The present invention is directed to nanostructures. More particularly, the invention provides arrays of long nanostructures in semiconductor substrates and methods thereof. Merely by way of example, the invention has been applied to arrays of long nanowires in silicon with certain thermoelectric properties. However, it would be recognized that the invention has a much broader range of applicability, including but not limited to use in solar power, battery electrodes and/or energy storage, catalysis, and/or light emitting diodes.
Thermoelectric materials are ones that, in the solid state and with no moving parts, can, for example, convert an appreciable amount of thermal energy into electricity in an applied temperature gradient (e.g., the Seebeck effect) or pump heat in an applied electric field (e.g., the Peltier effect). The applications for solid-state heat engines are numerous, including the generation of electricity from various heat sources whether primary or waste, as well as the cooling of spaces or objects such as microchips and sensors. Interest in the use of thermoelectric devices that comprise thermoelectric materials has grown in recent years in part due to advances in nano-structured materials with enhanced thermoelectric performance (e.g., efficiency, power density, or “thermoelectric figure of merit” ZT, where ZT is equal to S2 σ/k and S is the Seebeck coefficient, σ the electrical conductivity, and k the thermal conductivity of the thermoelectric material) and also due to the heightened need both for systems that either recover waste heat as electricity to improve energy efficiency or cool integrated circuits to improve their performance.
To date, thermoelectrics have had limited commercial applicability due to the poor cost performance of these devices compared to other technologies that accomplish similar means of energy generation or refrigeration. Where other technologies usually are not as suitable as thermoelectrics for use in lightweight and low footprint applications, thermoelectrics often have nonetheless been limited by their prohibitively high costs. Important in realizing the usefulness of thermoelectrics in commercial applications is the manufacturability of devices that comprise high-performance thermoelectric materials (e.g., modules). These modules are preferably produced in such a way that ensures, for example, maximum performance at minimum cost.
The thermoelectric materials in presently available commercial thermoelectric modules are generally comprised of bismuth telluride or lead telluride, which are both toxic, difficult to manufacture with, and expensive to procure and process. With a strong present need for both alternative energy production and microscale cooling capabilities, the driving force for highly manufacturable, low cost, high performance thermoelectrics is growing.
Thermoelectric devices are often divided into thermoelectric legs made by conventional thermoelectric materials such as Bi2Te3 and PbTe, contacted electrically, and assembled in a refrigeration (e.g., Peltier) or energy conversion (e.g., Seebeck) device. This often involves bonding the thermoelectric legs to metal contacts in a configuration that allows a series-configured electrical connection while providing a thermally parallel configuration, so as to establish a temperature gradient across all the legs simultaneously. However, many drawbacks may exist in the production of conventional thermoelectric devices. For example, costs associated with processing and assembling the thermoelectric legs made externally is often high. The conventional processing or assembling method usually makes it difficult to manufacture compact thermoelectric devices needed for many thermoelectric applications. Conventional thermoelectric materials are usually toxic and expensive.
Nanostructures often refer to structures that have at least one structural dimension measured on the nanoscale (e.g., between 0.1 nm and 1000 nm). For example, a nanowire is characterized as having a cross-sectional area that has a distance across that is measured on the nanoscale, even though the nanowire may be considerably longer in length. In another example, a nanotube, or hollow nanowire, is characterized by having a wall thickness and total cross-sectional area that has a distance across that is measured on the nanoscale, even though the nanotube may be considerably longer in length. In yet another example, a nanohole is characterized as a void having a cross-sectional area that has a distance across that is measured on the nanoscale, even though the nanohole may be considerably longer in depth. In yet another example, a nanomesh is an array, sometimes interlinked, including a plurality of other nanostructures such as nanowires, nanotubes, and/or nanoholes.
Nanostructures have shown promise for improving thermoelectric performance. The creation of 0D, 1D, or 2D nanostructures from a thermoelectric material may improve the thermoelectric power generation or cooling efficiency of that material in some instances, and sometimes very significantly (a factor of 100 or greater) in other instances. However, many limitations exist in terms of alignment and scale for the nanostructures needed in an actual macroscopic thermoelectric device comprising many nanostructures. The ability to process nanostructures in similar methods to the processing of silicon and other semiconductors would have tremendous cost advantages.
