Micromachined Thermal Mass Flow Sensor With Self-Cleaning Capability And Methods Of Making the Same

Abstract

The current invention generally relates to Micro Electro Mechanical Systems (MEMS) thermal mass flow sensors for measuring the flow rate of a flowing fluid (gas/liquid) and the methods of manufacturing on single crystal silicon wafers. The said mass flow sensors have self-cleaning capability that is achieved via the modulation of the cavity of which the sensing elements locate on the top of the cavity that is made of a silicon nitride film; alternatively the sensing elements are fabricated on top of a binary silicon nitride/conductive polycrystalline silicon film under which is a porous silicon layer selective formed in a silicon substrate. Using polycrystalline silicon or the sensing elements as electrodes, an acoustic wave can be generated across the porous silicon layer which is also used for the thermal isolation of the sensing elements. The vibration or acoustic energy is effective to remove foreign materials deposited on top surface of the sensing elements that ensure the accuracy and enhance repeatability of the thermal mass flow sensing.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention generally relates to thermal mass flow sensors on measuring the flow rate of flowing gas or liquid, more particularly; it concerns mass flow sensors which are made of Micro Electro Mechanical Systems (MEMS) approach and methods of manufacture. The present MEMS flow sensor is built on an active membrane or a porous silicon based device.

The active membrane or the porous silicon device is capable of generating a self-cleaning surface wave, such as ultrasonic acoustic wave emitted from porous silicon, on the active region of sensor surface. With the self-cleaning capability at the time of desire, the sensor itself would be able to work at environments with alien particles or debris from its active region. The sustained cleanness of active area on sensor surface could greatly enhance the flow measuring accuracy and retain its repeatability from calibration.

2. Description of the Related Art

Various micromachined gas and liquid mass flow sensors have been heretofore developed and commercially available on the market. One of the popular mass flow sensors, thermal mass flow sensor, is operated based on the principle of hot-wire anemometry or calorimetry. Compared to MEMS technology, the conventional technologies of mass flow sensors are constrained by the low flow uncertainties, small turn-down ratio on flow rate measurement, and high power consumption. In particular, the conventional thermal mass flow meters often become malfunction in a dirty fluid channel such as the fluid flow with smoke or dust in an electrical industrial environment. The malfunction of the meters lead to interruption of the manufacture and the sensors after liquid or dry cleaning may not have the same performance besides the installation deviations.

The US patents (Philip J. Bohrer and Robert G. Johnson, Flow Sensor, U.S. Pat. No. 4,478,077; Robert E. Higashi, Semiconductor device microstructure, U.S. Pat. No. 4,696,188) teach a typical MEMS type of thermal mass flow sensor generally comprised of a micro-machined membrane which is functioned as thermal isolation purpose to improve the accuracy of device operation. Therein the active region of membrane usually consists of heating elements and sensing elements such as resistance temperature detector (RTD) or thermopiles. However, this type of MEMS thermal flow sensor would have the following limitations:

• (1) The thin film membrane is very fragile to be damaged and cause the device to malfunction frequently in a dusted or smoked fluid.
• (2) The opening slots on the surface of membrane are constructed to block the heat conduction horizontally. However the open slots will also easily trapping the particles that may lead to the malfunction of the sensor.
• (3) The opening slots on membrane will limit the application of flow sensor on liquid measurement because the filled liquid underneath the membrane will reduce the thermal resistance between membrane and the substrate to cause uncertainties.

The U.S. Pat. No. 7,040,160 (Flow Sensor; by Hans Artmann et al.) teaches a thermal flow sensor built on a region having poor heat conductivity of a silicon substrate. The region having poor heat conductivity is made of porous silicon or porous silicon dioxide. However, in the embodiment of this patent, the lateral thermal conductivity between the heater element and sensor components, unlike the current invention, is not totally isolated. The lateral heat conduction through the cover layer in Hans Artmann's invention can significantly reduce the measuring accuracy. Moreover, the location of the ambient temperature sensor to detect the environmental temperature for heater temperature control is either omitted or not specified explicitly in Hans Artmann's invention. To ensure the ambient temperature sensor having good thermal conductivity to the substrate is very crucial to prevent the temperature effect of thermal flow sensor. For the above reason, the ambient temperature sensor should not be disposed on the porous silicon region. A further limitation of the Artmann's approach is that the sensor would not work in a dust or dirty flow fluid as the surface of the sensor would cover by such to cause the malfunction.

