WO2012057603A1

WO2012057603A1 - Isfet device with membrane

Info

Publication number: WO2012057603A1
Application number: PCT/MY2010/000288
Authority: WO
Inventors: Chia Sheng Daniel Bien; Mohd Saman Rahimah; Aishah Mohamad Badaruddin Siti; Mohd Zain Azlina; Ramdzan Buyong Muhamad; Fairuz Amir Mohamad
Original assignee: Mimos Berhad
Priority date: 2010-10-29
Filing date: 2010-11-24
Publication date: 2012-05-03

Abstract

The present invention provides an ISFET sensor device and a method to fabricate the ISFET sensor device with nanostructured membrane which will improve the sensitivity and efficiency of the device. The nanostructures can be in unlimited shape or design, in the form of nanowires, nanorings or nanoparticles, fabricated with the function to increase the sensor sensitivity by increasing the surface area of the membrane exposed to the sample solution or electrolyte. The nanostructured membrane can be formed either by nanofabrication techniques which includes lithographic patterning, pattern transfer, thin film deposition and etching methods or by spin coating of nanomaterials and nanowires using various materials, not limited to, such as, Si₃N₄ [32], polysilicon [34] and metallic nanowires.

Description

Y2010/000288

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ISFET DEVICE WITH MEMBRANE

The present invention relates to an ion sensitive filed effect transistor (ISFET) device with membrane to improve the performance of the ISFET sensor.

BACKGROUND ART

ISFET is used as a sensor device for sensing ion concentrations in a solution via its membrane. The solution is used as the gate electrode and when the ion concentration changes, the current through the transistor will change accordingly as a voltage between the substrate and oxide surfaces arises due to an ions sheath.

Presently, there is a prior art which teaches how to fabricate ISFET structure as such that the external electrical contact to the P+ source and drain regions is made through individual holes etched from the back to the source and drain regions with side wall isolation being provided in the holes and metallization covering its surface of said sidewalls and extending to contact pads on the back of the ISFET.

Another prior art listed the fabrication of ISFET device with planar semiconductor structure which has chemically active, geometrically and spatially very small areas, known as nano-spots that are embedded in the chemically inactive surface. This structure has passivated contact and a chemically inert surface, which is in direct contact with the surrounding medium of fluid or gas.

The present invention is made in view of the prior arts described above where typically a conventional ISFET device is fabricated with planar membrane as the sensing gate and it has been associated with problems of limited ion concentration that can be sensed. Due to this limited exposed area to the ions in the sample to be tested, the sensitivity and efficiency of the device is limited. Also, although there are improvements made by using nano-spots in the ISFET, the invention is only chemically active in the nano region and not in the membrane or structure.

SUMMARY OF INVENTION 010 000288

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The present invention proposes an ISFET sensor and method to fabricate the ISFET sensor device with nanostructured membrane which will improve the sensitivity and efficiency of the device. The nanostructures design of the membrane increase the membrane surface area exposed to the sample solution or electrolyte which improves the sensitivity of the device. The nanostructures on the membrane can be in unlimited shapes of nanowires, nanorings or nanoparticles which are fabricated using silicon based compatible processes.

BRIEF DESCRIPTION OF DRAWINGS

Fig. 1 is a schematic drawing of the ISFET device with nanostructured membrane.

Fig. 2a is a schematic drawing showing the patterning of Si0₂.

Fig. 2b is a schematic drawing showing the deposition of polysilicon.

Fig. 2c is a schematic drawing showing the polysilicon spacer etched for spacer

formation.

Fig. 2d is a schematic drawing showing the removal of Si0₂.

Fig. 2e is a schematic drawing showing the halfway etching of Si₃N₄.

Fig. 2f is a schematic drawing showing the removal of polysilicon.

Fig. 3a is a schematic drawing showing the patterning of poly.

Fig. 3b is a schematic drawing showing the deposition of Si₃N₄.

Fig. 3c is a schematic drawing showing the Si₃N₄ spacer etched for spacer formation.

Fig. 3d is a schematic drawing showing the etching of poly.

DESCRIPTION OF EMBODIMENTS

Hereinafter, the present invention is described in detail.

The invention involves an ISFET sensor device with nanostructured membrane to increase the membrane surface area exposed to the sample solution or electrolyte. The nanostructures can be in the form of nanowires, nanorings or nanoparticles. The nanostructured membrane is fabricated using silicon based compatible processes.

The fabrication of the ISFET device begins with the implantation of the source-drain region on semiconductor substrate [20] such as silicon. This is followed by the 88

3 deposition of an oxide dielectric layer [26] and then the nanostructured membrane formation [28] at the membrane area [22]. The oxide dielectric layer [26] is next to the substrate [20] having source-drain region surface. Nanostructures are formed either by nanofabrication techniques or spin coating of nanomaterials and nanowires. The ISFET device is completed with the metallization at the contact pad area [24] for conductive contact to the source-drain region. Fig. 1 shows the ISFET device fabricated with silicon dioxide (Si0₂) as the oxide insulating layer [26], silicon nitride (Si₃N₄) nanostructures [28] membrane and aluminium as the metal contact [30]. The metal contact is next to oxide dielectric layer at a source-drain region. The gate membrane is next to oxide dielectric layer at another source-drain region. Notice that the nanostructures provide an increased contact area of membrane to increase the sensitivity of the ISFET.