Hence, it is highly desirable to improve techniques for the formation of large arrays of very long nanostructures, such as nanowires or nanoholes, using less expensive and less toxic materials such as silicon, its alloys, and other suitable semiconductors. It is also highly desirable to form these large arrays of very long nanostructures from materials with advantageous electrical and thermal properties for use in thermoelectric devices.
The present invention is directed to nanostructures. More particularly, the invention provides arrays of long nanostructures in semiconductor substrates and methods thereof. Merely by way of example, the invention has been applied to arrays of long nanowires in silicon with certain thermoelectric properties. However, it would be recognized that the invention has a much broader range of applicability, including but not limited to use in solar power, battery electrodes and/or energy storage, catalysis, and/or light emitting diodes.
According to one embodiment, an array of nanowires includes a plurality of nanowires. The plurality of nanowires includes a plurality of first ends and a plurality of second ends respectively. For each of the plurality of nanowires, a corresponding first end selected from the plurality of first ends and a corresponding second end selected from the plurality of second ends are separated by a distance of at least 200 μm. All nanowires of the plurality of nanowires are substantially parallel to each other.
According to another embodiment, an array of nanostructures includes a plurality of nanostructures. The plurality of nanostructures includes a plurality of first ends and a plurality of second ends respectively. For each of the plurality of nanostructures, a corresponding first end selected from the plurality of first ends and a corresponding second end selected from the plurality of second ends are separated by a distance of at least 200 μm. All nanostructures of the plurality of nanostructures are substantially parallel to each other. Each of the plurality of nanostructures includes a semiconductor material.
According to yet another embodiment, an array of nanowires includes a plurality of nanowires. Each of the plurality of nanowires includes a first end at a first surface and a second end. The first end and the second end are separated by a first distance of at least 200 μm. The plurality of nanowires corresponds to a first area on the first surface. All nanowires of the plurality of nanowires are substantially parallel to each other.
According to yet another embodiment, an array of nanostructures includes a plurality of nanostructures. Each of the plurality of nanostructures includes a first end at a first surface and a second end. The first end and the second end are separated by a first distance of at least 200 μm. The plurality of nanostructures corresponds to a first area on the first surface. All nanostructures of the plurality of nanostructures are substantially parallel to each other. Each of the plurality of nanostructures includes a semiconductor material.
According to yet another embodiment, the method for forming an array of nanowires includes: providing a semiconductor substrate including a first surface and one or more second surfaces; masking at least one or more portions of the one or more second surfaces with at least a first portion of the first surface being exposed; applying a metalized film to at least the exposed first portion of the first surface; etching the semiconductor substrate through at least the exposed first portion of the first surface using a first etchant solution; and forming a first plurality of nanowires. Each of the first plurality of nanowires includes a first end at a third surface and a second end. The first end and the second end are separated by a first distance of at least 200 μm. The first plurality of nanowires corresponds to a first area on the first surface. The first area on the first surface substantially corresponds to the exposed first portion of the first surface. All nanowires of the first plurality of nanowires are substantially parallel to each other.
Depending upon the embodiment, one or more of these benefits may be achieved. These benefits and various additional objects, features, and advantages of the present invention can be fully appreciated with reference to the detailed description and accompanying drawings that follow.
The present invention is directed to nanostructures. More particularly, the invention provides arrays of long nanostructures in semiconductor substrates and methods thereof. Merely by way of example, the invention has been applied to arrays of long nanowires in silicon with certain thermoelectric properties. However, it would be recognized that the invention has a much broader range of applicability, including but not limited to use in solar power, battery electrodes and/or energy storage, catalysis, and/or light emitting diodes.
In general, the usefulness of a thermoelectric material depends upon the physical geometry of the material. For example, the larger the surface area of the thermoelectric material that is presented on the hot and cold sides of a thermoelectric device, the greater the ability of the thermoelectric device to support heat and/or energy transfer through an increase in power density. In another example, a suitable minimum distance (i.e., the length of the thermoelectric nanostructure) between the hot and cold sides of the thermoelectric material help to better support a higher thermal gradient across the thermoelectric device. This in turn may increase the ability to support heat and/or energy transfer by increasing power density.
