhancement, the modified evaporation mass flux (J) becomes [cf. Eqs.
(1) and (2)]
. If a surface processing technique (including both chemical
modification and physical texture) modifies the apparent contact angle of the surface in question from
θ0 to , then it directly follows from Eq. (4) that Hence, if and θ0 are known,
λ and the corresponding J can be
obtained to evaluate the modified h(t) from Eq. (3). Therefore, the enhancement of a microscopic
quantity [or P(h)] can be obtained
from macroscopic contact angle values.In the framework of the formulation, the effect of surface wettability and texture on the
resultant λ can be separately discerned. The contribution of wettability
can be separated by evaluating the Hamamker contact (A) of
interaction between the SL and LV interfaces for the
corresponding contact angle. In a process involving both chemical modification and
physical modification by texture-induced roughness of a surface, let us assume that the
change in contact angle and associated A are as follows: , wherein . Depending upon the intrinsic wettability and the
roughness, the droplet-substrate system may remain either in Wenzel or Wet–Cassie state
(cf. Fig. 1), which, along with wettability, would determine the resultant
λ and thereby the formation of the residual thin-film. The details of
these states, their applicability, and conditions along with the incorporation in the
present model will be discussed later (cf. Sec. IV A).We first evaluate the Hamaker constant corresponding to the SL and
LV interfacial interaction from the contact angle. To evaluate or , we consider a generic contact angle θ to
obtain a generic A. The solid–liquid adhesive energy
(W) for some θ reads as where N/m for water. Since the dispersive component of the
surface interaction energies dominates wetting phenomena,
W is related to dispersive component of the surface free
energy of the solid () and liquid ( N/m for water) by the Berthelot's geometric mean rule which reads as The Hamaker constant of the solid surface in question
(A11) is related to () as
where D0 is the interfacial
contact separation, and an “universal constant value” of 0.165 nm can be assigned to
it. From Eqs. (7)–(9), A11
can be obtained from θ. The Hamaker constant
A of interaction between SL and
LV interfaces can be evaluated from A11,
and the Hamaker constant of air () and liquid ( J) can be evaluated by using the following relation:Plugging A computed from Eq. (10) and λ from Eq. (6), we obtain J and corresponding
h(t) for an engineered surface by using Eq. (3).
VALIDATION AGAINST PREVIOUS SARS-CoV-2 TITER MEASUREMENTS
In our previous reports, the
change in the thickness of the liquid film with time and its correlation with the slope of
reduction of coronavirus titer with time was examined. The slope of reduction of virus titer
was found to match qualitatively well with the thickness (or volume) change with time of the
film for all cases examined in the studies. The thin-film thickness variation explained the
coronavirus survival both for the cases of impermeable and porous surfaces. Thus, the
analysis yields useful results to explain the virus survival time on different surfaces
qualitatively; that the time-varying virus titer scales with the time-varying thin-film
thickness, and thereby assessing the risk factors associated with different surfaces of use.
Motivated by these findings, herein we compare the model developed to obtain the
time-varying thin-film thickness h(t) on textured surfaces
(cf. Sec. II B) with the previous virus titer
measurements on nanostructured surfaces.
In the previous virus titer measurements, pure aluminum (Al 6063 alloy) substrate and nanostructured aluminum
surface fabricated by wet-etching (called as “etched aluminum” surface) were exposed to
10 μl of viral inoculum ( TCID50/ml), and the virus titer
[TCID50/ml (log10)] was monitored at different time points after the
exposure. They reported that the
wet-etching process leads to the formation of aluminum hydroxide and nanostructures grouped
as ridges. This process alters the apparent contact angle from to .
Following the formulation presented in Sec. II B, we
get J. Using this value for A, and
λ = 1 and 8.4155 [cf. Eq. (6)] for smooth and etched aluminum surfaces, respectively, one can evaluate the
time evolution of residual thin-film thickness [h(t)] on
them. This analysis takes into account both the effect of chemical and roughness
modification induced by the wet-etching process, enabling us to compare the virucidal
properties of etched aluminum and smooth aluminum surfaces.Figure 2 shows a qualitative comparison of
time-varying thin-film thickness with the previous virus titer measurements. The initial film thickness is taken as
350 nm in the present calculations. The slope of the time-varying film thickness agrees
qualitatively with the virus titer decay with respect to time, with comparable thin-film
lifetime and virus survival time on smooth and etched aluminum surfaces. On smooth aluminum
surfaces, 3–4 log reduction () in the virus titer was recorded after 24 h of exposure (cf. Fig.
