The promise of enabling time and space resolved chemistries has seen the emergence of droplet microfluidics for lab-on-chip technologies. Generally, prior art approaches to transporting droplets have been directed to creating global surface energy gradients by exploiting electrowetting/electrocapillarity, thermo-capillarity, chemistry, or texture. Prior art static global gradients, however, are limited in usefulness because they can only drive droplets over short distances and can never form a closed loop.
Despite recent advances in microfluidic manipulation of droplets, there remains the need for a simple method and apparatus for transporting droplets over a substrate. In particular, there is a need for an apparatus that can transport droplets along complex paths, including, for example, closed loops.
A novel approach is disclosed herein to transport droplets, wherein an engineered surface having periodic structures with local asymmetry rectifies local “shaking” into a net transport of droplets on the surface. This approach retains the simplicity and ease of operation of passive gradients while overcoming their limitations by making it possible to create arbitrarily long and complex droplet guide-tracks that can also form closed loops.
In one aspect, a method for moving a droplet along a predetermined path on a surface is provided. The method includes: providing a horizontal surface having an elongated track comprising a plurality of transverse arcuate projections that are sized and spaced to support a droplet in a Fakir state, wherein the droplet has a front portion; depositing the droplet on the elongated track; and vibrating the surface at a frequency and amplitude sufficient to cause the droplet to deform such that the front portion of the supported droplet contacts at least one additional transverse arcuate projection, thereby urging the droplet towards the additional transverse arcuate projection.
In another aspect, a device is provided for moving a droplet along a predetermined path on a surface, comprising: a surface having an elongated track comprising a plurality of transverse arcuate projections that are sized and spaced to support a droplet in a Fakir state, wherein the droplet has a front portion; and a means for vibrating the surface at a frequency and amplitude sufficient to cause the droplet to deform such that the front portion of the supported droplet contacts at least one additional transverse arcuate projection, thereby urging the droplet towards the additional transverse arcuate projection.
In one aspect, a method of moving a droplet along a predetermined path on a surface is provided. In one embodiment, the method includes:
providing a surface having an elongated track comprising a plurality of transverse arcuate regions having a different degree of hydrophobicity than the surface, wherein the transverse arcuate regions are sized and spaced to induce asymmetric contact angle hysteresis when the droplet is vibrated;
depositing the droplet on the elongated track; and
vibrating the surface at a frequency and amplitude sufficient to cause the droplet to deform such that a front portion of the supported droplet contacts an at least one additional transverse arcuate region, thereby urging the droplet towards the at least one additional transverse arcuate region.
In another aspect, a device for moving a droplet along a predetermined path on a surface is provided. In one embodiment, the device includes:
a surface having an elongated track comprising a plurality of transverse arcuate regions having a different degree of hydrophobicity than the surface, wherein the transverse arcuate regions are sized and spaced to induce asymmetric contact angle hysteresis when the droplet is vibrated; and
a means for vibrating the surface at a frequency and amplitude sufficient to cause the droplet to deform such that the front portion of the droplet contacts at least one additional transverse arcuate region, thereby urging the droplet towards the at least one additional transverse arcuate region.
The foregoing aspects and many of the attendant advantages of this invention will become more readily appreciated as the same become better understood by reference to the following detailed description, when taken in conjunction with the accompanying drawings, wherein:
The invention provides methods and devices for transporting droplets on a surface. The aspects provided include droplet transport schemes utilizing both textured “mesas” and flat “wetting barrier” surfaces.
Textured Surfaces
A method is disclosed for transporting droplets on a surface textured with a plurality of nested transverse arcuate projections (interchangeably referred to herein as “mesas”) where the motion results from vibrating a droplet having a front portion contacting a larger area of mesa surface than the back portion of the droplet, such that the imbalance of the contacted areas propels the droplet in the direction of greater contacted surface area due to surface energy minimization. The arcuate mesas form “tracks” for the moving droplet. The energetically favored movement of the droplet is in the direction of the concave portion of the arcuate mesas. Thus, as the droplets are vibrated, they “ratchet” along the arcuate mesas tracks. The tracks can be arbitrary in length and form complex shapes, including loops. While arcuate mesas are provided, it is contemplated that other mesa shapes (e.g., v-shapes) may alternatively be useful.
In one aspect, a method for moving a droplet along a predetermined path on a surface is provided. The method includes: providing a surface having an elongated track comprising a plurality of transverse arcuate projections that are sized and spaced to support a droplet in a Fakir state, wherein the droplet has a front portion; depositing the droplet on the elongated track; and vibrating the surface at a frequency and amplitude sufficient to cause the droplet to deform such that the front portion of the supported droplet contacts and adheres to at least one additional transverse arcuate projection, thereby urging the droplet towards the additional transverse arcuate projection.
