Method of forming an electronic device on a flexible substrate

Abstract

A method of forming an electronic device on a flexible substrate without using acetone dissolvent, including the steps of: printing a hydrophobic mask on a porous membrane to form a pattern thereon which is complementary to a desired pattern; filtering an aqueous suspension of an electronic material through the non-printed region of the porous membrane, whereby some electronic material is deposited on said non-printed region following the desired pattern; pressing the flexible substrate against the printed face of the membrane in order to transfer the patterned electronic material deposited on the porous membrane to the flexible substrate to form the electronic device thereon.

Claims

1. A method of forming an electronic device on a flexible substrate, wherein the flexible substrate is a sheet, the method comprising the steps of: wax printing a hydrophobic mask on a porous membrane to form a pattern thereon which is complementary to a desired pattern; filtering an aqueous suspension consisting of water and an electronic material, wherein the electronic material is graphene oxide, through a non-printed region of the porous membrane, wherein some electronic material is deposited on the non-printed region following the desired pattern; and transferring the patterned electronic material to the sheet by a transfer step consisting of pressing the sheet against the printed face of the porous membrane with a press, enabling the transfer of the patterned electronic material deposited on the porous membrane to the sheet to form the electronic device thereon; wherein the transfer step of the method is carried out without using acetone dissolvent.

2. The method according to claim 1, wherein the electronic material is reduced graphene oxide.

3. The method according claim 1, wherein the porous membrane is made of nitrocellulose, a pore size thereof being between 0.01 m and 0.3 m.

4. The method according of claim 3, wherein the pressing step uses a pressing force of between 500 kg and 700 kg.

5. The method according to claim 1, wherein the sheet is organic.

6. The method according to claim 5, wherein the sheet is polyethylene terephthalate (PET).

7. The method of claim 5, wherein the sheet is a continuous sheet and the pressing step is performed with roll-to-roll hardware.

8. The method according to claim 7, wherein the hydrophobic mask is printed with a printer which is integrated with the roll-to-roll hardware.

9. The method according to claim 1, wherein the press actuates through a stamp to which the sheet is adhered.

10. The method according to claim 1, wherein the electronic device is an interdigitated electrode.

11. The method according to claim 1, wherein the electronic device is transparent.

12. The method according to claim 1, wherein the pressing step uses a pressing force of between 500 kg and 700 kg.

13. The method according to claim 1, wherein the electronic material is oxidized graphene oxide.

14. The method according to claim 1, wherein the electronic device is an electrode microarray.

15. The method according claim 1, wherein the porous membrane is made of nitrocellulose, a pore size thereof being between 0.01 m and 0.1 m.

16. The method according of claim 15, wherein the pressing step uses a pressing force of between 500 kg and 700 kg.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Some examples of the present disclosure will be described in the following, only by way of a non-limiting example, with reference to the appended drawings, in which:

(2) FIGS. 1a, 1b, 1c, 1d and 1e schematically show some steps of a method of forming a patterned electronic device on a flexible substrate;

(3) FIGS. 2a and 2b schematically show a printing step; and

(4) FIGS. 3a, 3b, 4a, 4b, 5a. 5b, 6a and 6b show examples of patterned electronic devices.

DETAILED DESCRIPTION OF THE EMBODIMENTS

(5) With reference to FIG. 1, FIG. 1a represents a porous membrane 10, e.g. a hydrophilic nitrocellulose membrane (NCM) with a pore size of approximately 25 nm. FIG. 1b shows a hydrophobic mask 12 printed on the porous membrane, e.g. a wax-printed mask (WPM) with a height of approximately 25 m. The mask 12 follows a pattern that is complementary to the pattern desired for an electronic device or structure 20 (see FIGS. 1b and 1e), and leaves corresponding openings 11 that reach the surface of the membrane 10.

(6) FIG. 1c shows an electronic material 22 deposited on the non-printed region of the porous membrane 10, i.e. on the openings 11 left by the mask 12, as a consequence of the vacuum filtration of a suspension, e.g. an aqueous suspension, of the electronic material, e.g. non-conductive graphene oxide (oGO), through the porous membrane. That is, the liquid, e.g. water, is filtered through the membrane 10 and there is a deposition of electronic material 22 into the openings 11 (remember that the printed mask 12 is hydrophobic) and onto the non-printed region of the porous membrane. Since the printed mask 12 follows a pattern that is complementary to the pattern desired for the electronic device, the deposited electronic material 22 follows the desired pattern.