2). The present model predicts an equivalent decay in thin-film thickness within h. On etched aluminum surfaces, the virus was effectively
inactivated within 6 h of exposure (5-log reduction), and from Fig. 2, it is noted
that the model also returns the same timescale ( h) of decay of the liquid-thin film thickness due to the
disjoining pressure-driven evaporation. Overall, the time-varying thin-film thickness
matches well with the decay of virus titer reported earlier, and the agreement between the two dataset is consistent with our
previous paper. Thus, the
analytical model captured the higher virucidal effect of the etched aluminum surface as
compared to smooth aluminum surface. It is noteworthy that the present model considers the
enhancement of thin-film evaporation rate (and hence the virucidal property) by virtue of
contact angle modification, which is a macroscopic and easily measurable quantity.
Furthermore, since the contact angle modification is the result of both chemical
modification and texture induced roughness, the model incorporates both the effects by a
single parameter. Therefore, a generic model has been developed, irrespective of the
specific feature of the surface geometry, which may help in expanding the applicability of
the process of surface modification and texturing to induce virucidal effects.
FIG. 2.
Time-varying evaporating thin-film thickness (h, plotted as blue and
red lines for smooth and etched aluminum surfaces, respectively) and virus titer
[TCID50(log10), plotted as blue and red circles for smooth and
etched aluminum surfaces, respectively]. The virus titer data with the error bar have
been reproduced from the recent study. The initial thin-film thickness is taken as 350 nm.
Time-varying evaporating thin-film thickness (h, plotted as blue and
red lines for smooth and etched aluminum surfaces, respectively) and virus titer
[TCID50(log10), plotted as blue and red circles for smooth and
etched aluminum surfaces, respectively]. The virus titer data with the error bar have
been reproduced from the recent study. The initial thin-film thickness is taken as 350 nm.
DESIGNING ANTIVIRAL SURFACES
Concept
The above analysis and comparison with virus titer data motivate us to model engineered
surfaces across a wide variation of wettability and texture induced roughness. For this, a
few physical aspects have been considered. First, it is well-known that if the surface
under question is intrinsically hydrophobic ( or ), then (or ). Hence, roughening a surface with would reduce λ by virtue of Eq. (6), and therefore, the thin-film evaporation
would be decelerated resulting in a longer virus survival time. Therefore, a surface
engineering process should first modify the contact angle such that .In the process exercised by Hasan et al., this criterion was met by the formation of aluminum hydroxide
due to wet-etching, confirmed by energy dispersive x-ray spectroscopy (EDS) and x-ray
photoelectron spectroscopy (XPS) measurements. Once a is obtained, surface texture can further lead to a , as it is well-documented that roughness enhances the
hydrophilicity of an intrinsically hydrophilic surface. Therefore, in the analysis presented below for the model
surfaces, θ is varied in the range of 0° to 90°, and the
quantity is defined as the contribution of physical texture induced
roughness to λ in Eq. (6).
A rough surface is characterized by two factors: (i) the roughness factor,
r, which is the ratio between the actual area of the rough surface and
its projected area and (ii) the solid area fraction, , which is the ratio between the solid area at the top
surface and the projected area. Furthermore, when a droplet is deposited on a rough
surface with , two distinct regimes are possible depending upon the intrinsic wettability
(characterized by θ) and the roughness (characterized by
r and ), as shown schematically in Fig. 1. The first regime is the Wenzel regime, realized for higher
θ, in which the droplet triple phase contact line follows
all the topographical variations of the surface [cf. Fig.