In another aspect, a device is provided for moving a droplet along a predetermined path on a surface, comprising: a surface having an elongated track comprising a plurality of transverse arcuate projections that are sized and spaced to support a droplet in a Fakir state, wherein the droplet has a front portion; and a means for vibrating the surface at a frequency and amplitude sufficient to cause the droplet to deform such that the front portion of the supported droplet contacts and adheres to at least one additional transverse arcuate projection, thereby urging the droplet towards the additional transverse arcuate projection.
If the surface 20 is vibrated, inertial forces will cause the droplet 100 to deform. For example, during an upward portion of a vibration the droplet 100 will tend to spread out as the surface 20 pushes the bottom of the droplet 100 upwardly. Droplet deformation is illustrated in
Because the arcuate shape of the mesa 10 curves in the same direction as the droplet front portion 102 (and opposite the curvature of the droplet back portion 104), the droplet front portion 102 contacts a larger surface area of mesa 10′ than the back portion 104 contacts of mesa 10″. Therefore, from surface energy and/or surface tension considerations, the droplet 100 will preferentially pin or adhere to mesa 10′ at the front portion 102. Then, as the surface 20 vibration moves downwardly, inertial forces tend to cause the droplet 100 to elongate vertically, and the droplet 100 will move in the direction of the front portion 102. In one embodiment, the arcuate mesas define substantially circular arcs, the arcs having substantially similar radii to that of the droplet. If the radii of the arcuate mesas and the droplet are substantially similar, the amount of mesa-top surface area potentially contacted by the front portion of the droplet is maximized.
The droplet 100 moved by the above process is illustrated in
The movement of a droplet in the devices can be explained in terms of locally minimizing surface energy. The droplet front portion 102 tends to contact greater mesa surface area than the droplet back portion 104 because the front portion 102 curves in the same direction as the mesas 10. More surface area contacted results in minimized surface energy. As the surface 20 vibrates, the droplet 100 is deformed and the front portion 102 contacts greater surface area than the back portion 104 for a symmetrical deformation. The droplet 100 will therefore be urged to move towards the front portion 102. The vibration frequency and amplitude must be sufficient to cause the droplet 100 to extend across one or more of the gaps between arcuate mesas 10. So long as the front portion of the droplet continues to contact more surface area than other sides of the droplet, the front portion will be preferentially pinned to the new position and the droplet 100 will tend to move toward the front portion 102.
Referring now to
In
Referring now to
Tracks useful in representative devices are not limited to linear shapes, but also include any shape that can be patterned on a surface, including looped tracks and tracks that Cross.
A device need not be strictly horizontal to function, and a droplet can be transported up (or down) an incline so long as the spacing and density of the mesas and the vibration intensity are such that it is energetically favorable for a droplet to move along the incline and remain pinned at increasingly higher locations due to energy minimization. In embodiments wherein a droplet is moved along an incline, gravitational forces must be considered. For example, when driving a droplet up an incline, the pinning force at the front portion of the droplet will be resisted by gravity.
Devices can be useful, for example, in facilitating space and time-resolved chemistries, and for the handling of chemical and biological samples that are available in low quantities or low concentration.
Theory
Although not intending to be limited by the following, the inventor's current understanding of the physical mechanism included is discussed below.
As described above, representative devices operate when a droplet is in the Fakir state on a surface. The Fakir state of a droplet on a textured surface is illustrated in
cos θF=φ(cos θi+1)−1 (1)
where θi is the intrinsic contact angle of the droplet on a non-textured mesa material and φ is a surface texture parameter defined by Equation (2), wherein a, r, and R are illustrated in
Generally, φ is the ratio of total mesa-top surface area to total projected surface area.
Because φ is defined both by the post dimension and the spacing between posts, if the posts all have a constant surface size (e.g., cylindrical posts having uniform diameter), then the resulting φ value will increase the closer the posts are spaced from one another. An increase in φ corresponds to a decrease in surface energy and contact angle when referring to a system where a droplet is contacting the mesa tops.
A second texture parameter z can be expressed as the ratio of the total mesa surface area (including height, length, and width) to the total surface area over which the pillar and surrounding surface cover. The texture parameters φ and z can be distinguished in that z takes into account the three-dimensional surface area of the mesas while φ only concerns the mesa-top surface area.