One type of thermoelectric nanostructure is an array of nanowires with suitable thermoelectric properties. Nanowires can have advantageous thermoelectric properties, but to date, conventional nanowires and nanowire arrays have been limited in their technological applicability due to the relatively small sizes of arrays and the short lengths of fabricated nanowires. Another type of nanostructure with thermoelectric applicability is nanoholes or nanomeshes. Nanohole or nanomesh arrays also have limited applicability due to the small volumes into which these nanostructures can be created or synthesized. For example, conventional nanostructures with lengths shorter than 100 μm have limited applicability in power generation and/or heat pumping, and conventional nanostructures with lengths shorter than 10 μm have even less applicability because the ability to maintain or establish a temperature gradient using available heat exchange technology across these short lengths is greatly diminished. Furthermore, in another example, arrays smaller than the wafer dimensions of 4, 6, 8, and 12 inches are commercially limited.
The development of large arrays of very long nanostructures formed using semiconductor materials, such as functionalized silicon, can be useful in the formation of thermoelectric devices. For example, silicon nanostructures that have a low thermal conductivity, and formed within a predetermined area of a semiconductor substrate can be utilized to form a plurality of thermoelectric elements for making a uniwafer thermoelectric device. In another example, functionalized silicon nanowires formed within the predetermined area of the semiconductor substrate can be utilized as the n- or p-type legs or both in an assembled thermoelectric device.
In some embodiments, the semiconductor substrate 110 is functionalized. For example, the semiconductor substrate 110 is doped to form an n-type semiconductor. In another example, the semiconductor substrate 110 is doped to form a p-type semiconductor. In yet another example, the semiconductor substrates is doped using Group III and/or Group V elements. In yet another example, the semiconductor substrate 110 is functionalized to control the electrical and/or thermal properties of the semiconductor substrate 110. In yet another example, the semiconductor substrate 110 includes silicon doped with boron. In yet another example, the semiconductor substrate 110 is doped to adjust the resistivity of the semiconductor substrate 110 to between approximately 0.00001 Ω-m and 10 Ω-m. In yet another example, the semiconductor substrate 110 is functionalized to provide the array of nanostructures 120 with a thermal conductivity between 0.1 W/m-K and 10 W/m-K.
In other embodiments, the array of nanostructures 120 is formed in the semiconductor substrate 110. For example, the array of nanostructures 120 is formed in substantially all of the semiconductor substrate 110. In another example, the array of nanostructures 120 includes a plurality of very long nanowires 130. In yet another example, each of the plurality of nanowires 130 has a first end 140 and a second end 150. In yet another example, the first ends 140 of the plurality of nanowires 130 collectively form a first surface area of the array of nanostructures 160. In yet another example, the first surface area of the plurality of nanowires 160 is 0.1 mm by 0.0 mm. In yet another example, the first surface area of the plurality of nanowires 160 is 450 mm in diameter. In yet another example, the second ends 150 of the plurality of nanowires 130 collectively form a second surface area of the plurality of nanowires 170. In yet another example, a distance between each of the first ends 140 of the plurality of nanowires 130 and the second ends 150 of each of the plurality of nanowires 130 is at least 200 μm. In yet another example, a distance between each of the first ends 140 of the plurality of nanowires 130 and the second ends 150 of each of the plurality of nanowires 130 is at least 300 μm. In yet another example, a distance between each of the first ends 140 of the plurality of nanowires 130 and the second ends 150 of each of the plurality of nanowires 130 is at least 400 μm. In yet another example, a distance between each of the first ends 140 of the plurality of nanowires 130 and the second ends 150 of each of the plurality of nanowires 130 is at least 500 μm. In yet another example, a distance between each of the first ends 140 of the plurality of nanowires 130 and the second ends 150 of each of the plurality of nanowires 130 is at least 525 μm.