1(b)]. This regime is characterized by . Hence, in the Wenzel regime, . However, there exists a limit in the applicability of the
Wenzel formulation that a surface cannot be made infinitely hydrophilic by inducing
roughness, which precipitates the onset of the second regime discussed below.The second regime is the hemiwicking (henceforth, referred to as Wet–Cassie) regime, in
which a part of the liquid departs from the droplet and impregnates through the crevices,
and the rest of the droplet resides on a patchwork of solid and liquid, as shown
schematically in Fig. 1(c). This regime is
characterized by . Hence, in this regime, . In either regime, satisfies the condition that , i.e., , and it should be noted that the Wet–Cassie regime is
characterized by a lesser enhancement in the hydrophilicity, i.e., lesser enhancement in the energy required to
form unit area of solid–liquid interface.The condition for realizing the Wet–Cassie regime is that θ
must be less than a critical value, θ, such that . Hence, whether for a given surface, the transition from
Wenzel to Wet–Cassie regime is determined by both the chemical details (by virtue of
θ) as well as the geometric features (by virtue
θ). Due to the differences in the droplet interaction
with the substrate surface in the aforesaid two regimes, the formation of the residual
thin film after the diffusion-limited evaporation of the bulk droplet would also be
different, as schematically shown in Figs. 1(d) and
1(e). The modified evaporation mass flux
(J) of the residual thin-film will, thus, be governed
by the appropriate λ and , thereby modifying Eq. (3) as The factor is, therefore, crucial in dictating the temporal variation
of film thickness h (hence, the film evaporation rate) on the engineered
surfaces. Below, we analyze the optimum conditions for θ and
r to achieve the fastest evaporation rate of the residual thin-film,
leading to the most effective virucidal properties.
Proposed design
We consider two engineered surfaces, which are shown schematically in Fig. 3: (i) surfaces with rectangular parallel grooves
[cf. Fig. 3(a)] and (ii) surfaces with rectangular
pillars [cf. Fig. 3(b)], as it was previously
demonstrated that an arbitrary rough surface can be well-approximated by a square-wave
generic model in two dimensions to estimate r and by
virtue of which the model detailed in Sec. II B can
be applied. These simpler geometries are easier to model and from a practical point of
view, such surfaces are easier to fabricate by conventional, widespread
nano/micromachining techniques, such as focused ion beam (FIB), electron beam lithography,
and photo lithography. The generic
model that was employed to examine the correlation between the thin-film lifetime and the
virus survival time in Sec. III will be applied
herein to analyze the model surface configurations depicted in Fig. 3. This way, the two model surfaces considered herein, is
sufficient to reach the research goal, as highlighted in Sec. I.
FIG. 3.
Schematic of the model surfaces: (a) with rectangular parallel grooves and (b) with
rectangular pillars. h: surface height with respect to the base;
a: lateral dimension of the heights; g: gap
between the heights; and : pitch.
Schematic of the model surfaces: (a) with rectangular parallel grooves and (b) with
rectangular pillars. h: surface height with respect to the base;
a: lateral dimension of the heights; g: gap
between the heights; and : pitch.As shown in Fig. 3, for both surfaces, the lateral
dimensions of the features of height h (with respect to the base) are
a × a, having a gap of g between
them. Hence, the pitch is . From geometry, r and are determined as
and for surfaces with rectangular grooves; and
and for surfaces decorated with rectangular pillars.
Analysis and optimization of parameters
Next, we analyze the thin film evaporation mechanism on the model surfaces for . However, for the sake of contrast and comparison, first a
smooth surface () is considered. From Fig.
4, it is seen that increases with decreasing θ
[cf. Eqs. (7)–(10)]. Consistent
with our earlier findings, the
thin-film lifetime is lesser for lower θ ( h for to h for ). Therefore, our present analysis meets the physical
requirements.
FIG. 4.
Analysis of thin-film evaporation on smooth surface; (a) variation
A with θ and (b) regime
map of film thickness h(t) with respect to time
(t) and θ.
Analysis of thin-film evaporation on smooth surface; (a) variation
A with θ and (b) regime
map of film thickness h(t) with respect to time
(t) and θ.Furthermore, we analyze the engineered surfaces with rectangular parallel grooves [cf.
Fig. 3(a)]. Figures
5(a) and 5(b) show the regime maps of
r and with respect to a/h and
a/g for the model grooved surfaces. As expected,
r increases for low a/h and high
a/g, and is independent of a/h,
however, increases with a/g. Using these regimes for
r and , we attempt to compute θ, and
thereby, the regimes for the applicability of Wenzel and Wet–Cassie formulation for the
model grooved surfaces are deciphered. From Fig.
5(c), it is seen that for the model grooved surfaces,
θ varies from to within the range of a/h
and a/g considered herein. Accordingly, Fig. 5(d) depicts that the system would remain in Wenzel
regime for higher θ and in the Wet–Cassie regime for low
θ. For low roughness, lesser
θ is required for transition from Wenzel to Wet–Cassie
regime. The opposite is true for higher roughness.