The texture parameters φ and z are used to design textured surfaces that support droplets in the Fakir state, which is stable only if the inequality expressed in Equation (3) holds true:
Thus, if a particular droplet (liquid) and surface result in a fixed intrinsic contact angle (θi), the design of the mesas of the substrate that influence z and φ allow the structure to be tailored to either support the Fakir state or the Wenzel state (full wetting of the surface).
The intrinsic contact angle θi is related to the apparent contact angle θF of a Fakir droplet on a textured surface according to Equation (1). The contact angle θF for representative droplets on textured surfaces include droplets having a contact angle θF of 90° to 180°.
The contact angle θF varies with the energy of the surface area contacted by the droplet and thus is influenced by the texture parameter φ. As φ increases and the area contacted by the droplet increases, the contact angle decreases as a result of the reduction of the surface energy. The opposite also holds true: as φ decreases and the area contacted by the droplet decreases the surface energy increases and the contact angle formed between the droplet and the mesas increases. In representative devices, the front portion of the droplet has a smaller contact angle than the back portion because it contacts more surface area, and thus has a lower surface energy.
A Fakir droplet on a surface does not spontaneously transition to the Wenzel state because of the presence of an energy barrier. The contact angle θF depends only on φ and θi and is independent of the coating on the sidewall. However, the energy barrier between the Fakir and Wenzel states depends on the coatings of the sidewall and is independent of the θi of the mesa tops (according to Equation (3)). Thus, the size and surface chemistry of both the mesa tops and sidewalls are important for devices of the invention.
As described above, during device operation the droplet moves as the result of pinning Pinning refers to the force between a portion of the droplet and the surface it touches. An advancing droplet is a droplet that is flattened such that it is reduced in height and increased in radius (in the plane of the substrate; assuming a symmetric vibrational mode shape), and a receding droplet is the opposite: the droplet is increased in height and reduced in surface area radius. Thus, a vibrating droplet will first advance, such that the droplet is compressed and spread out, and then will recede.
There is an asymmetry in the behavior of different portions of advancing and receding droplets, which drives the movement of droplets in representative devices. The degree of pinning of a portion of a droplet is based on the texture parameter φ, with a low φ resulting in: a high contact angle θF, a low degree of pinning in the advancing direction, and a low degree of pinning in the receding direction. A high φ (i.e., larger surface area) results in: a lower contact angle θF, low pinning when advancing, and high pinning in the receding direction. This asymmetry in receding pinning forces results in movement towards an area of high φ if there is an asymmetry in the φ parameter between front and back portions of the droplet when vibrating. Because an area of high φ has a high degree of receding pinning, the pinned portion will remain in the high φ (low surface energy) area while the low φ area will not pin the opposite portion of the droplet, and thus the droplet is allowed to move towards a higher φ area.
Representative arcuate mesa structures are surrounded by a low-φ region that serves to repel the droplets, thus tending to retain the droplets on the arcuate mesa tracks. The φ of this region is significantly smaller than that of the track, so as to contain the droplets, but the pillars are not so sparse that the droplets sag down between them. In an exemplary embodiment, the φ of this region is less than or equal to 0.04.
Vibration
Devices operate through the vibration of droplets on a textured surface. The means for supplying the vibration is not specifically important and any techniques for generating vibration known to those of skill in the art are useful. In a representative embodiment, the vibration of the droplet is vertical (perpendicular to the substrate) and acoustically induced by a speaker driven by an amplifier. Alternatively, modal exciters (such as the Bruel & Kjaer 4808) and piezo actuators are exemplary means for providing vibration. Non-perpendicular vibration can be useful, for example, to produce asymmetric vibrations that may act (sometimes in conjunction with surface features) to produce droplet switches, for example, where tracks intersect and a droplet is directed along a selected path by the angle (relative to the substrate) of the vibration.
The frequency and intensity of vibration needed to move a droplet depends on the size of the droplet and the energy considerations related to the textured surface. In a representative, non-limiting, embodiment, a micron-sized droplet can be transported across a textured surface with a vibration frequency of from about 1 to about 100 Hz.
Devices
An exemplary system 600 in accordance with the present invention is illustrated in
Additionally, as will be appreciated by those of skill in the art, the motion of a droplet can be measured using, for example, a laser vibrometer or a built-in accelerometer.
The devices are useful as a tool for transporting droplets to and from locations on a substrate where the droplets can be analyzed or manipulated by techniques known to those of skill in the art. Representative analytical techniques include passive analyses, such as microscopy, and destructive analyses, such as GC/MS.
