Analysis of heat transfer and AuNPs-mediated photo-thermal inactivation of E. coli at varying laser powers using single-phase CFD modeling

Greek symbols

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αeffi,j,L

= effective polarizability of the i-particle;

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αi,j,L

= polarizability of the i-particle;

β

= volume expansion coefficient (K⁻¹);

ϵ

= emissivity (-);

θ

= incident angle, here: 0 rad;

μ

= viscosity (Pa·s);

μ_bac

= viscosity of bacteria (Pa·s);

μ_eff

= effective viscosity (Pa·s);

μ_w

= viscosity of water (Pa·s);

ξ

= AuNPs concentration in the considered volume (m⁻³) (here: ξ = 3.0 · 10²² m⁻³);

ρ

= density (kg·m⁻³);

σ

= Stefan–Boltzmann constant (W·m⁻²·K⁻⁴);

σ_abs

= absorption coefficient in room temperature (m⁻¹);

ϕ

= volume fraction of bacteria (-); and

ϕ_m

= maximum packing fraction of bacteria (-).

Subscripts

o

= at initial and standard conditions (24°C, 101 325 Pa);

f

= fluid;

i

= i-particle, in reference to size distribution;

m

= maximum;

w

= water;

abs

= absorption;

bac

= bacteria;

cell

= cell – in reference to bacteria;

eff

= effective;

ext

= external;

inac

= inactivated, in reference to bacteria; and

surv

= surviving, in reference to bacteria.

Abbreviation

Au

= gold;

AuNPs

= gold nanoparticles;

AuNRs

= gold nanorods;

CFD

= computational fluid dynamics;

NPs

= nanoparticles;

UDF

= user-defined function; and

UDS

= user-defined scalar.

2.1 Microchamber device: precision in bacterial inactivation

For bacterial inactivation, the microchamber device presented in this study combines the advantages of microfluidics and a targeted treatment strategy. It is constructed by combining a 1-mm-thick borosilicate glass plate (75 × 25 mm²) with a corresponding 1-cm-thick PolyDiMethylSiloxane (PDMS) layer [see: (Petronella et al., 2022) and (Sforza et al. (2024))]. AuNRs are placed at the base of the chamber, treated as a thin film 23 nm thick. By exploring two microchamber heights (10 μm and 100 μm), the physical model can be used to study the germicidal properties of the system.

Figure 2 outlines the chamber’s dimensions, highlighting its structural properties. The laser beam directed onto the device, as illustrated in Figure 2a, uses a targeted irradiation approach, focusing specifically on a 3 × 3 mm² surface of the AuNPs plate (Figure 2b).

We used data from the work of Petronella et al. (2022) to determine the concentration of gold nanoparticles. In the work of Petronella et al. (2022), the gold nanoparticles were not only analyzed in detail for their distribution and morphology, but were also used in a functional system to inactivate bacteria and to detect their presence even at low concentrations. Thus, based on the work of Petronella et al. (2022), we are able to conclude that nanoparticles, when used appropriately, show multifunctionality for both detection of bacteria and their subsequent inactivation. The experimental data allowed the determination of the concentration of ξ = 1.41·10²¹m⁻³. This parameter was then introduced into the mathematical model obtaining the same number of AuNRs. However, it should be mentioned that this assumption introduces a certain simplification, as in the mathematical model the distribution of nanoparticles is uniform. Furthermore, implemented model does not take into account the absorbance shift due to the presence of E. coli bacteria, as illustrated in a recent paper by Sforza et al. (2024). However indeed, the microchamber device is a hybrid solution that effectively integrates the advantages of microfluidics and targeted treatments. Carefully dimensioned, the device enables control and efficiency of bacterial inactivation.

However, it should be noted that microfluidic devices, often referred to as lab-on-a-chip systems, have reshaped experimental models, particularly in the field of biological and chemical analysis (Wang et al., 2015). These miniaturized platforms offer a wide range of advantages, including precise control of fluid dynamics, reduced sample volumes and accelerated reaction times (Hajmohammadi et al., 2018; Li et al., 2019; Feng et al., 2020). In the context of bacterial inactivation studies, these qualities become essential, as they help to improve heat transfer control and overall experiment efficiency (see Patinglag et al., 2021; Pudasaini et al., 2021; Wang et al., 2020). The reduced sample volume in microfluidic devices allows rapid temperature changes, which are essential for obtaining precise, controlled heat transfer conditions. The increased surface-to-volume ratio and confinement of microfluidic flow channels optimize heat exchange, ensuring targeted heat treatment with minimal energy dispersion. Operating under laminar flow conditions, these devices offer predictable and stable flow patterns, facilitating controlled heat transfer processes.