FIG. 5.
(a) Variation of r with respect to
a/h and a/g, (b)
variation of with respect to a/h
and a/g, (c) regime map of
θ for varying a/h and
a/g, and (d) the Wenzel and Wet–Cassie regimes for
varying θ and r. Results shown for the
grooved surfaces.
(a) Variation of r with respect to
a/h and a/g, (b)
variation of with respect to a/h
and a/g, (c) regime map of
θ for varying a/h and
a/g, and (d) the Wenzel and Wet–Cassie regimes for
varying θ and r. Results shown for the
grooved surfaces.Now, the thin-film lifetime (t) for varied
θ and r will be analyzed for the grooved
surfaces. Figure 6 depicts the results. From Fig. 6(a), it is noted that r varies
linearly with and the slope increases with decreasing
a/h, which is evident from Eqs. (12) and (13). In this work, r is chosen as the representative
of roughness. Figure 6(b) depicts the regime map of with respect to r and
θ. In the context of Fig.
5(d), it is noted that for high roughness
(r > 10), approaches to zero (complete wetting) in the Wenzel regime;
the Wet–Cassie regime is not reached at all. At lower roughness, an overlap between the
Wenzel and Wet–Cassie regime is noted, depending upon the value of
θ. However, for low r, complete wetting is
obtained in the Wet–Cassie regime only. This leads to a change in slope of the constant curves near .
FIG. 6.
(a) Variation of r as a function of for different a/h,
(b) regime map of with respect to r and
θ, (c) regime map of with respect to r and
θ, and (d) regime map of
t with respect to r and
θ. (Multimedia view) Animation depicting regime map
of time varying thin-film thickness [h(t)] with
respect to r and θ. The results are
shown for the grooved surfaces. Multimedia View: https://doi.org/10.1063/5.0049404.1
(a) Variation of r as a function of for different a/h,
(b) regime map of with respect to r and
θ, (c) regime map of with respect to r and
θ, and (d) regime map of
t with respect to r and
θ. (Multimedia view) Animation depicting regime map
of time varying thin-film thickness [h(t)] with
respect to r and θ. The results are
shown for the grooved surfaces. Multimedia View: https://doi.org/10.1063/5.0049404.1Since the resultant J-profile J and hence
the h(t) of the residual thin-film depends on both
r and θ [cf. Eq. (11)], in Fig.
6(c), a regime map of the quantity with respect to r and
θ is depicted. Importantly, is the highest () in the range and . Hence, it is concluded that there must be having an
optimum range of r and θ, in which the
resultant enhancement in the J-profile would be the highest. In Fig. 6(d) (multimedia view), we present a regime map of
the thin film lifetime (t) with respect to r
and θ. The associated movie presents an animation to depict
the temporal evolution of thin-film thickness with time
[h(t)]. The animation is presented for a total time of
27 h, with a time step of 0.5 h. The movie is played at 2 frames per second for enhanced
clarity. From the results, it is noted that the optimum range of r and
θ, in which the highest thin-film evaporation rate is
realized, is and , which corresponds to and , respectively (cf. Fig.
5). In this range, the model yields a thin-film lifetime of h. Also, it is noted that at low roughness () and high θ, the thin-film
lifetime approaches to that of a smooth surface having lesser wettability ( h). Hence, at low roughness (), faster thin-film evaporation can be achieved by lowering
θ, and in this regime, the thin-film lifetime approaches
to that of a smooth surface having higher wettability [cf. Fig. 4(b)]. This fact can be better understood from the associated animation.
One can see that the thin-films in the regions of and dry at the earliest ( h). Thereafter, in the regions of lower roughness () and higher wettability (), and in the regions of lower wettability () and higher roughness () with h. The thin-film in the regions of lower wettability () and lower roughness () dries at last ( h). Figure 8(d)
(multimedia view) and the associated animation, thus, demonstrate that by optimizing the
θ and r, five times lesser thin-film
lifetime and corresponding virucidal effects can be achieved.
FIG. 8.