An exemplary device 660 incorporating a loop-shaped track 114 of arcuate mesas 10 is sketched in
Textured Surface Fabrication
Textured surfaces can be fabricated using techniques known to those of skill in the art. Surfaces can be made from a range of materials (e.g., semiconductors or polymers), with the only limitation on available materials being the ability of the material to form a surface that will support a droplet in the Fakir state. Traditional semiconductor microfabrication techniques, including photolithography, thin film deposition, and etching techniques, can be used to fabricate devices of the invention, as can other techniques (e.g., molding, soft lithography, and nanoimprint lithography). Any fabrication technique is useful if it can produce the appropriate mesa structures (having the appropriate surface chemistry) for creating the Fakir state of a droplet.
Referring now to
In this exemplary process, two different etching stages are performed to define the mesa height, with the resulting structure illustrated in
As described previously, the Fakir state is primarily a result of the hydrophobicity of the sidewalls of the mesas, although the tops of the mesas also contribute to the overall hydrophobic effects of the substrate. In one embodiment, the tops of the mesas are hydrophilic and the sidewalls of the mesas are hydrophobic.
Exemplary Device Results
An exemplary device includes round post-shaped mesas having diameters of 20 microns, the posts being shaped into arcs nested with other arcs. An exemplary structure illustrating this design is pictured in the micrograph of
Graphical analyses of devices of the invention are shown in
Referring now to
In the exemplary device graphically analyzed in
Flat Surfaces
As discussed above, textured devices (“texture ratchets”) can be used to move a droplet suspended on the textured pattern in the Fakir state. As a result of the semi-circular rung design, there is near-continuous pinning for the side of the drop aligned with the rung curvature but only intermittent pinning for the anti-aligned side. The asymmetry in pinning results in unbalanced contact angle hysteresis. That is, when vibrated, the aligned side exhibits a greater range of contact angles over time per vibration cycle than the anti-aligned side for the same time and cycle and thus, the hysteresis of the aligned side is greater than the hysteresis of the anti-aligned side. When sufficiently agitated by vertical vibration, the contact line of the drop will de-pin to cyclically advance and recede. Asymmetry in contact angle hysteresis rectifies footprint oscillations into controlled horizontal transport, specifically, in the direction of the rung curvature, or, greater contact angle hysteresis.
Texture ratchets capitalize on strong pinning at geometric barriers, but they are inherently limited by the nature of rough surfaces. At extreme vibrations the drop can collapse from the Fakir state into the microstructure and become immobilized in the Wenzel state. In addition, aspect-ratio fabrication constraints limit the minimal ratchet period length achievable on a microstructured surface. Fully transparent texture ratchets are impossible to realize. The fabrication protocols required for a rough surface limit the concurrent fabrication and integration of electrodes and sensors.
Transparent ratchet devices on a flat surface can be designed using principles similar to the texture ratchets.
In one aspect, a method of moving a droplet along a predetermined path on a surface is provided. In one embodiment, the method includes:
providing a surface having an elongated track comprising a plurality of transverse arcuate regions having a different degree of hydrophobicity than the surface, wherein the transverse arcuate regions are sized and spaced to induce asymmetric contact angle hysteresis when the droplet is vibrated;
depositing the droplet on the elongated track; and
vibrating the surface at a frequency and amplitude sufficient to cause the droplet to deform such that a front portion of the supported droplet contacts an at least one additional transverse arcuate region, thereby urging the droplet towards the at least one additional transverse arcuate region.
In another aspect, a device for moving a droplet along a predetermined path on a surface is provided. In one embodiment, the device includes:
a surface having an elongated track comprising a plurality of transverse arcuate regions having a different degree of hydrophobicity than the surface, wherein the transverse arcuate regions are sized and spaced to induce asymmetric contact angle hysteresis when the droplet is vibrated; and
a means for vibrating the surface at a frequency and amplitude sufficient to cause the droplet to deform such that the front portion of the droplet contacts at least one additional transverse arcuate region, thereby urging the droplet towards the at least one additional transverse arcuate region.
In the flat surface embodiments, the flat devices operate using vibration and edge pinning of the droplet on an elongated track formed from a plurality of arcuate features. For the textured devices, the elongated track is formed from a plurality of arcuate projections (“mesas”) that extend from the surface of the substrate, as described above. Conversely, flat devices do not have arcuate projections, but instead have a surface patterned with an elongated track formed from a plurality of transverse arcuate regions having a different degree of hydrophobicity than the surface. This hydrophobic-hydrophilic patterning is referred to herein as a “wetting barrier” ratchet track. The track supports a droplet along an alternating pattern defined by regions having a different degree of hydrophobicity. As used herein, the term “different degree of hydrophobicity” is used to describe surfaces that have a different affinity for water, which is used as the benchmark droplet liquid. The substrate and the arcuate regions may both be hydrophobic, they may both be hydrophilic, or one may be hydrophobic and the other may be hydrophilic. In one embodiment, the plurality of transverse arcuate regions are more hydrophobic than the surface. In one embodiment, the plurality of transverse arcuate regions are more hydrophilic than the surface.