In addition, germicidal chambers represent a distinct category of disinfection systems designed to effectively inactivate microorganisms, including bacteria. These chambers exploit various technologies, such as ultraviolet (UV) irradiation or chemical agents, to achieve germicidal effects (Stephan, 2017; Xu et al., 2013). The controlled environment of germicidal chambers ensures constant exposure to disinfecting agents, maximizing their effectiveness (Won et al., 2023). Although these chambers excel at large-scale disinfection, they can encounter difficulties in reaching complex structures or delivering targeted treatments.

2.2 Thermal properties of used materials

In this work, the specific heat of PDMS used to build the microfluidic chamber is depended on the temperature variation (Narottam, 1986; Agari et al., 1997; Cahill et al., 1991; James, 1999). All thermal properties of the used materials are summarized in Table 1.

Additionally, the thermophysical properties of water and E. coli bacteria are presented in Table 2.

In the present research three density models were used to define the water density:

• The first is the constant density model (ρ = 998.2).

• The second model uses the Boussinesq equation, expressed as follows (Braginsky and Roberts, 2007; Barletta, 2022):

  (1) ρ(T)=ρ0(1−β(T−T0))

where:

ρ= density as a function of temperature T;

ρ₀ = reference density at a reference temperature T₀;

β = coefficient of thermal expansion; and

T = current temperature.

Therefore, using the Boussinesq equation, the density is considered constant except in buoyancy forces, where the density of water varies following the Boussinesq approximation:

• The third density model considers the density temperature-dependency (Wagner and Pruss, 2002), described as follows:

  (2) ρ(T)=999.9720+0.3230⋅T−0.0013·T2+0.00000175⋅T3

The specific thermo-physical properties of E. coli bacteria come from literature sources, as follows: density (Martinez-Salas, Martin, and Vicente, 1981), specific heat capacity (Lee and Kaletunc, 2002), thermal conductivity (Nakanishi et al., 2017), respectively.

3.1 Governing equations with the single-phase approach

The single-phase approach simplifies the modeling of the bacteria-water mixture by treating it as a homogeneous medium, which significantly reduces computational complexity and cost. This approach is justified because the focus is on the overall behavior of the system, rather than the detailed interaction between individual particles and the fluid. The use of the effective thermal properties allows the contribution of bacterial characteristics to be taken into account in the overall diffusion of heat inside the microdevice (Buongiorno, 2006; Feurhuber et al., 2019). The flow of the bacteria-water mixture inside the microfluidic device is characterized by a 3D, laminar regime in a transient state. The continuum equation for this system encompasses (Darrigol, 2002; Brenner, 2005):

ρ_eff = effective density, kg·m⁻³;

t = time, s; and

This equation ensures mass conservation, depicting the temporal change of effective density (ρ_eff) and divergence of the product of density and velocity. The effective density of the mixture (bacteria-water) depends on the volume fraction ϕ of bacteria, and it is obtained using different empirical correlations (in this case, the rule of mixtures to calculate effective density):

ϕ = volume fraction of bacteria;

ρ_w = density of water, kg·m⁻³; and

ρ_bac = density of bacteria, kg·m⁻³.

The momentum equation for viscous fluid (Reynolds, 1883), thence, is written as follows (Buongiorno, 2006; Feurhuber et al., 2019):

p = pressure, Pa;

μ_eff = effective viscosity, Pa·s;

⊗ = dyadic multiplication.

Describing momentum conservation, it accounts for the effects of pressure, viscosity and gravity on the flow. Moreover, the effective dynamic viscosity of the mixture was estimated using the Brinkman model (Brinkman, 1952):

μ_w – viscosity of water, Pa·s.