It would be desirable, therefore, to provide an apparatus and method whereby the mass flow meter could work robustly in a dirty flow fluid without being disrupted for improved work efficiency. To this end, it would also be desirable that the sensors can perform self-cleaning periodically to maintain the flow meter accuracy and productivity. It is further desirable to have the sensing element of the sensors being well isolated, and ensure the environment temperature detection sensor well functioned.

Self-cleaning usually involved special surface coating (U.S. Pat. Nos. 4,147,845, Article having self-cleaning coating, by A. Nishino et al., and 6,858,284, Surface rendered self-cleaning by hydrophobic structures, and process for their production, by E. Nun et al.). However, in a dirty or smoked fluid flow, modification of the surface structure often can only improve but not prevent from surface sticking of foreign materials. It is known that surface wave would be much stronger and active than merely passive surface coating in cleaning of the surface. But most of the cleaning apparatus involved a complicated system (U.S. Pat. No. 4,007,465, System for self-cleaning ink jet head, K. C. Chaudhary), and may not a simple adaptation for the said flow sensors.

It would be desirable, nonetheless, that a simple flow sensor with a high-performance in flow measurement yet a self-cleaned surface for reliability can be constructed. It is further desirable that the sensors shall be easily manufactured for a mass production. To this end, it is known that porous silicon can emit acoustic wave with strength (Characteristics of thermally induced ultrasonic emission from nanocrystalline porous silicon device under impulse operation, by Y. Watabe et al., Jap. J. Appl. Phys. Vol. 45, 3645-47). Alternative approach of the surface wave can be realized using an active capacitive force generated surface vibration. Such a structure can be simply constructed (U.S. Pat. No. 6,781,735, Fabry-Perot cavity manufactured with bulk micro-machining process applied on supporting substrate, Huang, et al.) Likewise, it is desirable to construct the mass flow sensor with self-cleaned surface by combining the mass flow sensor apparatus and surface acoustic emission or the surface vibration configuration.

SUMMARY OF THE INVENTION

It is therefore an object of the present invention to provide an apparatus and a method of fabricating a MEMS thermal mass flow sensor with the superior performance in flow measurement while maintaining a robust self-cleaned surface. In the present invention, the porous silicon layer shall be modified to form the acoustic surface wave emitter for the self-cleaning capability while functioning as the heat isolation and the robust cushion for the sensing elements. In an alternative approach, the sensing elements shall be fabricated on a membrane below which is a cavity where a capacitive force could be applied such that the vibration at the time of desire shall remove foreign materials deposited on the surface of the sensing elements.

In the present preferred embodiments, the integrated micromachined silicon thermal flow sensors employed the principles of both anemometry and calorimetry on a substrate with the capability of acoustic wave emission or membrane vibration for removal of foreign material on the sensing element surface are depicted. More specifically, the sensing elements of the flow sensors mainly comprise four serpentine-shape thermistors which are made of same thin film materials. One of the thermistors is built as reference thermistor to monitor the ambient temperature while another one of the thermistors is functioned as heater thermistor. In the preferred embodiments, the resistance of reference thermistor is several times higher than the heater's. The heater thermistor is elevated to a constant temperature higher than the ambient temperature. A Wheatstone bridge circuit consisting of the heater and reference thermistors is designed to achieve constant temperature control of heater thermistor. The other two thermistors are disposed to the upstream and downstream of heater thermistor in an either symmetrical or asymmetrical configuration to the center of the heater thermistor. Since the moving fluid continuously carries heat away from the heater thermistor, and thus to change the temperature distribution around the adjacent region of heater thermistor. The temperature difference between the upstream and downstream area of heater thermistor is hence measured by the temperature sensing elements. The output signal is normally recorded using a Wheatstone bridge circuit, in which the downstream and upstream sensing elements comprise two of its four branches. Various materials with high TCR (temperature coefficient of resistance) property such as Pt, Au, SiC, and TaN could be the candidates for temperature sensing elements.