Modification of surfaces to form hydrophobic or hydrophilic functionalities is well known to those of skill in the art. Chemical modifications (e.g., using self-assembled monolayers) or thin-film depositions (e.g., chemical vapor deposition) are exemplary methods. Any means can be used to form the transverse arcuate projections as long as the method used can form the necessary patterned regions in the shape of the elongated track with sufficient precision so as to allow the track to support a droplet and allow for movement of the droplet along the track when sufficiently vibrated.
The droplet is a liquid supported by the elongated track according to the description herein. The droplet may be hydrophobic (e.g., an organic solvent) or hydrophilic (e.g., water).
The droplet has a degree of hydrophobicity such that it is supported as a droplet on the substrate and the arcuate regions and there is an asymmetry in how each side of the droplet experiences the substrate/arcuate region interface, thus inducing asymmetric contact angle hysteresis during vibration.
In one embodiment, the droplet has a degree of hydrophobicity closer to the degree of hydrophobicity of the transverse arcuate regions than that of the surface. The hydrophobicity of the droplet, arcuate regions, and the surface are all defined such that the droplet has a degree of hydrophobicity closer to the degree of hydrophobicity of the transverse arcuate regions than that of the surface. Because the droplet has affinity for the arcuate regions, the edge-pinning effect occurs, which allows for transport of the droplet across the track when vibrated.
In other embodiments, the degree of hydrophobicity of the droplet is closer to the degree of hydrophobicity of the surface than that of the transverse arcuate regions. In such embodiments, the affinity of the droplets to the substrate and the arcuate regions still supports the droplet and creates an asymmetry in how each side of the droplet experiences the substrate/arcuate region interface, thus inducing asymmetric contact angle hysteresis during vibration.
As with the texture ratchets, the transverse arcuate regions are sized and spaced to induce asymmetric contact angle hysteresis when the droplet is vibrated. The step of vibrating the surface at a frequency and amplitude sufficient to cause the droplet to deform such that a front portion of the supported droplet contacts an at least one additional transverse arcuate region, thereby urging the droplet towards the at least one additional transverse arcuate region operates in a similar manner as disclosed above with regard to texture ratchets, although a theoretical description is also provided below.
A comparison of how water pins to a sharp edge and to a wetting barrier is shown in
In one embodiment, the plurality of transverse arcuate regions and the surface are optically flat. “Optically flat” means that any step between the surface of the substrate and the arcuate regions is invisible to the eye (i.e., is significantly less than the wavelength of light (in the tens of nanometers, approximately).
In one embodiment, the plurality of transverse arcuate regions and the surface are coplanar. “Coplanar” means that there is no step at all.
In one embodiment, the plurality of transverse arcuate regions and the surface are formed from the same substrate. In such an embodiment, the surface and the arcuate regions are both formed from the same bulk material. To provide the contrast in hydrophobicity, one or both of the surface and arcuate regions are treated or coated. For example, in one embodiment the surface is untreated substrate material and the arcuate regions are chemically treated or coated to provide distinct hydrophobicity and form the elongated ratchet track.
Regarding the vibration of the surface, any combination of amplitude and frequency sufficient to move the droplet along the track is contemplated. In one embodiment, the amplitude is from 1 micron to 1 mm. In one embodiment, the frequency is from 1 Hz to 1 kHz. Flat devices typically require smaller amplitude to operate than textured devices.
That is, for similar geometry devices, a flat device will move a droplet at a lower threshold amplitude than a textured device.
The elongated track can take any shape. The track shapes and functions discussed above with regard to the textured devices are applicable for flat devices. In one embodiment, the elongated track defines a closed loop. In one embodiment the track includes at least one turn. In one embodiment the track splits from a single track into two or more tracks. In one embodiment the track includes a merge of two or more tracks into a single track.
The source of vibration can be any means of vibration. The sources of vibration disclosed above for the textured devices apply to the flat devices. In one embodiment, the step of vibrating the surface comprises a technique selected from the group consisting of acoustic vibration, electromagnetic vibration, and piezoelectric vibration.