The membrane and membrane nanostructures are common ISFET gate material such as silicon nitride, polysilicon, metal oxides, tantalum pentoxide or hafnium oxide. The membrane nanostructures are in the form of nanowires, nanorings or nanoparticles.

The nanostructured membrane can be fabricated via two options under the nanofabrication techniques, which are the pattern transfer and direct forming methods. In the pattern transfer method, the process begins with the formation of the oxide structures. From the example of ISFET device highlighted in Fig 1 , where the substrate of silicon [20] is deposited with Si0₂ [26] followed by Si₃N₄ [32], a layer of Si0₂ [26] is deposited on the Si₃N₄ [32] where it is lithographically patterned and etched, stopping on the desired location of underlying nanostructures Si₃N₄ [32] as shown in Fig 2a. This is followed by a second stage of silicon based nanostructures formation. A layer of polysilicon [34] is deposited on the patterned Si0₂ [26] as shown in Fig. 2b and then blanket etched to form polysilicon spacers [36] as shown in Fig. 2c. This is followed by the removal of the Si0₂ [26] oxide to form polysilicon nanostructures [38] shown in Fig. 2d. The last stage is the formation of the Si₃N₄ nanostructures [28] where the underlying Si₃N₄ [32] is etched halfway using the polysilicon nanostructures [38] as transfer mask as shown in Fig. 2e and followed by the removal of the polysilicon nanostructures [38], leaving behind the completed Si₃N₄ nanostructures [28] as shown in Fig. 2f. 88

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As for the direct forming method, the process uses the formation of polysilicon [34] structures as template to form nanostructures. From the example of ISFET device highlighted in Fig 1, where the substrate of silicon [20] is deposited with Si0₂ [26] followed by Si₃N₄ [32], a layer of polysilicon [34] is deposited on the Si₃N₄ [32] where it is 5 lithographically patterned and etched, stopping on the desired location of underlying nanostructures Si₃N₄ [34] as shown in Fig 3a. This is followed by a second stage of Si₃N₄ nanostructures formation. A layer of Si₃N₄ [32] is deposited on the patterned polysilicon [34] as shown in Fig. 3b and then blanket etched to form Si₃N₄ spacers [40] as shown in Fig. 3c. This is followed by the removal of the polysilicon [34] to form Si₃N₄ 10 nanostructures [28] shown in Fig. 3d.

Besides Si₃N₄ [32], the nanostructured membrane can also be formed using other material such as polysilicon [34] and metallic nanowires, for example, not limited to, tantalum pentoxide (Ta₂0₅), aluminium oxide (Al₂0₃), WO_x or hafmium oxide (Hf0₂).

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Accordingly, the invention disclosed a method to fabricate an ISFET sensor device with nanostructured membrane which will improve the sensitivity and efficiency of the device. The nanostructures can be in unlimited shape or design, in the form of nanowires, nanorings or nanoparticles that are fabricated using silicon based compatible processes. 0 The nanostructures have a function to increase the sensor sensitivity by increasing the surface area of the membrane exposed to the sample solution or electrolyte. The nanostructured membrane can be formed either by nanofabrication techniques which includes lithographic patterning, pattern transfer, thin film deposition and etching methods or by spin coating of nanomaterials and nanowires. The fabrication options for

25 nanofabrication techniques include pattern transfer method and direct forming method.

This nanostructured membrane can be fabricated using various materials such as polysilicon [34] and metallic nanowires, for example, not limited to, Si₃N₄ [32], Ta₂0₅, Al₂0₃, WO_x or Hf0₂.

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Claims

An ISFET device with membrane, comprising:

a substrate [20] with implanted source-drain region;

an oxide dielectric layer [26] next to the substrate [20] having source-drain region surface;

a metal contact [30] next to oxide dielectric layer [26] at a source-drain region; a gate membrane [32] next to oxide dielectric layer [26] at another source-drain region;

characterized in that,

the membrane has membrane nanostructures [28].

An ISFET device according to claim 1 , wherein the membrane and membrane nanostructures are silicon nitride, polysilicon, metal oxides, tantalum pentoxide or hafnium oxide.

An ISFET device according to claim 1 , wherein the membrane nanostructures are nanowires, nanorings or nanoparticles.

A method of fabricating an ISFET device with membrane characterized in that,

forming membrane nanostructures [28] at the membrane area [22] on top of the oxide dielectric layer with substrate having implanted source-drain region.

A method according to claim 4, wherein forming membrane nanostructures, comprising:

depositing a layer of oxide on top of membrane material;

lithographically patterning and etching the oxide, stopping on the desired location of underlying nanostructure membrane material;

depositing a layer of polysilicon [34] on top of the patterned oxide;

blanket etching the polysilicon [34] to form polysilicon spacers [36];

removing the oxide to form polysilicon structures [38];

etching underlying membrane material layer using the polysilicon structure [38] as transfer mask; and

removing the polysilicon structure [38], leaving behind the formed nanostructures on the membrane.

6. A method according to claim 4, wherein forming membrane nanostructures, comprising:

depositing a layer of polysilicon [34] on top of membrane material;

lithographically patterning and etching the polysilicon [34], stopping on the desired location of underlying membrane material;

depositing a layer of membrane material on top of the patterned polysilicon [34]; blanket etching membrane material to form spacers;

removing the polysilicon [34], leaving behind the formed nanostructures on the membrane.