Likewise, the energy equation can be presented by Buongiorno (2006):

Cp_eff = effective specific heat capacity, J·kg⁻¹·K⁻¹;

T_f = temperature of fluid, K;

k_eff = effective thermal conductivity, W·m⁻¹·K⁻¹; and

In this work, the source term on the boundary by the UDF used the DEFINE_PROFILE macro has been applied. Consequently, the source term in the energy equation can be eliminated. It is well known that the energy conservation law states that the total energy of the system equals the sum of work and heat added to the system. However, since the water is working fluid and it can be considered as low-viscosity flows (viscous dissipations typically minimal), also due to time-efficient calculation and physical characteristics of the system in Figure 2, the viscous dissipation and pressure work terms in the energy equation for water flow were neglected. Therefore, the applied equation can be simplified to the form:

Cp_w = specific heat capacity of water, J·kg⁻¹·K⁻¹; and

Cp_bac = specific heat capacity of bacteria J·kg⁻¹·K⁻¹.

To predict the effective thermal conductivity of the water-bacteria mixture, the Lewis-and-Nielsen model (Pal, 2008) can be used as follows:

S = bacteria shape factor;

ϕ_m = maximum packing fraction, depending of alignment’s type;

k_bac = thermal conductivity of bacteria, W·m⁻¹·K⁻¹; and

k_w = thermal conductivity of water, W·m⁻¹·K⁻¹.

S and ϕ_m can be obtained by referring to the following Table 3 and Table 4.

5.1 Numerical simulation and mesh test

Numerical simulations were carried out using the commercial software Ansys Fluent (ANSYS Inc., 2021). For 3D flow within the microchamber, a transient flow regime coupled with a laminar flow condition was assumed. The transient regime was also adopted for conduction across the solid parts. The SIMPLE algorithm was used for velocity-pressure coupling in the Navier–Stokes equations. The Second-Order Upwind algorithm was used for the spatial discretization of pressure, velocity and energy terms. In addition, the transient formulation was carried out using the Bounded Second-Order Implicit algorithm. To ensure the independence of results from the time step size, four simulations were run with different time steps, using the same boundary conditions. The average temperature results at t = 190 s inside the microfluidic device for each time step size are shown in Table 6. The table shows that the time step Δt = 0.0008 presents a good compromise between result accuracy and computational costs. Therefore, a time step of Δt = 0.0008 was used for the rest of the simulations carried out in the present work.

A structured mesh grid was used in the simulation of the microdevice to enhance computational efficiency. Special attention was given to mesh treatment at the microchamber boundaries due to the substantial temperature gradient in these regions (refer to Figure 3). The bias technique was applied, and the bias factor was computed to ensure that the size of the first element near the microchamber wall was equaled the dimensions of the elements in the microfluidic device. To assess the sensitivity of numerical results concerning velocity within the chamber to the node number, various grid systems were tested. Figure 4 illustrates the results in terms of the maximum fluid velocity at different simulation times for different mesh grids. Notably, the maximum velocity of the bacteria-water mixture exhibited insensitivity to the mesh grid size beyond the M4 grid. This insensitivity indicates that the simulation results have reached a level of mesh independence, meaning that further refinement of the mesh does not lead to significant changes in the results. Consequently, the M4 mesh grid was used for the subsequent numerical simulations. This choice of the M4 grid strikes a balance between computational efficiency and accuracy. By selecting a mesh that is fine enough to capture all relevant flow details but not so fine as to unnecessarily increase computational cost, we ensure that the simulations are both reliable and efficient.

5.2 User-defined function implementation

To take into account, the thermophysical properties of E. coli bacteria in the microchamber, UDFs have been developed using the equations defined in equations (4), (6) and (10) with the DEFINE_PROPERTY macro, and another UDF with the DFINE_SPECIFIC_HEAT macro to define the heat capacity of the bacteria-water mixture [equation (9)]. It should be noted that these UDFs also take into account temperature dependency.

In addition, a UDF with the DEFINE_PROFILE macro has been developed to integrate the boundary condition defined in equation (19), using the heat generation formula [equation (18)]. This UDF calculates the heat generation rate of the AuNRs deposited on the bottom surface of the microchamber, using the assigned input data. The result will be used as heat generation at individual mesh elements. The UDF also contains a conditional loop to select the mesh cells responsible for heat generation, given that the irradiated surface is 3 × 3 mm².

5.3 Bacteria inactivation model

The volume of cells exceeding 55°C was tracked to calculate inactivated bacteria in the microfluidic chamber using the equation:

V_cell = volume of cells reaching or exceeding 55°C; and

V_bac = volume of a single E. coli bacterium.

