1. Introduction
Chromatography, the fractionation of (molecular) components according to their intrinsic properties, depends on the defined interaction of the components with a stationary phase material (SPM) while being transported in a carrier fluid through the pore space of that SPM. The efficiency and selectivity of fractionation is therefore the outcome of a complex multi-scale, multiphase process.
A main problem observed in the realization and operation of chromatography and packed bed processes in general is that the transport of carrier fluid and components, and heat and mass transfer depend on the structure of the packing, i.e., the spatial arrangement of the SPM in the apparatus and the properties of the generated pore space. The pore space is characterized by a complex pore network, determining, e.g., the porosity (radially, axially), the pore size distribution, the connectivity of pores, as well as the tortuosity of paths through the SPM. The extent of spatial distribution, e.g., in porosity, and property distributions, such as pore size, has a significant influence on the efficiency, capacity and selectivity of an SPM in a chromatographic separation task.
Synthesized (spherical) chromatographic beads, e.g., from spray-drying [
1], are typically assembled into packings by filling the material into the chromatographic column followed by a compaction process, e.g., application of an external pressure. It is well-known that in packed beds the porosity in radial direction increases towards the apparatus walls, creating a centre zone that is less porous than the outer zone. Classical works, e.g., by Martin [
2], have shown that even small high-porosity zones may have huge influences on flow distribution (residence time distribution of fluid, resp.), heat and mass transfer, and on the performance indicators. Well defined stationary phase packings are therefore a major handle towards efficient and selective separation in chromatography.
As a consequence, the design of a new functional SPM must be accompanied by the development of techniques for defined and optimized packing structures to minimize flow maldistribution and broadening of residence time distributions and maximize the selective interaction of the components with functionalised SPM.
In the broader context of fixed beds with defined packing structures and applications in catalysis and liquid chromatography, two main approaches are currently investigated: self-assembly of colloidal particles into (dense) structures, e.g., pillar arrays [
3], monoliths [
4], or vacuum-assisted layer-wise methods [
5,
6]. The practicality of these approaches are currently limited by either producing too dense packings or in challenges going from single- to multi-layer specimens.
The second main approach is the use of various additive manufacturing techniques. Periodic porous structures have been generated in metal-based processes, e.g., cellular structures with pore sizestypically larger than 100
m by selective electron beam melting [
7,
8,
9], achieving significant increases in heat and mass transfer in liquid chromatography. Using polymers as base materials with particulate additives, e.g., metals or ceramics, very defined structures at a (sub-)micrometer scale have been achieved [
10,
11,
12]. The techniques with the highest resolution are currently two photon photopolymerization techniques, with a spatial resolution of down to 30 nm [
13]. Variation of the size and shape of the particulates also allows production of homogeneous structures with low porosity, e.g., by temporary use of spacer particles or porogens [
14,
15].
The major challenge in the use of polymers is that compatible systems need to be found, i.e., photoinitiators, photoabsorbers, materials that cross-link well with the particles and tight reaction control are required. In terms of functionalisation, some of the particles are included in the polymer matrix, i.e., they are not accessible for interaction with the carrier fluid or other particulates, such as NP dispersed in the fluid.
The use of suspensions of functionalized colloidal particles to generate porous packings has not yet attracted comparable attention. The potential here lies in the wide variety of combinations of liquids and solids, as well as in the many different options for functionalisation of the colloidal particles. Moreover, the excessive loss of the functional surface due to incorporation of the active particulates into the volume of a support medium (e.g., polymer) is avoided. A third advantage over other techniques is that the spatial structure of the packing can be manipulated over a wide rage, e.g., by using polydisperse particles and the inclusion of spacer particles.
The key working principle is the solids deposit formation from the evaporating sessile droplet. The first investigations were presented in the seminal work by Deegan et al. [
16] on the coffee-ring effect that related the pattern formation to differences in the evaporation profile along the liquid–gas interface of the sessile droplet. For an in-depth study of the intra-droplet processes, we refer to the review by Larson [
17] and the additional experimental investigations and explanations in Sondej et al. [
18]. Therein, it is shown that the shape of the deposit can be manipulated by the gas-side drying conditions.