(7) FIG. 1d shows the assembly of the porous membrane 10, the printed mask 12 and the electronic material 22 turned down and being pressed by a press stamp 50 (e.g. a PDMS stamp) against a flexible substrate 30, e.g. PET, exerting a force of for example 600 kg. The face of the assembly in contact with the substrate 30 is the face with the printed mask 12 and the electronic material 22 deposited on the openings 11 left by said mask.

(8) FIG. 1e shows the electronic material transformed into an electronic device 20 transferred onto the flexible substrate 30 by virtue of the pressure exerted by the stamp 50, on account of the van der Waals interactions being weaker between the electronic material 22 and the porous membrane 10 than between the electronic material 22 and the flexible substrate 30 (see FIG. 1e).

(9) FIG. 2 shows the process of printing wax masks 12 with the aid of a computer 60 and a printer 70 (e.g. a Xerox ColourQube 8570 printer). The masks can be computer-designed and such designs can be wax-printed on nitrocellulose sheets 10. Openings 11 define the desired electrode pattern (the openings are the complement or negative of the mask).

(10) FIG. 3a shows an example of a mask 121 printed on a porous membrane 101 and leaving some openings 111, and FIG. 3b shows an electronic device 201 that matches the openings 111, and thus is complementary to the mask 121, and has been transferred onto a flexible substrate 301. This is an example of square electrodes forming the electronic device 201.

(11) FIG. 4a shows an example of a mask 122 printed on a porous membrane 102 and leaving some openings 112, and FIG. 4b shows an electronic device 202 that matches the openings 112, and thus is complementary to the mask 122, and has been transferred onto a flexible substrate 302. This is an example of interdigitated electrodes forming the electronic device 202.

(12) FIG. 5b shows an example of an electronic device 203 on a flexible substrate 303 and FIG. 5a shows a pair of corresponding electrodes in greater detail. This is an example of circular interdigitated electrodes forming the electronic device 203.

(13) FIG. 6b shows an example of an electronic device 204 on a flexible substrate 304 and FIG. 6a shows a pair of corresponding electrodes in greater detail. This is an example of an electrode microarray forming the electronic device 204.

(14) Naturally, the materials can vary from one example to another one, can be the same for some elements and different for others, or can be always the same for analogous elements. And there can be any suitable number of electrodes (or electronic components) formed on the flexible substrate or even different electrodes or components on the same substrate.

(15) Regarding the method of forming a, for example, oGO structure on a, for example, organic substrate, the NCM is first patterned in the desired shape using a, for example, wax printer (FIG. 2) The areas to be printed are delineated by a binary color-coding scheme. The colored areas, assigned a positive value (or 1, in binary programming language), are destined for wax printing (see ref. 12 in FIG. 1b), whereas the uncolored areas, given a negative value (or 0), are left unprinted to subsequently serve as filters (openings 11). An aqueous suspension of oGO is poured onto the mask and then filtered through these uncovered areas 11.

(16) The WPM is set onto a filtering glass and the suspension of oGO (at a desired concentration) is filtered, leaving an oGO mesh on top of the WPM (FIG. 1c). In related work, other groups had reported that the concentration and volume of the oGO suspension strongly influence the filtration rate. However, in this case a reduction in the filtration area led to a strong decrease in pressure and, consequently, to a much slower filtration. Therefore, it was decided to simply remove the unfiltered oGO, instead.

(17) The WPM topped with oGO 22 is placed onto the substrate 30 and the assembly is subjected to vertical pressure (FIG. 1d), which leaves a patterned oGO device or structure 20 (e.g. electrodes) on the substrate surface (FIG. 1e). It is hypothesized that the transfer involves two related steps: expulsion of the oGO from the WPM and attachment of it to the substrate surface. The inventors believe that the expulsion occurs by simple air/humidity pressure and that the attachment is favored by van der Waals forces, as the reported values at the oGO/NCM interface are lower than those at the oGO/substrate interface.

(18) Additionally, as proof of concept of a technique that is presently considered amenable to specialized technologies, a wax printer outfitted with roll-to-roll hardware was used to transfer shaped oGO onto a PET substrate. The roll-to-roll machinery can be used for feeding substrate sheets into the printer and for printing the wax, and must apply sufficient pressure to transfer the oGO. This method offers strong potential for simple, fast printing of this class of oGO devices on an industrial scale.