(a) Variation of r as a function of for different a/h,
(b) regime map of with respect to r and
θ, (c) regime map of with respect to r and
θ, and (d) regime map of
t with respect to r and
θ. (Multimedia view) Animation depicting regime map
of time varying thin-film thickness [h(t)] with
respect to r and θ. The results are
shown for the pillared surfaces. Multimedia View: https://doi.org/10.1063/5.0049404.2
Next, we analyze the model surfaces with rectangular pillars [cf. Fig. 3(b)]. Figures 7(a) and 7(b) represent the variation of r and , respectively, with respect to varying
a/h and a/g ratios
for the model pillared surfaces. Figures 7(c) and
7(d) depict the regime map of
θ with respect to a/h and
a/g, and the regimes of applicability of the Wenzel
and Wet–Cassie regimes for different r and
θ, respectively. Noteworthy that a comparison between Fig. 5 with Fig. 7
shows that the parameters r, , and θ exhibit an universal
behavior irrespective of the specific geometry (grooves/pillars). This is further
manifested in the thin-film lifetime as depicted in Fig.
8. Similar to the observation for the grooved surfaces (cf. Fig. 6), for the cases of pillared surfaces also, r
increases linearly with with the slope increasing as
a/h decreases, which follows from Eqs. (14) and (15) [cf. Fig. 8(a)]. Furthermore,
the regime map of θ for pillared surfaces [cf. Fig. 8(b)] also exhibits similar behavior as observed for
grooved surfaces [cf. Fig. 6(b)]. A comparison
between Figs. 6(c) and 6(d) (multimedia view) and Figs. 8(c) and
8(d) (multimedia view) shows that the regime maps
of and t behave in the same way
for the respective cases of grooved and pillared geometries. Similar to the case of
grooved surface, for pillared surfaces also, we observe that there is a optimum condition
for r and θ to achieve the highest thin-film
evaporation rate by virtue of the optimized . The movie corresponding to Fig. 8(d) (multimedia view) is an animation depicting the time-varying film
thickness h(t) with respect to r and
θ. The animation runs for a total time of 27 h with a
time step of 0.5 s. For the pillared geometry, the highest thin-film evaporation rate
(lowest t) is realized for θ
within the range of and for r within the range of 3–11, which
corresponds to and (cf. Fig. 7). Hence,
the thin-film evaporation rate is dictated by the parameters
θ and r (or ), irrespective of the specific geometry.
FIG. 7.
(a) Variation of r with respect to
a/h and a/g, (b)
variation of with respect to a/h
and a/g with respect to r and
θ, (c) regime map of θ
for varying a/h and
a/g, and (d) the Wenzel and Wet–Cassie regimes for
varying θ and r. The results are shown
for the model pillared surfaces.
(a) Variation of r with respect to
a/h and a/g, (b)
variation of with respect to a/h
and a/g with respect to r and
θ, (c) regime map of θ
for varying a/h and
a/g, and (d) the Wenzel and Wet–Cassie regimes for
varying θ and r. The results are shown
for the model pillared surfaces.(a) Variation of r as a function of for different a/h,
(b) regime map of with respect to r and
θ, (c) regime map of with respect to r and
θ, and (d) regime map of
t with respect to r and
θ. (Multimedia view) Animation depicting regime map
of time varying thin-film thickness [h(t)] with
respect to r and θ. The results are
shown for the pillared surfaces. Multimedia View: https://doi.org/10.1063/5.0049404.2
DISCUSSION
The generic analytical model developed herein depicts the evaporation mechanism of a
thin-liquid film resting on textured surfaces having varied wettability, which aids to
design surfaces with enhanced virucidal properties in the context of COVID-19. The model
takes into account the effect of both surface wettability and texture within the purview of
a macroscopic measurable quantity, the contact angle. The formulation allows to discern the
individual contributions of chemical modification-induced altered wettability and
texture-induced roughness on the evaporation mechanism of a thin-liquid film on engineered
surfaces. Comparison of the model predictions with the previous virus titer
measurements (cf. Sec. III) substantiates the fidelity of the theory. Thereby, the
results depicted in Sec. IV for the designed surfaces
are crucial in dictating the performance of the antiviral surfaces to suppress the spread of
COVID-19.First, it is deciphered that the process of fabricating antiviral surface should include a
chemical treatment, so that the intrinsic wettability falls within the hydrophilic regime.