Meanwhile, the number of surviving bacteria, N_surv, is given by:

N₀ = initial number of bacteria; and

N_inac = number of inactivated bacteria.

An initial bacterial concentration, n₀, is given by:

5.4 Validation of the computational fluid dynamics model

In this work, the validation was carried out by comparing the results of the numerical simulations with those obtained experimentally. The experimental procedure carried out in the nanorods experiment consists of applying a layer of AuNRs to the lower surface of the microchamber, as described in Figure 2. The nanoparticle layer is then irradiated by a laser of power P = 0.8W with a wavelength of 808 nm (see Table 6), for 190 s. A thermal camera was used to record the maximum temperature at the bottom surface of the borosilicate glass and the corresponding temperature fields. The results obtained from the CFD were compared with those obtained using a thermal camera, as shown in Figure 5. The thermal fields obtained numerically agree very well with those obtained experimentally. In a further comparison, the evolution of maximum temperature during the irradiation process (see Figure 6), shows good agreement between the two time-dependent temperature curves. Both of these comparisons demonstrate the accuracy of the numerical simulations carried out in this work, and enhance the validity of the proposed CFD model.

6.1 Heat transfer mode and density model sensitivity

Within the microfluidic chamber under laser irradiation, this study of heat transfer dynamics shows clear predominance of conduction as the main mechanism. This observation is supported by the isothermal structure depicted in Figure 7 where, after 190 s of irradiation, the isotherms show a tight, parallel configuration. Such a pattern shows the absence of a convective regime, indicating that conduction is the dominant mode of heat diffusion in the confined microchamber. The physical explanation for this phenomenon lies in the constraints imposed by the chamber’s dimensions. With a small height and confined space, the development of natural convection currents is limited or non-existent. Consequently, diffusion conduction appears to be the dominant process. The role of AuNRs is significant in this system, since it considered as the source of heating. Moreover, the laser irradiation at the base of the microchamber, where the AuNPs are deposited, leads to the conversion of electromagnetic energy into thermal energy. This photothermal conversion is highly efficient due to the absorption properties of the AuNRs. The CFD simulations incorporate this by modeling the localized heat generation within the microchamber as a result of the AuNPs’ presence. The discrete particle integration method used in the simulations accounts for the energy contribution of each nanoparticle, allowing for a detailed analysis of the heat distribution. Despite the high localization of heat around the AuNRs, the overall heat transfer within the chamber remains dominated by conduction, as shown by the consistent isothermal profiles. The simulations indicate that, while the AuNPs significantly enhance the localized heating effect, leading to the inactivation of E. coli, this does not alter the macroscopic mode of heat transfer, which is conduction. The analysis of different density models constant density, the Boussinesq approximation and temperature-dependent density further supports this conclusion, showing minimal impact on the mean temperature profiles regardless of the model used. The effectiveness of the AuNRs in achieving photothermal inactivation is thus integrated into the thermal dynamics without shifting the dominant heat transfer mechanism from conduction to convection.

To validate the previous result (heat conduction is the predominant mode), three density models for the bacteria-water mixture were examined, namely, the constant density model, the Boussinesq approximation [equation (1)] and the temperature-dependent density model [equation (2)]. The results in Figure 8 show the mean temperature profile of the bacteria-water mixture vs irradiation time. These results demonstrate that even if we change the density model in the CFD simulations, the mean temperature values remain almost unchanged. Clearly, the choice of density model has a minimal impact on the evolution of mean temperature.

By way of explanation, the constant density model assumes uniform density throughout the mixture without any variation, while the Boussinesq approximation takes into account buoyancy effects due to density variations caused by temperature difference. Even with the temperature-dependent density model, which takes into account the possibility of adapting to varying thermal conditions, the overall temperature behavior remains largely insensitive to these variations. Together, these results emphasize the high dominance of conduction in heat transfer within the microchamber. The confined nature of the experimental device, combined with its specific geometry, underlines the importance of conduction over convection mechanisms.