In yet another example, all the nanowires of the plurality of nanowires 130 are substantially parallel to each other. In yet another example, the plurality of nanowires 130 is formed substantially vertically in the semiconductor substrate 110. In yet another example, the plurality of nanowires 130 are oriented substantially perpendicular to the first surface area of the nanostructure 160 and the second surface area of the nanostructure 170. In yet another example, the each of the plurality of nanowires 130 has a roughened surface. In yet another example, each of the plurality of nanowires 130 includes a substantially uniform cross-sectional area with a large ratio of length to cross-sectional area. In yet another example, the cross-sectional area of each of the plurality of nanowires 130 is substantially circular. In yet another example, the cross-sectional area of each of the plurality of nanowires 130 is between 1 nm to 250 nm across. In yet another example, each of the plurality of nanowires 130 are spaced between 25 nm to 250 nm from each other.
As discussed above and further emphasized here,
Referring to the process 310, the semiconductor substrate from which the nanostructure will be formed is provided. In one example, the semiconductor substrate is semiconductor substrate 110. In another example, the semiconductor substrate includes silicon. In yet another example, the semiconductor substrate includes GaAs or other semiconductors.
According to certain embodiments, the optional process 320 for functionalizing the semiconductor can be performed with various methods and to alter various material properties of the semiconductor substrate. For example, the semiconductor substrate is functionalized through one or more subprocesses involving doping, alloying, thermal diffusion treatment, and other material processing techniques. In another example, the semiconductor substrate has its thermoelectric figure of merit enhanced (e.g., through subprocesses or during formation of nanostructures). In another example, the thermal conductivity is reduced and/or electric conductivity increased while the Seebeck coefficient is not decreased significantly.
At the process 330, the semiconductor substrate is washed according to certain embodiments. In one example, the semiconductor substrate is washed using one or more chemical solutions. In another example, the semiconductor substrate is washed using Piranha solution. In yet another example, the semiconductor substrate is washed using hydrogen fluoride (HF).
According to some embodiments, at the process 340 portions of the semiconductor substrate are masked. According to certain embodiments, portions of the semiconductor substrate are masked to define an exposed surface region of the semiconductor substrate where a plurality of nanostructures are to be formed. For example, one or more masking materials are applied to those areas of the semiconductor substrate where the nanostructure is not desired. In another example, the one or more masking materials includes one or more materials from a group comprising tape, nail polish, photo resist, films (e.g., Si3N4, SiC, DLC), or any other suitable masking film or material. In yet another example, one or more conductive films are used as the one or more masking materials. In yet another example, the one or more conductive films are selected from a group consisting of Al, SiC, Ti, Ni, Au, Ag, Cr, ITO, Fe, Pt, and Mo. In yet another example, the one or more conductive films allow electrical conductance between an etchant solution and the semiconductor substrate 510 and modify and/or enhance the transfer of electrons or holes during later processing steps. In yet another example, the one or more masking materials are a combination of one or more conductive films and/or one or more non-conductive films.
As discussed above and further emphasized here,
In yet another example, the metalized film 830 includes a porous structure. In yet another example, the metalized film 830 includes a partial layer with holes 850. In yet another example, the porous structure includes nanoscale holes 850 over the corresponding exposed surface region 840. In yet another example, the metalized film 830 defines a pattern to guide further processing steps. In yet another example, the areas of the metalized film 830 with holes 850 allow the semiconductor so exposed to be susceptible to oxidation. In yet another example, the oxidized semiconductor protects the underlying semiconductor substrate 810 from further processing steps.
According to other embodiments, the metalized film 830 is formed by various processes. In one example, the metalized film 830 is applied by electroless deposition in an HF solution. In another example, the metalized film 830 is formed by sputtering deposition in a vacuum chamber. In yet another example, the metalized film 830 is applied by thermo evaporation. In yet another example, the metalized film 830 is applied by electrochemical deposition. In yet another example, the metalized film 830 is deposited using a lithography process. In yet another example, the lithography process include a wet etch, a dry etch, and/or lift-off techniques. In yet another example, the process 350 for applying the metalized film 830 is controlled to obtain a desired distribution and size of the holes 850. In yet another example, each of the holes 850 defines the location and size of a nanowire.