This is because the physically textured surfaces should exhibit a lesser apparent contact
angle than that of a smooth surface having the same chemical details in order to enhance
E, so that the thin-film evaporation rate becomes faster
by virtue of an augmented disjoining pressure (cf. Sec. IV A). Second, for a droplet deposited on an hydrophilic surface, two regimes are
possible, which decide the formation of the residual thin-liquid film after the evaporation
of the bulk droplet. The regimes are, as discussed in Sec. IV A, the Wenzel and the Wet–Cassie regime. The regime in which the droplet will
stay is dictated both by the intrinsic wettability and surface roughness. These two regimes
are characterized by different enhancement in E, and
therefore, the resultant enhancement in the thin-film evaporation rate will be governed by
both wettability and roughness. By taking into account the applicability of both the
regimes, we found that there exists a optimum range of wettability
(θ) and roughness (r) where the thin-film
lifetime is the lowest, indicating the strongest virucidal effects. Interestingly, as
demonstrated in Sec. IV C in light of the comparison
between Figs. 6 (multimedia view) and 8 (multimedia view), the evaporation dynamics of the
thin-film is dictated by r and θ irrespective
of the geometric details (grooved/pillared). This is also true for the optimization of
parameters. Furthermore, it is worth noting that both for the cases of grooved and pillared
geometry, for and , the thin-film lifetime returns in h. This is also consistent with the titer decay timescale
reported by Hasan et al., wherein the coronavirus survival time was found to be h on surfaces decorated with nanostructures grouped in
ridges, wherein and (area ). Hence, the generic model developed herein, by taking into
account the effect of wettability and roughness, rightly captures the essential mechanism
behind the virucidal properties of textured surfaces. It demonstrates that the optimum
thin-film evaporation rate can be achieved by tailoring r and
θ, irrespective of the specific geometry of the texture.
This is essentially the consequence of Eq. (6), wherein all the modification induced by the surface engineering process has
been accommodated within the ambit of contact angle.The present analysis expands the applicability of the process; one may fabricate any kind
of geometric structures as per the convenience and the availability of the fabrication
technique in order to achieve the same outcome. The optimized operating conditions reported
in Figs. 6 and 8
should be accounted for to obtain the best results. We also point out that the findings
reveal that within the preferred range of θ, there exists a
range of roughness () for which the optimized thin-film evaporation rate (and
hence the virucidal effect) is realized. This is further beneficial because surface
texturing involves sophisticated techniques such as laser writer, electron beam lithography,
focused ion beams, and chemical etching. Our results indicate that for the given range of
θ, one may choose any r within the range
of optimized thin-film evaporation rate, thereby optimizing the operating time and cost.
Hence, surface texturing and tailoring wettability can be considered as a viable tool for
inducing enhanced virucidal properties to surfaces.For the sake of better clarity and contrast, we present a case study of the thin-film
lifetime or the virucidal effects across varying wettability and texture. Figure 9 schematically represents the same, which is an
excerpt of the findings presented in this communication. As outlined in Sec. IV B, it is plausible to represent rough surface by a
square-wave pattern in the two-dimensions. For a given surface, if , the surface engineering process should include a chemical
modification by which is obtained in order to enhance the thin-film evaporation
rate, and thereby the virucidal effects by introducing additional roughness. Furthermore,
surfaces with taller and closely packed surface heights (say, for example and ) fall within the aforementioned range required for
optimization with respect to roughness (), and therefore returns the least thin-film lifetime ( h) if falls within the aforementioned range required for
optimization with respect to intrinsic wettability (say, for example, ). At lower roughness (), the thin-film lifetime of the engineered surfaces can be
minimized by lowering θ (say, for example, 20 ). The thin-film lifetime in this limit approaches to that of
smooth surfaces having higher wettability ().
FIG. 9.
A case study of the virucidal properties across different surface wettability and
texture, shown schematically (not to scale). The values depicted for r, , θ, and
t are representative, extracted from the data shown in
Figs. 4–8, for the purpose of
demonstration of different regimes with respect to surface wettability and texture,
which lead to optimized virucidal effects.