Via the modelling of drying of colloidal suspensions, either free or sessile droplets, e.g., in [
19,
20], further main influences on structure formation from single droplets were derived, for instance, regarding gas-side conditions or functionalisation of the colloidal particles. Recent works of Janocha and Tsotsas on structure formation during spray coating (i.e., towards layer formation) provide significant insights [
21,
22]: They showed by small scale experiments (individual droplets, at most three stacked on top of each other) the influence of material and drying conditions on the evaporation profiles. Using tomographic methods, they also provided insight into porosity and internal structure formation of the deposits.
In this work, we report on the development and characterisation of a new scalable technology for the continuous production of stationary phase materials from suspensions by spray printing. The porous substrate is generated by a layer-by-layer build-up from individual droplet placement and convective drying.
The work is structured as follows: In
Section 2, we present the new apparatus for the production of the porous substrates and characterisation of the main materials used in the studies and the porous structures. Then, a presentation of exemplary results follows, including a discussion of the major challenges of the manufacturing process and how to overcome them. The contribution closes with conclusions and an outlook on future work.
2. Materials and Methods
In this section, we introduce the spray printing setup. We also describe the fundamentals of sessile droplet drying as the main building block for build-up of large-scale porous structures. Furthermore, the materials (solid, liquid, gas) and experimental conditions are introduced as well as the main characterisation methods.
2.1. Spray Printing Setup
The main working principle of the spray printing setup is drop-on-demand casting. In the context of spray printing, only the required amount of droplets are placed at specified locations—either on a substrate or onto a pre-manufactured porous substrate. The structures are formed from solid-containing (i.e., nanoparticles) liquids; the liquid is evaporated by a heated gas flow, leading to the generation of a solid deposit from each droplet. Rational placement of droplets and control of drying conditions allow construction of porous layers of arbitrary shape and size. Repetition of this process yields a layer-by-layer build up of the porous substrate (
Figure 1).
The equipment used in this study is schematically presented in
Figure 2 (assembled from components manufactured by DataPhysics Instruments GmbH, Filderstadt, Germany): The main component is an opticalbench (OCA 200), typically used for contact angle measurements. The optical bench (platform, 10-by-10 cm
) can be positioned automatically relative to the position of the syringes in the x- and y-directions (left/right; front/back) as well as the z-direction (up/down). The spatial resolution and accuracy of movement are 500 nm (x- and y-direction) and 500
m (z-direction), respectively. Maximum speeds in the x-, y-, z-direction are 14 mm/s, 16 mm/s and 20 mm/s, respectively. The coarser resolution in the z-direction is due to the necessity to move the complete construction that requires additional mechanical stability to withstand larger external forces.
The optical bench carries a temperature chamber into which the initial substrate is placed on which the porous layers are formed. To this chamber, a gas flow with a defined temperature and initial moisture content is provided. Contact of the gas and the droplets and porous substrates leads to the evaporation of the liquid and deposit formation.
An additional main component is an array of three automated syringes that is positioned on top of the optical bench. Different syringes (dispensing volumes and droplet sizes) can be installed and operated simultaneously. For the purpose of this study, each syringe has a volume of 1 mL and a tip diameter of 0.8 mm. The initial x-, y- and z-position of the syringes was set to 70 mm, 100 mm, and 6 mm, respectively.
The droplet position pattern can be chosen either from a library of patterns or can be designed freely via the automation software of the dispensing system (SCA, DataPhysics Instruments GmbH, Germany).
An LED light source provides sufficient illuminations to generate shadow projections of the placed droplets and porous substrates. Realtime information on the process is obtained by high-speed imaging using a CCD camera coupled with a 7-fold zoom lens with controlled software, motorized focus (±4.5 mm) and adjustment of the observation angle (approx. 10 degrees). The image size of the camera is a maximal 1544-by-1088 pixels; the maximum sample rate is 78 images per second at this image size.
The whole setup is housed in a container to prevent changing environmental conditions influencing the structure formation. Furthermore, it is decoupled from environmental vibrations.
2.2. Nanosuspension Preparation and Characterisation
The preparation of the nanosuspension is described as well as the characterisation methods for suspension properties important for spray printing.