As discussed above and further emphasized here,
In yet another example, the etching process 360 executes in a highly anisotropic manner in a direction substantially strictly into the semiconductor substrate 810. In yet another example, the metallic particles in the metalized film 830 catalyze the etching of the underlying semiconductor substrate. In yet another example, the semiconductor substrate 810 under the holes 850 in the metalized film 830 develop a semiconductor oxide that substantially protects those portions of the semiconductor substrate 810 from etching. In yet another example, a plurality of nanowires 960 form under each of the holes 850 as the semiconductor substrate around each of the plurality of nanowires 960 is etched away. In yet another example, the plurality of nanowires 960 is the plurality of nanowires 130. In yet another example, the length of the plurality of nanowires 960 is controlled by the choice of etchant solution 930, temperature during the etching process 360, and/or duration of the etching process 360. In yet another example, the temperature is raised above room temperature. In yet another example, the temperature is lowered below room temperature. In yet another example, a metal dendrite structure 970 forms on the surface of the semiconductor substrate 810. In yet another example, the metal dendrite structure 970 is altered by the addition of one or more chemicals selected from a group consisting of KMnO4, HNO3, and the like.
According to certain embodiments, one or more dimensions of each of the plurality of nanowires 960 is controlled. For example, the cross-sectional area of each of the plurality of nanowires 960 is controlled by the shape and size of the holes 850 in the metalized film 830. In another example, each of the plurality of nanowires 960 has a first end 980. In yet another example, each of the plurality of nanowires 960 has a second end 990. In yet another example, a distance between each of the first ends 980 of the plurality of nanowires 960 and the second ends 990 of each of the plurality of nanowires 960 is at least 200 μm. In yet another example, a distance between each of the first ends 980 of the plurality of nanowires 960 and the second ends 990 of each of the plurality of nanowires 960 is at least 400 μm. In yet another example, a distance between each of the first ends 980 of the plurality of nanowires 960 and the second ends 990 of each of the plurality of nanowires 960 is at least 500 μm.
In other embodiments, the etchant solution 930 includes HF, AgNO3, and H2O. For example, the molar concentration of the HF in the etchant solution 930 varies from 2M to 10M. In another example, the molar concentration of AgNO3 in the etchant solution 930 varies from 0.001M to 0.5M. In yet another example, other molar concentrations vary depending on the etching parameters desired. In yet another embodiment, KNO3 is added to the etchant solution 930. In one example, the KNO3 is added to the etchant solution 930 after a certain time period of initial etching without KNO3 in the etchant solution 930. In another example, KNO3 is added to the etchant solution 930 all at once. In yet another example, KNO3 is added to the etchant solution 930 continuously at a predetermined rate. In yet another example, KNO3 is added to the etchant solution 930 to maintain the proper balance between Ag and Ag+ to control the etching rate, the anisotropy, and/or other etch characteristics. In yet another embodiment, other oxidizing agents other than KNO3 are added to the etchant solution 930. In yet another embodiment, the process 360 for etching the semiconductor substrate 810 includes multiple subprocesses. In one example, a first etchant solution including HF, AgNO3, and H2O is used for a first time period and then a second etchant solution including HF, H2O2, and H2O is used for a second time period. In another example, a third etchant solution including HF, AgNO3, and H2O is used for a third time period and then a fourth etchant solution including HF, Fe(NO3)3, and H2O is used for a fourth time period.
As discussed above and further emphasized here,
In other embodiments, the method 300 for forming the nanostructure in the semiconductor substrate 810 includes an optional process 380 for drying the etched semiconductor substrate 810. In one example, the process 380 for drying the etched semiconductor substrate 810 removes any liquid residues from the semiconductor substrate 810 and/or the plurality of nanowires 960. In another example, the process 380 for drying the etched semiconductor substrate 810 includes using natural or forced convection. In yet another example, the process 380 for drying the etched semiconductor substrate 810 includes heating the semiconductor substrate 810 to an elevated temperature. In yet another example the elevated temperature is not to exceed 500 degrees C. In yet another example, the process 380 varies in length from 10 seconds to 24 hours. In yet another example, the process 380 for drying the etched semiconductor substrate 810 includes the use of a Critical Point Dryer (CPD). In yet another example, the process 380 for drying the etched semiconductor substrate 810 includes the use of low surface tension materials.