A case study of the virucidal properties across different surface wettability and
texture, shown schematically (not to scale). The values depicted for r, , θ, and
t are representative, extracted from the data shown in
Figs. 4–8, for the purpose of
demonstration of different regimes with respect to surface wettability and texture,
which lead to optimized virucidal effects.It is important to mention here that although the Wenzel state is characterized by a higher
enhancement in the hydrophilicity, or a higher enhancement in
E, for a given surface roughness (given r), the
least thin-film lifetime is always returned for a θ falling in
the Wet–Cassie regime (cf. Figs. 5–9). This
is because, in the present analysis, both the effect of roughness and wettability have been
considered by virtue of Eq. (11). The
absolute value of the product is the deciding factor for the resultant evaporation dynamics
of a thin-film on an engineered surface. It can be seen from Figs. 6(c) and 6(d) (multimedia view) and
8(c) and 8(d)
(multimedia view) that is always the highest for θ
values within the Wet–Cassie regime for all roughness considered in the present study. This
is essentially because the Wet–Cassie regime inherently falls in the regions of higher
wettability, i.e., higher surfaces free energy of the underlying solid, which automatically
leads to a higher excess energy/disjoining pressure within the thin-liquid film.It is worth mentioning that a textured surface can also have hierarchical features, i.e.,
may contain additional tiers. As
demonstrated by Frankiewicz and Attinger, the total roughness factor r for a
surface with n tiers can be represented by , where r is the roughness factor
due to ith tier. Hence, for surfaces having multiple tiers,
r should be replaced as r in the above
analyses. It is quite straightforward to show that for the same
a/h and a/g ratios
across all tiers, adding tiers would further accelerate the thin-film evaporation.
Therefore, with the optimized conditions with respect to θ,
a/h, and a/g found in
the present model, adding tiers would further make the surface more and more antiviral.A few limitations of this study are discussed, which can be addressed in the future. First
of all, we have considered a surrogate droplet of pure water and the corresponding residual
thin-liquid film in the present analysis. Real respiratory droplets or saliva may contain
biological solutes whose drying has been explained by the Raoult's effect. Yet, the error for these approximations
considered in the present study is within .
The shear stress associated with the presence of the virus is also negligible.Finally, we discuss the relevance of the present findings in the context of molecular
surface effects. The developed model analyses the dynamics of the liquid thin-film on
engineered surfaces on the basis of the disjoining pressure within the film by accounting
the solid–liquid adhesive interaction [cf. Eqs. (4), (5), and (7)]. Adhesion has a molecular origin; the contact
angle is determined by the interplay between the cohesive and adhesive intermolecular
interaction between the liquid and solid in question. The adhesive energy determines the threshold static friction
that needs to be overcome to commence a motion of the triple phase contact line against a
solid surface. Moreover, recent
molecular dynamics studies on
liquid nanoflows confined within solid walls have disclosed that the flow pattern is
distorted by roughness, which generates a viscosity gradient and modifies the velocity
profile near the solid wall. The above-mentioned phenomena in the presence of varying
wettability and texture of the walls can be studied within the ambit of the present
formulation, which could be a future scope of research.
CONCLUSIONS
In closure, we have explored the combined effect of varying surface wettability and texture
on the virucidal properties of surfaces in the context of COVID-19. We propose design of
antiviral surfaces, which could help reducing the survival of coronavirus on impermeable
surfaces, thereby mitigating the spread of COVID-19 via fomite route. Previously, it was
reported that the lifetime of a residual thin-film after the diffusion limited evaporation
of a respiratory droplet is correlated with the coronavirus survival time. Therefore, we
analyze the said virucidal properties by modeling the evaporation mechanism of the thin-film
on textured surfaces with varied wettability and roughness. The generic model developed
herein could explain the earlier virus titer measurements on textured surfaces with
reasonable fidelity. Thereafter, model surfaces having parallel rectangular grooves and
rectangular pillars have been analyzed on the basis of the model. It has been found that the
thin-film evaporation rate is a function of the roughness factor and the intrinsic contact
angle, irrespective of the specific geometry considered. Also, the optimum range for the
intrinsic wettability and roughness, for which the fastest thin-film evaporation rate is
obtained to yield the most conducive virucidal effects, has been disseminated in the present
communication. The findings are useful for fabricating surfaces with virucidal properties of
surfaces, especially applicable to medical and pathological laboratory equipment, thereby
mitigating the spread of COVID-19 from these sources.
FIG. 1.
FIG. 2.
FIG. 3.
FIG. 4.
FIG. 5.
FIG. 6.
FIG. 8.
FIG. 7.
FIG. 9.