The shapes of the transverse arcuate regions are similar to those described above with regard to textured devices. In one embodiment, the transverse arcuate regions have a track width (lateral width from side to side of the track) from 1 micron to 50 mm. In one embodiment, the transverse arcuate regions have a track width from 10 microns to 10 mm.
In one embodiment, the transverse arcuate regions have a region width (“rung width”; width of each rung measured in the longitudinal track direction) from 1 nm to 1 mm. In one embodiment, the transverse arcuate regions have a region width from 100 nm to 100 microns.
In one embodiment, the transverse arcuate regions have a period (“rung period”; longitudinal track distance from the start of one rung to the start of the next rung) from 1 nm to 1 mm. In one embodiment, the transverse arcuate regions have a period from 100 nm to 100 microns.
In one embodiment, the transverse arcuate regions define substantially circular arcs having a constant radius. In one embodiment, the transverse arcuate regions define substantially circular arcs having a varying radius, (e.g., an portion of an ellipse).
In one embodiment, the constant radius is approximately equal to a radius of a footprint of the droplet.
In one embodiment, the substantially circular arcs are equal to or less than ½ of a circle.
In one embodiment, the radius of the substantially circular arcs is half of the track width or more.
In one embodiment, the step of depositing the droplet on the elongated track occurs without any external vibration. That is, the droplet can be deposited on the track prior to applying vibration. Conversely, in one embodiment, the droplet is placed on the track when vibration is applied.
In one embodiment, the step of depositing the droplet on the elongated track occurs via condensation on the elongated track. Droplets are typically deposited on the track in liquid form, although any means of providing the droplet on the track is contemplated, including condensation.
In one embodiment, the plurality of transverse arcuate regions and the surface are transparent at visible wavelengths. As noted above, it is impossible to form textured surface ratchets that are transparent because the height of the mesas introduce visible discontinuities. Because flat ratchets have no height difference between the surface and the arcuate regions, transparent devices are possible. In such embodiments if both the surface and the arcuate regions are transparent materials than the device will be transparent. Transparent devices are desirable for facile integration with microscopy (e.g., inverted epi-fluorescence). Additional benefits can be found in the potential for seamless integration onto windows or displays such as an automobile or an electronic display.
Theory
When a drop is placed on a flat chemically homogeneous surface the contact angle at the three-phase boundary can be characterized by the Young-Dupré equation. However, this equation does not hold if the triple line (TPL) coincides with a wetting discontinuity, where a range of contact angles can be established. Pinning is observed as a contact angle hysteresis, i.e., as the difference between the apparent advancing (θA) and receding contact angles (θR). The metastable state of a liquid on geometric discontinuities was first considered by Gibbs and later experimentally confirmed by Oliver et al. More recently, a similar effect was described at chemical discontinuities between regions of varying wettability. For our purposes, it is useful to define a hysteresis force (FHys) as the difference between the pinning force at the TPL for the advancing and receding state:
F
Hys
=wγ(cos θR−cos θA) (4)
where w is the width of the drop projected orthogonally to the direction of pinning, and γ is the solid-liquid surface tension. By using this projection, we effectively extract the component of the force vector FHys in one direction of pinning. For a drop placed on a heterogeneous surface the classic Cassie-Baxter (CB) equation predicts the apparent contact angle by an area weighted average of the cosines of the material contact angles. Recently, several papers have pointed out the limitations of the CB equation for surfaces with non-uniform pinning at the TPL and proposed modified CB equations. We use the line fraction modified CB equation, which enables a simple and intuitive means for describing our system. When a drop is placed on the device, fractions of the TPL lie on the hydrophilic region, the hydrophobic region and the boundary between the two wettabilities. The portion of the TPL at the boundary accounts for the majority of hysteresis, as its local contact angle (θb) can vary between the equilibrium contact angles of the two materials before it de-pins (θ1<θb<θ2). Using the line fraction method we can relate the apparent contact angle to the alignment of the TPL on a heterogeneous surface:
cos θapp=X1 cos θ1+X2 cos θ2+Xb cos θb (5)
where θapp, θ1 and θ2, and θb are the apparent contact angle, the equilibrium contact angles for the hydrophilic and hydrophobic materials, and the contact angle at the boundary. The line fraction Xi is the proportion of the TPL length on the given materials or along the boundary projected orthogonally to the direction of pinning, such that X1+X2+Xb=1. To solve for cos θR and cos θA from Equation 5 we assume recession occurs when θb=θ1 and advancement when θb=θ2. The results are substituted into Equation 4 to derive the direct relationship between the force of pinning to the boundary line fraction Xb and the difference in the contact angle cosines of the two surfaces.