As discussed above and further emphasized here,
As discussed above and further emphasized here,
According to one embodiment, an array of nanowires includes a plurality of nanowires. The plurality of nanowires includes a plurality of first ends and a plurality of second ends respectively. For each of the plurality of nanowires, a corresponding first end selected from the plurality of first ends and a corresponding second end selected from the plurality of second ends are separated by a distance of at least 200 μm. All nanowires of the plurality of nanowires are substantially parallel to each other. For example, the array of nanowires is implemented according to at least
In another example, the distance is at least 300 μm. In yet another example, the distance is at least 400 μm. In yet another example, the distance is at least 500 μm. In yet another example, the distance is at least 525 μm. In yet another example, each of the plurality of nanowires includes a semiconductor material. In yet another example, the semiconductor material is silicon.
According to another embodiment, an array of nanostructures includes a plurality of nanostructures. The plurality of nanostructures includes a plurality of first ends and a plurality of second ends respectively. For each of the plurality of nanostructures, a corresponding first end selected from the plurality of first ends and a corresponding second end selected from the plurality of second ends are separated by a distance of at least 200 μm. All nanostructures of the plurality of nanostructures are substantially parallel to each other. Each of the plurality of nanostructures includes a semiconductor material. For example, the array of nanostructures is implemented according to at least
In another example, the semiconductor material is silicon. In yet another example, the distance is at least 300 μm. In yet another example, the distance is at least 400 μm. In yet another example, the distance is at least 500 μm. In yet another example, the distance is at least 525 μm. In yet another example, the plurality of nanostructures corresponds to a plurality of nanoholes respectively.
According to yet another embodiment, an array of nanowires includes a plurality of nanowires. Each of the plurality of nanowires includes a first end (e.g., the end 150) at a first surface and a second end (e.g., the end 140). The first end and the second end are separated by a first distance of at least 200 μm. The plurality of nanowires corresponds to a first area on the first surface. All nanowires of the plurality of nanowires are substantially parallel to each other. For example, the array of nanowires is implemented according to at least
In another example, the plurality of nanowires is a part of a thermoelectric device. In yet another example, the first distance is at least 300 μm. In yet another example, the first distance is at least 400 μm. In yet another example, the first distance is at least 500 μm. In yet another example, the first distance is at least 525 μm. In yet another example, the first area is at least 100 mm2 in size. In yet another example, the first area is at least 1000 mm2 in size. In yet another example, the first area is at least 2500 mm2 in size. In yet another example, the first area is at least 5000 mm2 in size.
In yet another example, each of the plurality of nanoholes are substantially perpendicular to the first surface. In yet another example, each of the plurality of nanowires corresponds to a cross-sectional area associated with a distance across less than 250 nm. In yet another example, the cross-sectional area is substantially uniform along a longitudinal direction for each of the plurality of nanowires. In yet another example, the plurality of nanowires includes a first nanowire and a second nanowire, the first nanowire and the second nanowire are separated by a second distance less than 1000 nm. In yet another example, each of the plurality of nanowires is separated from another nanowire selected from the plurality of nanowires by a second distance less than 1000 nm. In yet another example, each of the plurality of nanowires includes a semiconductor material. In yet another example, the semiconductor material is silicon.
According to yet another embodiment, an array of nanostructures includes a plurality of nanostructures. Each of the plurality of nanostructures includes a first end at a first surface and a second end. The first end and the second end are separated by a first distance of at least 200 μm. The plurality of nanostructures corresponds to a first area on the first surface. All nanostructures of the plurality of nanostructures are substantially parallel to each other. Each of the plurality of nanostructures includes a semiconductor material. For example, the array of nanostructures is implemented according to at least
In another example, the plurality of nanostructures is a part of a thermoelectric device. In yet another example, the semiconductor material is silicon. In yet another example, the first distance is at least 300 μm. In yet another example, the first distance is at least 400 μm. In yet another example, the first distance is at least 500 μm. In yet another example, the first distance is at least 525 μm. In yet another example, the first area is at least 100 mm2 in size. In yet another example, the first area is at least 1000 mm2 in size. In yet another example, the first area is at least 2500 mm2 in size. In yet another example, the first area is at least 5000 mm2 in size. In yet another example, the plurality of nanostructures are substantially perpendicular to the first surface.