In the prior arts using thermistors as the sensing elements require a heat isolation that is achieved via forming a cavity beneath a suspending membrane on which the thermistors are deposited. The cavity was formed on a silicon substrate and it was processed usually by wet chemical etch such that the bottom of the cavity is an upside down pyramid due to preferable etch of the atomic structure of the silicon. The thermal conductivity property of air is about 0.024 W/m/K at ambient. In the present disclosed invention, the suspending membrane was formed by a silicon nitride film of 0.3˜1.5 μm on top of a conductive polycrystalline silicon film of 0.3˜0.5 μm that serves as one of the electrode of the said capacitor. The cavity underneath the membrane shall be formed via a standard spin-on glass (SOG) process combining with the surface micromachining using the technology previously disclosed by the same assignee (U.S. Pat. No. 6,620,712, Defined sacrificial region via ion implantation for micro-opto-electro-mechanical system applications, Huang et al.), such that the cavity bottom surface shall be flat and another capacitor surface can be formed by adding a silicon oxide or silicon nitride film of 0.3˜0.5 μm first on the silicon substrate and the conductive polycrystalline silicon thin film of 0.3˜0.5 μm on top of the said silicon oxide or silicon nitride. These two polycrystalline silicon films are preferably formed by low pressure chemical vapor deposition (LPCVD) such that the proper stress can be managed making the both surface of the said capacitor flat. These two polycrystalline silicon films could become conductive by doping them with either n- or p-type with dopants such as phosphors or boron. Thereby they shall serve as the electrodes of the said capacitor to drive the vibration of the membrane. The vibration of the membrane can be achieved by applying an alternative voltage or pulse to the said capacitor with a desired frequency that shall have the strength to remove foreign materials on the surface of the sensing elements.

In another approach, and yet would be a preferable embodiment, that a porous silicon device capable of emitting acoustic wave was fabricated beneath the membrane on which the sensing elements are disposed. A pattern of porous silicon is produced in the surface of a p-type silicon substrate by performing an electrochemical anodization of silicon in a hydrofluoric acid (HF) electrolyte. The porous silicon in current invention is generated by a selective formation method. The porous silicon with a porosity of porous silicon of 50% is known to have a low thermal conductivity of ˜0.2 W/m/K that is about 700 times lower than that for the substrate silicon (On the optical and thermal properties of porous silicon, by J. M. Devi et al., NDT.net Vol. 11, No. 6 2006). Whereby use of porous silicon for the purpose of thermal isolation become advantageous.

Different from the other thermistors in the device, since the reference thermistor needs good thermal conduction to the substrate, therefore any porous silicon layer underneath the reference thermistor is unfavorable. The selective formation method can greatly reduce the chance for metal interconnection breakage during device fabrication process. This is because a very abrupt and deep recess, especially in the case of 100˜200 μm thickness of porous silicon, could be created for patterning the porous silicon through dry/wet etching afterwards. On the other hand, the selective formation of porous silicon would be able to avoid the generation of such abrupt recess on wafer surface.

In the disclosed invention, silicon nitride is applied as the hard mask for the selective formation of porous silicon. The characters that determine the porosity of porous silicon layers including the substrate doping level, anodizing current density, and the concentration of hydrofluoric acid (HF) electrolyte. In general situation, the porosity of porous silicon is increased with increasing current density, and it is reversely proportional to the substrate doping level and HF electrolyte concentration. The LPCVD silicon nitride is most preferred than the films obtained from other deposition methods since in this method its etching resistance to HF acid is upon highest. As the reference thermistor is aimed to measure the environment temperature, hence it needs good thermal conductivity to the substrate bottom. Since the insulation layer (silicon nitride) underneath the reference thermistor is no longer used as part of the membrane structure, therefore it could be as thin as possible. It is thus to increase the thermal conductivity of reference thermistor to substrate, which could facilitate to greatly reduce the temperature effect and enhance the thermal response of device.