F
Hys
=X
b
wγ(cos θ1−cos θ2) (6)
On a ratchet utilizing periodic curved rungs as its pawl, an asymmetric boundary line fraction is established between the portion of the drop edge aligned with the curvature, and the portion of the drop edge that is anti-aligned with the curvature of the rungs (
F
Anisotropy=(Xb,Lead−Xb,Trail)wγ(cos θ1−cos θ2) (7)
This equation provides a useful design principle for optimizing performance. Surfaces that maximize the boundary line fraction along the leading edge while minimizing the boundary line fraction along the trailing edge will produce the greatest anisotropy and ratcheting performance. The boundary line fractions Xb,Lead and Xb,Trail are determined by the complex interaction between a drop and a ratchet design—rung period, rung width, track width, rung curvature, and surface hydrophobicity in addition to drop volume, surface tension, and position on the track all play a critical role.
Flat Device Fabrication
To realize a ratchet on a flat surface, we chemically patterned hydrophilic regions (contact angle θ1) on a hydrophobic background (contact angle θ2) with θ1<θ2. In contrast to geometric discontinuities in texture ratchets, the wetting barrier ratchet utilizes a periodic, semi-circular, chemically heterogeneous pattern to induce asymmetric contact angle hysteresis. We report two surface modification techniques using both oxide and gold-adhering self-assembled monolayers (SAMs) to pattern the wettability of a surface. Trimethylsilanol (TMS)-dodecanethiol and TMS-perfluorooctyltrichlorosilane (FOTS) ratchets have been generated. Observations regarding the performance between texture ratchets and wetting barrier ratchets, including the role of rung curvature in establishing asymmetry and ratcheting performance, are disclosed herein.
We present two techniques for surface chemistry modification. One device has a chemically patterned surface of TMS (53° air-water contact angle) and dodecanethiol SAM (104° air-water contact angle). The other has a TMS and FOTS (108° air-water contact angle) patterned surface. For both processes, the silicon wafer was rinsed with acetone, isopropanol, and deionized water. The wafer was then coated with a liquid film of hexamethyldisilazane adhesion primer and allowed to react for 20 seconds before being spun dry. The result is a monolayer of TMS on the wafer surface. Photolithography was then performed with 1.2 μm of AZ1512 photoresist. After development, the remaining photoresist forms the pattern of the ratchet's rungs. An oxygen plasma treatment at 40 W for 5 minutes removes the exposed TMS (the area not covered with photoresist), revealing a bare silicon oxide layer. At this point the fabrication sequences of the two devices diverge.
For the TMS-FOTS ratchet, the next step was a chemical vapor deposition of FOTS in a standard desiccator using a house vacuum for 1 hour. Afterwards, the FOTS was annealed by placing the device on a hot plate for 1 hour at 150° C. to create covalent siloxane bonds. In the final step, the photoresist was removed with acetone revealing a TMS-FOTS pattern.
For the TMS-dodecanethiol ratchet, the next step was an evaporation of 50 nm Au onto the surface, with a 10 nm Cr adhesion layer. Liftoff was then performed. The device was then immersed into a 1:4 dodecanethiol:ethanol (by volume) bath for 1 hour to allow the dodecanethiol to assemble on the Au surface.
Experimental Setup
The experimental setup consisted of an Agilent 33120A function/arbitrary waveform generator, Brüel & Kjær Type 2718 power amplifier, Brüel & Kjær Type 4809 vibration exciter, Agilent Infiniium oscilloscope, Polytec OFV vibrometer, DRS Data & Imaging Systems Inc. Lightning RTD high-speed camera and Matlab on a Windows PC. A die with the wetting barrier ratchet was attached on the vibration exciter such that the die was horizontal and the vibration acted in the vertical direction. Drops of deionized water were pipetted onto the ratchet.