2.2.1. Suspension Preparation
A technical nanosilica suspension (Köstrosol 4550, CWK-BK GmbH, Bad Köstritz, Germany) with a concentration of wt-% and a primary particle size of 45 nm was used throughout the investigations. Suspensions with lower concentrations were generated by dilution with ultra pure water (Merck Millipore). To facilitate a uniform dispersion of the nanosilica, all solutions were stirred for 30 min by a magnetic stirrer prior to their use (either in spray printing setup or for suspension characterisation).
2.2.2. Suspension Rheology
For droplet generation, information on the rheological properties—especially at high solids loadings—is required. Previous studies on Drop-on-Demand Printing have shown that a dynamic viscosity of the suspension in the range of 1 to 50 mPa s is preferable for fast and reproducible droplet generation [
23].
Characterisation of the dynamic viscosity was performed in a rheometer (MCR 302, Anton Paar Gmbh, Ostfildern, Germany) using the coaxial cylinder geometry (DG26.7). The shear rate (at different concentrations) was varied in the range from 0.01 to 1000 s (at a constant temperature of 25 °C) to account for different stresses during the droplet generation, e.g., at the tip of the syringe. Furthermore, the viscosity dependence on the suspension temperature was studied in the range from 25 to 40 °C (at a fixed shear rate of 1000 s).
For the range of shear rates specified, an almost constant viscosity of 1.5 mPa s was measured. Changing the temperature from 25 to 40 °C yielded a reduction in viscosity, which can be fully attributed to the decrease in viscosity of the base liquid (water): mPa s at 25 °C to mPa s at 40 °C.
2.2.3. Contact Angle and Surface Tension
Information on the contact angle and surface tension are required to design, e.g., the surface coverage of individual droplets on the substrate, and yield information on the limitations in local spatial resolution.
Determination of the (static) contact angle and surface tension of the nanosuspension were performed using an OCA 200 (DataPhysics Instruments GmbH, Germany). The contact angle on the glass substrate was measured using the sessile drop method; and determination of the surface tension was measured using the pendant drop method. For both setups, image acquisition and evaluation are performed by the integrated software (SCA, DataPhysics Instruments GmbH, Germany) based on evaluation of the Young(-Laplace) equation. Static contact angles were determined for droplets with a volume of 1.5 L; the surface tension measurements used larger droplets (droplet volume of 25 L at a needle tip with diameter of 1.83 mm). The droplet volumes are adjusted for ease of evaluation by the software package.
For the suspension under consideration, a contact angle of 13.7° (cleaned but non-functionalised glass slide) and a surface tension of 86.7 mN/m were measured.
2.3. Characterisation of Porous Structure
Apart from the feasibility of the approach, packing porosity and pore size distribution of the structures are the key success indicators.
Non-destructive estimation of the average porosity of the generated porous structures was performed using the information of total mass
and volume
of the (intermediate) structure. Given this information and the skeletal mass density of silica,
the average porosity was obtained via
where
. The mass of the structure was obtained by weighing with a resolution of 0.1 mg (Sartorius AG, Göttingen, Germany, model 320G). The total volume of the structure was obtained from images (photographs or SEM images depending on structure dimensions).
Detailed textural characterisation of the porous structure was performed by advanced gas physisorption based on a combination of Ar 87 K and N 77 K adsorption. All samples were degassed at 150 °C under vacuum prior to each measurement. All physisorption experiments were performed with an Autosorb IQ (QuantaTec, Anton Paar). Ar 87 K isotherms were measured over the whole pressure range (with the relative pressure ranging from approximately up to 1). N 77 K isotherms were determined in a relative pressure range from up to 1. The pore network and connectivity were analysed by comparing the pore size distributions determined from the adsorption and desorption branches.
3. Results and Discussion
In this section, we present two examples to highlight the capabilities of the approach and discuss the general operational issues in spray printing and further steps to improve and enhance the properties of the generated porous structures.
In
Figure 3, a rectangular packing generated by spray printing is shown. The dimensions are: length = 46 mm (left to right); width = 23 mm and a height of 1 mm. The packing comprises 60 layers, i.e., each layer contributes on average a height of 16.6
m. With a total mass of 0.97 g and a total volume of 1.06 cm
, an average porosity of 0.59 is achieved. Due to its dimensions, we refer to it in the following as a "thin-layer" structure.