In yet another example, each of the plurality of nanostructures corresponds to a plurality of nanoholes respectively. In yet another example, each of the plurality of nanoholes corresponds to a cross-sectional area associated with a distance across less than 250 nm. In yet another example, the cross-sectional area is substantially uniform along a longitudinal direction for each of the plurality of nanoholes. In yet another example, the plurality of nanostructures includes a first nanostructure and a second nanostructure, the first nanostructure and the second nanostructure are separated by a second distance less than 1000 nm. In yet another example, each of the plurality of nanostructures is separated from another nanostructure selected from the plurality of nanostructures by a second distance less than 1000 nm.
According to yet another embodiment, the method for forming an array of nanowires includes: providing a semiconductor substrate including a first surface and one or more second surfaces; masking at least one or more portions of the one or more second surfaces with at least a first portion of the first surface being exposed; applying a metalized film to at least the exposed first portion of the first surface; etching the semiconductor substrate through at least the exposed first portion of the first surface using a first etchant solution; and forming a first plurality of nanowires. Each of the first plurality of nanowires includes a first end (e.g., the end 150) at a third surface and a second end (e.g., the end 140). The first end and the second end are separated by a first distance of at least 200 μm. The first plurality of nanowires corresponds to a first area on the first surface. The first area on the first surface substantially corresponds to the exposed first portion of the first surface. All nanowires of the first plurality of nanowires are substantially parallel to each other. For example, the method is implemented according to at least
In another example, the semiconductor substrate includes silicon. In yet another example, the process for masking at least one or more portions of the one or more second surfaces includes applying one or more masking materials to the one or more second surfaces. In yet another example, the one or more masking materials are selected from a group consisting of tape, nail polish, photo resist, Si3N4, SiC, DLC, Al, Ti, Ni, Au, Ag, Cr, ITO, Fe, Pt, and Mo. In yet another example, the metalized film includes one or more metals selected from a group consisting of Ag, Au, Pt, Pd, Ni, and Cu. In yet another example, the first etchant solution includes one or more oxidizing agents. In yet another example, the one or more oxidizing agents are selected from a group consisting of AgNO3, KNO3, NaNO3, Fe(NO3)3, H2O2, Ag2CrO4, HNO3, and KMnO4.
In yet another example, the method further includes etching the semiconductor substrate through at least the exposed portion of the first surface using a second etchant solution, the second etchant solution is different from the first etchant solution. In yet another example, the method further includes washing the semiconductor substrate. In yet another example, the method further includes cleaning the semiconductor substrate after the process for forming a first plurality of nanowires. In yet another example, the method further includes drying the semiconductor substrate after the process for forming a first plurality of nanowires. In yet another example, the semiconductor substrate includes a fourth surface opposite to the first surface and the process for masking at least one or more portions of the one or more second surfaces includes keeping at least a second portion of the fourth surface exposed. In yet another example, the method further includes applying the metalized film to at least the exposed second portion of the fourth surface, etching the semiconductor substrate through at least the exposed second portion of the fourth surface using the first etchant solution, and forming a second plurality of nanowires, each of the second plurality of nanowires including a third end at a fifth surface and a fourth end. The fifth surface is different from the third surface.
Although specific embodiments of the present invention have been described, it will be understood by those of skill in the art that there are other embodiments that are equivalent to the described embodiments. For example, various embodiments and/or examples of the present invention can be combined. Accordingly, it is to be understood that the invention is not to be limited by the specific illustrated embodiments, but only by the scope of the appended claims.
This application claims priority to U.S. Provisional Application No. 61/415,577, filed Nov. 19, 2010, commonly assigned and incorporated by reference herein for all purposes.
Work described herein has been supported, in part, by U.S. Air Force SBIR Contract No. FA8650-10-M-2031. The United States Government may therefore have certain rights in the invention.
Number | Date | Country | |
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61415577 | Nov 2010 | US |