Droplet Transport
A 12.5 μL drop on the TMS-FOTS ratchet was transported at 5.4 mm/s when agitated with a vibrational agitation of 100 μm at 72 Hz. A high-speed camera captured the silhouette of the drop at 1 ms intervals and several frames from one period of oscillation are displayed in
Actuation Amplitude
The minimum amplitude required to initiate transport, defined as the actuation amplitude, is limited by the pinning at the leading edge. Agitation must be significant enough to advance the leading edge of the drop by at least one rung before transport can take place. A geometric sharp edge, i.e., a discontinuity between solid and vapor, will in general result in stronger pinning than a chemical edge, i.e., a discontinuity between two surfaces with different wetting properties. Therefore, wetting barrier ratchets are expected to have lower actuation amplitudes than texture ratchets. Actuation amplitudes were measured on texture ratchets versus the two new wetting barrier ratchets with identical rung layouts. The results shown in
Slip Test
To evaluate experimentally how rung curvature affects pinning anisotropy a slip test was performed. A drop was placed on a TMS-FOTS ratchet mounted on a horizontal stage. The stage was slowly tilted upwards until a critical stage angle (α) was reached at which point the drop slid downhill off the substrate. The slip test was conducted for three rung radii: 590 μm, 1000 μm, and 1500 μm. Experimental results are shown in
F
Anisotropy
=mg(sin αuphill−sin αdownhill) (8)
where m, g, αuphill and αdownhill are the mass of the drop, acceleration due to gravity, critical stage angles for when rung curvature was pointed uphill or downhill, respectively. The difference in α, displayed in
Ratchet Performance vs. Rung Curvature
As predicted by the slip test, the TMS-FOTS ratchet with a 590 μm rung radius outperformed the others in terms of minimizing actuation amplitude and maximizing transport velocity. Actuation amplitudes were evaluated over the same set of devices with their results from the slip test for 15 and 20 μL drops in
The increased force of anisotropy and improved ratchet performance for devices with shorter rung radii suggests a relationship between boundary morphology and pinning strength. To our knowledge, there has not been a comprehensive study directly investigating the issue of boundary curvature and pinning. Several independent investigations have been conducted on the two extremes: circular hydrophilic domain (high curvature) and straight hydrophilic stripe (no curvature). For the circular hydrophilic domain case TPL advancement occurred when θb=θ2. In the hydrophilic stripe case, TPL advancement was observed at θb<θ2. While a more extensive study is required to fully understand the boundary curvature's role in pinning, these studies support our experimental observations that a higher rung curvature increases pinning anisotropy and ratchet performance.
We realize a novel digital microfluidic platform. The wetting barrier ratchet implements a purely chemical pawl made of periodic semi-circular hydrophilic rungs on a hydrophobic background. Wetting barrier ratchets reduce the actuation amplitudes of previously reported texture ratchets more than three-fold for a 10 μL drop. They can be optically flat, making fully transparent devices possible. The chemical pattern can be simply fabricated in a number of ways, including techniques compatible with cheap mass production (e.g., inkjet or contact printing). The flat surface is easily cleaned, integrated with electrodes and sensors and is compatible for down-scaling to nanoscale features for improved performance.
For the first time, we use the line fraction CB equation to provide a theoretical foundation for describing how periodic curved rungs induce anisotropic contact angle hysteresis and drop transport. Experimentally determined pinning anisotropy is shown to be positively related to ratcheting performance in terms of minimizing the actuation amplitude while maximizing transport velocities. The smallest rung radius investigated, 590 μm, a complete semi-circle had the best ratcheting performance.
The wetting barrier ratchet provides a simple and cheap platform for performing drop based chemical or biological microfluidic functions. It could be implemented in a low-power DMF point-of-care technology, or alternatively as a laboratory tool easily integrated with inverted microscopy due to its transparency. Other potential applications include condensation collection on windows or for applications in cooling or desalination.
While illustrative embodiments have been illustrated and described, it will be appreciated that various changes can be made therein without departing from the spirit and scope of the invention.
This application claims the benefit of U.S. Provisional Application No. 61/872,476, filed Aug. 30, 2013. This application is also a continuation-in-part of U.S. application Ser. No. 13/357,036, filed Jan. 24, 2012, which claims the benefit of U.S. Provisional Application No. 61/435,679, filed Jan. 24, 2011, and which is a continuation-in-part of U.S. application Ser. No. 12/179,397, filed Jul. 24, 2008, now U.S. Pat. No. 8,142,168, which claims the benefit of U.S. Provisional Application No. 61/031,281, filed Feb. 25, 2008. The disclosures of each of the above-referenced patents and applications are expressly incorporated herein by reference in their entirety.
This invention was made with Government support under Contract No. ECCS 0501628 awarded by the National Science Foundation. The Government has certain rights in the invention.
Number | Date | Country | |
---|---|---|---|
61872476 | Aug 2013 | US | |
61435679 | Jan 2011 | US | |
61031281 | Feb 2008 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 13357036 | Jan 2012 | US |
Child | 14061625 | US | |
Parent | 12179397 | Jul 2008 | US |
Child | 13357036 | US |