For further investigation of the pore space, the packing has been cut into 3 strips of equal width along its length. In the following, the subsamples are denoted by their original position, i.e., “left”, “middle”, and “right”.
Figure 4a shows the comparison of N
adsorption isotherms for the three subsamples. The perfect agreement of the N
77 K physisorption isotherms for all three subsample signals have similar textural properties, as shown in
Table 1. This highlights the capability of the approach to generate large-scale structures with consistent properties. Hence, we focus solely on the detailed textural characterization of the left subsample in
Figure 4b–d.
The Ar 87 K and N
77 K isotherms shown in
Figure 4b are of type IV(a) [
24], indicating that mesopores are present in the sample.
Figure 4c shows excellent agreement of the pore size distributions determined from Ar 87 K and N
77 K adsorption and from Ar 87 K and N
77 K desorption, respectively.
From the adsorption branch in
Figure 4d, it can be inferred that two major types of pores are formed: one type with pore sizes clustered around 10 nm, and the second type with larger pore sizes between 20 and 30 nm. The first type of pore is generated by the voids generated between contacting primary silica particles. The second type of pores with larger pore sizes are due to the structure formed during drying of the deposited droplet. Under the drying conditions used in the study, a torus-like solids pattern develops from the sessile droplet. The measured large pore diameters correspond to the central void (“hole”) of the torus. Overlapping of these voids by the solid material of later layers may partially restrict access to these pores. The extent of this and also opportunities to manipulate the occurrences and extent of larger pores, e.g., by droplet deposition pattern and drying conditions, is currently under investigation.
The detailed discussion of the measured pore size distribution is divided into two parts in the following: first, for pores smaller than 15 nm; and second, for pores larger than 15 nm. For pores smaller than 15 nm, we find a small shift of the pore size distribution determined from the adsorption branch to smaller pore sizes compared to the pore size distribution from the desorption branch. This observation can be attributed to initiated/advanced condensation, i.e., the effective nucleation barrier associated with the nucleation of the liquid phase is reduced in an interconnected pore network, resulting in a phase transition at a relative pressure smaller than the relative pressure associated with the spinodal of the fluid in these pores [
25,
26,
27]. The occurrence of the initiated condensation is known to occur in highly connected 3D pore networks [
25]. For these pores, the desorption branch reflects thermodynamic equilibrium and the pore size can be determined in a straightforward way from the desorption branch.
However, for pores larger than 15 nm, a shift of the pore size distribution determined from the desorption branch to smaller pore sizes can be observed, which is caused by pore blocking. Hence, some of the larger mesopores are restricted by smaller pore necks and these pores remain filled until the necks evaporate at a lower relative pressure during the desorption process. For these pores, the pore size distribution can be reliably determined from the adsorption branch of the N 77 K and Ar 87 K isotherms, respectively.
Table 1 summarizes the textural properties of the three subsamples. The pore volume determined via the Gurvich rule at a relative pressure
= 0.98 is essentially the same as the pore volume determined with NLDFT (see
Figure 4c). The specific surface area of the subsamples was evaluated using the BET method based on Ar 87 K adsorption, as the choice of N
as a probe molecule for surface area assessment can lead to an overestimation of the specific surface area of approx. 20% [
28].
Finally, we note that packings of this size may already be relevant for chromatographic applications, i.e., the presented technique is of practical use.
Moreover, pillar-like structures that resemble chromatographic packings can be generated directly by this approach.
Figure 5 presents a current outcome. The trapezoidal packing has the following dimensions: a quadratic base with a side-length of 11 mm and a height of 13 mm; it comprises 225 layers in total.
With a total mass of 2.65 g, the average porosity yields 0.24, i.e., it is significantly denser than the thin-layer structure. This may be due to additional pressure on each layer due to the mass of material placed on top of it. This densification may be overcome by adding inert spacer materials, e.g., [
14], where waxes were used that were washed out from the generated structure. Another aspect that requires improvement is the dimensional accuracy, especially towards the top of the structure. Effects observed at the bottom can be manipulated by changing the contact angle of the suspension with the substrate such that the droplets do not spread as widely. This and the smoothing effect at the edges can be suppressed by simultaneously manufacturing suitable support structures, e.g., by one of the other syringes. Here, new and exciting opportunities for packing and structure design are opened.