(19) The lateral height of the WPMs was measured and their long-term stability was assessed. The direction of the wax printing (horizontal or vertical) was an important parameter to evaluate, as it affects the resolution and the shape of the lines edges. The best resolution was obtained when the line was printed vertically, as it did not lead to any systematic curves on the border. Different wax mask shapes were also evaluated. All the masks shown (FIGS. 3a and 4a), or implied (FIGS. 5 and 6), in the figures exhibited acceptable designs over a range of 200 to 300 m, which is consistent with literature values for printing onto paper or NCM. The transversal cut of the WPM shows a medium height of circa 25 m. The change in lateral spreading of the wax across the WPM at room temperature was studied over 5 months and no significant deformation or spreading was observed. It is, therefore, concluded that these WPMs are stable over the long term.

(20) The wax-printing method has been used to create various different masks for printing oGO devices or platforms (FIGS. 3 to 6). In the general procedure, a WPM is first laid onto the filtering glass and 5 mL of an aqueous suspension of oGO (0.1 mg/mL) is then filtered through it for 5 min. The unfiltered oGO solution is removed (and can later be reused), leaving behind an oGO mesh 22 on top of the membrane 10, as represented in FIG. 1c. The concentration, volume and filtering time of the oGO suspension each depend on the filtering pressure and can be adjusted according to the requirements of the desired end application. This methodology is faster than previously reported methods and is also controllable.

(21) Reduced graphene oxide (rGO) is a conductor and can be obtained by reducing the corresponding oGO products with hydrazine vapor.

(22) The present WPM method and subsequent reduction can be used to pattern various types of electronic devices, like generic interdigitated electrodes (IDEs, FIG. 4), circular IDEs (FIG. 5), or multiarray microelectrode systems amenable to multidetection applications (FIG. 6).

(23) In FIG. 3, four squares 201 of oGO are patterned onto a PET film 301, and then reduced to make them conductive. Next, several 300-m circles of oGO can be created and then transferred onto the rGO squares on the film, leaving behind circular oGO patterns to build up an integrated system wired by inkjet printing of silver ink. Such architecture enables conjugation of diverse nanomaterials and/or biomaterials to the device and further exploitation of the properties of oGO. SEM (Scanning Electron Microscope) images of the (transparent) electronic devices show that the oGO transfer is efficient and that the shapes are well defined.

(24) The EIS (Electrochemical Impedance Spectroscopy) response of the generic IDEs 202 of FIG. 4b deposited onto different flexible substrates 302 (e.g. glass, PEN, PET, cellulose acetate, plastic adhesive film, wax-modified paper, etc) shows an interesting behavior for applications in a myriad fields, including biosensing and energy (e.g. solar cells). The obtained results open the door to diversely functionalized flexible and transparent rGO electrodes. The EIS responses of the generic IDEs printed onto different flexible materials vary in their electrode-electrolyte interface impedance (EEII), which can be attributed to the differences in surface roughness, flexibility and hydrophobicity of the respective substrates, as these factors would have influenced the morphology of the printed oGO. The PEN and flexible glass present the lowest EEII, whereas the plastic adhesive film and the cellulose acetate offer the highest values.

(25) However, PET offered the best trade-off in terms of cost, transparency and flexibility, and it was chosen for further studies on the influence of oGO concentration on IDE performance (as measured by EIS). An increase in oGO concentration correlated to a decrease in EEII and therefore, to an increase in conductivity of rGO, consistently with literature reports. This trend was indirectly confirmed by performing AFM (Atomic Force Microscopy) studies on analogous glass IDEs, since PET, because of its roughness, is not very suitable for nanometric AFM measurements.

(26) In summary, the present disclosure reports a new, versatile and customizable method for patterning oGO onto flexible substrates through highly stable, microscale WPMs. These masks enable controlled printing of oGO in various shapes of interest for different applications. The oGO-printing technology reported here is advantageous over previously reported methods for fabrication of GO-based devices in terms of ease, cost and potential end-applications: for instance, it does not require the use of a clean room. It should ultimately pave the way to ready, low-cost industrial fabrication of a broad array of GO-based devices such as sensors and biosensors.

(27) Although only particular embodiments of the invention have been shown and described in the present specification, the skilled man will be able to introduce modifications and substitute any technical features thereof with others that are technically equivalent, depending on the particular requirements of each case, without departing from the scope of protection defined by the appended claims.

(28) For example, although the electronic devices are represented as black in the drawings, they can be transparent or translucent.