6.2 Initial bacterial concentration and design effect

In this subsection, temperature variations inside the microfluidic chamber under laser irradiation were explored, examining different initial bacterial concentrations (N_o) – see Table 7. Figure 9 shows the time evolution of the maximum temperatures, this can describe the interactions between heat generation, dissipation mechanisms and effects of chamber design. At the beginning of laser irradiation, the heat generation rate exceeds the dissipation, resulting in a rapid increase in temperature. Over time, the mechanisms of dissipation catch up, moving from an initial rapid increase to a more gradual rate. In particular, the chamber height influences the reached temperature, with h = 10 μm exhibiting higher temperatures than with h = 100 μm. Furthermore, it was found that the rate of bacterial presence (volume fraction ϕ) has no significant impact on thermal dynamics within the system. This observation can be attributed to the thermal properties of bacteria, which closely match those of water. However, a subtle effect was noted in the chamber with h = 100 μm, suggesting a limited influence on dissipation dynamics.

6.3 Temperature response to laser power level

In Figures 10–13, the temporal evolution of maximum and mean temperatures in the microscopic chamber reveals a consistent trend as the laser power increases, regardless of the chamber height (h = 10 μm [see: Figures 10 and Figure 12] or h = 100 μm [see: Figure 11 and 13]). The rise in temperature is expected as a consequence of laser irradiation on AuNPs within the microfluidic chamber. Where localized nanoscale heating contributes significantly to the overall temperature increase inside the chamber. The maximum temperature reflects the peak thermal effect reached during the process, whereas the mean temperature provides an average measure. This is consistent with previous experimental Zaccagnini et al. (2023) particularly in the low power range of lasers, where electron saturation has not yet occurred. The observed increase in both maximum and mean temperatures as the laser power rises signifies enhanced thermal inactivation of bacteria, underscoring the pivotal role of AuNRs in facilitating effective photothermal inactivation. This enhancement is particularly pronounced at higher laser powers, where the thermal effects generated by the AuNRs are more substantial, leading to efficient bacterial inactivation.

Figure 14 explores the relationship between laser power and maximum temperature after 190 s of irradiation. Notably, the linear variation suggests a proportional response within the studied power range (0.2 W to 1.0 W), corresponding to power densities of 2.22 Wcm⁻² to 11.11 Wcm⁻². This aligns with experimental findings reported in Zaccagnini et al. (2023), indicating a two-stage behavior in temperature progression. The initial linear phase, consistent with presented results, transitions into a slower increase beyond 12 Wcm⁻².

6.4 Dynamic of bacterial inactivation under varying laser power

Since the trends in terms of bacterial inactivation were the same for the 100 μm and 10 μm height microchambers, we chose to present the results for the h = 100 μm height microchamber for more simplicity. Figure 15 shows the changes in the inactivated and surviving bacteria population during laser irradiation. The curves represent the temporal evolution of the above-mentioned variables using different laser powers, thereby providing additional scope for the thermal analysis discussed above. In addition, the spatial distribution of active/inactive bacteria obtained from the calculated total volume gives interesting information on the inactivation rate of bacteria caused by laser irradiation this was presented in Figure 16. It should be recalled that the assumption taken about the condition for which the bacterium will be inactivated states that the bacteria cell will be inactive after exposure to a temperature of T ≥ 55°C for a period of 60 s. Thus, the results presented here represent the beginning of inactivation. The information provided in Figures 15 and 16 shows that at laser powers of 0.8 W and 1.0 W, there is a notable rapid temperature increase in the mesh elements, reaching temperatures of 55°C or higher. Specifically, at a power of 1.0 W, the temperature threshold of 55°C is reached approximately at the 10 s mark, whereas at 0.8 W, this temperature is reached around the 24 s mark. Clearly, as the temperature of the microchamber mesh element reaches or exceeds 55°C, this impacts the bacteria viability. Where, the increase in bacteria inactivation and the decrease in surviving bacteria, as depicted in Figure 15, illustrate the effect of thermal processes induced by laser irradiation on the bacteria inactivation mechanism. This finding confirms the relationship between the thermal impact generated by laser exposure and the process of bacterial inactivation. However, for laser powers ranging from 0.2 W to 0.6 W, the number of inactivated bacteria (Figure 15) as well bacteria inactivation rate (Figure 16) remains null over time, indicating that the entire microfluidic chamber does not reach temperatures above 55°C (see Figure 14). This corresponds to the general trend observed in the temperature analysis, and highlighting the importance of laser power in controlling thermal effects and bacterial inactivation.