Apart from these observation, general operational challenges exist that are addressed in the following.
3.1. Operational Challenges and Counter-Measures
Here, we report common challenges in the spray printing of porous substrates that may lead to breakdown of operation, minor and major defects in the spray printed structures. We also discuss strategies by which those challenges can be overcome or their occurrence be minimised.
The main challenges are summarised in
Figure 6. Note that several of the issues may appear simultaneously, depending on the operation parameters. Failure of the production process is highly likely if at least one of the challenges is present.
3.1.1. Syringe Clogging
A major problem of the spray printing setup is clogging of the syringe due to drying of the suspension at the syringe tip. The needle of the syringe is exposed to the heated gas, which is transferred through the material to the suspension. Due to this heat transfer, liquid evaporates. Combined with the drying time of the layer of deposited droplets during which the syringe is not operating, enough liquid can evaporate from the needle such that a solid packing is formed in the needle, preventing further droplet dispensing. The smaller the needle diameter, the smaller the liquid volume and the faster clogging occurs. In order to continue spray printing, the needle needs to be cleaned manually, reducing the productivity of the setup.
This challenge can be solved in at least three ways: the use of needles with larger diameters (only possible, if the generated droplets are still in the acceptable range); thermal insulation of the needle (jacketing) to limit heat transfer from the gas to the needle; and designing dispensing paths such that resting times for drying are minimised and continuous dispensing of droplets is achieved.
3.1.2. Spacing Effect
The correct and uniform positioning of droplets onto the glass substrate or the top layer of deposits does not allow for arbitrary spacings
between the tip of the needle and the uppermost layer (or substrate). Different outcomes are exemplified in
Figure 7.
If is too small compared to the intended droplet size (left column), the droplet is deformed upon deposition, leading to a larger footprint than intended. Depending on the interaction with the substrate or the porous layer, this footprint is kept throughout the drying process (“pinning”) yielding an unfavourable spatial distribution of nanoparticles.
If is too large, the droplet is in free-fall upon dispensing. Depending on the dispensing velocity, the droplet will splash upon contact with the substrate (either material), generating satellite droplets of varying size (middle column). This also leads to an unfavourable distribution of the solids, reducing the achievable quality of the porous structure. If the dispensing velocity is too low, then the droplet may not detach from the needle tip (right column), i.e., no droplet is generated, leading to a (unintentional) non-uniform droplet pattern on the substrate.
From our trials, the optimum distance is such that the fully formed droplet is barely in contact with the previous layer or substrate. Upon release from the needle, it quickly relaxes into its equilibrium shape (spherical cap), dries and generates the intended solids deposition pattern. Given that the droplet volume is related to the droplet footprint, this distance can be calculated without problems, see, e.g., Rieck et al. [
29].
3.1.3. Delamination
Separation of porous layers (delamination) during spray printing is occasionally observed. The main reasons are a lack of adhesion between layers due to weak interaction of the nanoparticles. Initially, adhesion is stronger due to the presence of liquid bridges between nanoparticles of different layers; with drying, this effect weakens. Droplet interaction with the top layer may also cause delamination, if the retraction force of the syringe is transferred directly to the top layer and overcomes the interaction forces between the (partially) dried nanoparticles.
Figure 6 shows a typical scenario where delamination occurs after a few layers. Neglecting the occurrence and subsequent build-up of additional layers yields unstable structures. The adhesion of further layers is locally weaker, which may lead to cracking of the structure. Empirically, it was observed that delamination preferentially starts near the corners and edges of the structures. This is to be expected as at those locations only partial interaction of the nanoparticles with each other can be realised due to the interface with the surrounding gas phase.
Delamination can be minimised by either strengthening the interaction between individual nanoparticles (by suitable functionalisation), slow retraction of the syringe after droplet position, optimisation of the drying conditions to prevent thermal stress during organisation and adhesion of the nanoparticles, and the supply of encompassing support structures during preparation of the spray printed substrate.