Referring to the papers of Asamura et al. (Intensifying Thermally Induced Ultrasound Emission, Proc. 19th Sensor Symposium IEEJ, Tokyo, 2002) and the paper of Watabe et al. an ultrasonic acoustic wave is feasible to produce from the flow sensor structure of current invention as a self-cleaning energy source. The thermally induced ultrasound emission device is normally including three parts in the structure: (1) a heat conductive base, such as silicon wafer (2) heat insulation layer: such as porous silicon (3) electrically conductive film: such as platinum (Pt). The ultrasonic wave is induced by the electrical pulse applied on the conductive film. The relationship between the ultrasound pressure amplitude (P) and the surface temperature fluctuation (ΔT_Peak) could be represented as

$P=\Delta T_{\mathrm{Peak}}\times \frac{A\sqrt{2\pi /t}}{K\left(x\right)},$

$K\left(x\right)=\frac{S}{2\mathrm{vtx}},A=\sqrt{\frac{{\mathrm{\gamma \alpha }}_A}{C_A}}\frac{P_A}{{\mathrm{vT}}_A}$

where the t and S are the input pulse width and the area corresponding to the ultrasonic emission. The constants v, α_A, C_A, P_A, and T_A are the sound velocity, the thermal conductivity, the heat capacity per unit volume of air, the atmospheric pressure, and the room temperature, respectively, and γ is the specific heat ratio as c_p/c_v≈1.4.

Another advantage gained from the porous silicon embodiment is the process simplification for device fabrication. That includes the deletion of process steps on front side protection layer deposition and removal before and after the backside bulk etching step. Avoiding the vulnerable and fragile membrane structure also benefits the device from dicing process since the yield and throughput can be significantly increased. It is apparent that the damage and failure situations for sensor during handling and operation had been cut down to a minimum base.

All the thermistors on device are encapsulated with a 0.3˜0.5 μm thick dielectric film as passivation layer. Above this dielectric film, a thin layer of fluorocarbon coating is deposited onto whole device to make the device surface become hydrophobic and low surface energy. The thin hydrophobic fluorocarbon coating is designed to prevent the stiction issues of alien particles or debris or liquid materials onto device surface, which could significantly degrade the device operation.

BRIEF DESCRIPTIONS OF THE DRAWINGS

FIG. 1 Illustrates the top view of a preferred sensor topology.

FIG. 2 Illustrates a MEMS thermal mass flow sensor of prior art.

FIG. 3 Illustrates the present invention of a thermal mass flow sensor fabricated on a cavity that can generate vibration via capacitive force for self-cleaning of surface foreign materials at a time of desire.

FIG. 4 Illustrates the basic structure of a thermally induced ultrasound emitter from porous silicon on silicon substrate.

FIG. 5 Illustrates a process for forming a new type of MEMS thermal mass flow sensor according to the preferred embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIG. 1 illustrates a top view of preferred sensor topology. The reference thermistor is aimed to measure the ambient temperature. The ambient temperature signal provides the feedback to a closed-loop heater thermistor control circuit. The control circuit is designed to keep the heater temperature constantly above the ambient temperature. The upstream and downstream thermistors besides the heater thermistor are worked as temperature sensing elements.

The working principle behind the fluid speed measurement in a fluid passage is primarily based on anemometry and calorimetry. Since the heater thermistor is operating under constant temperature mode, two major embodiments in the present invention are included:

• • (1) The heater thermistor and reference thermistor are working together as an MEMS constant temperature mode anemometer, which could measure a large dynamic flow rate.
  • (2) The heater thermistor and the two downstream/upstream thermistors comprise a calorimetric mode flow sensor, which could measure a lower dynamic flow rate with a better accuracy than feature (1).
  • (3) Consequently, combined the features (1) and (2), a large dynamic range (high turn-down ratio) flow sensor can be accomplished.

The open slots on the porous silicon island are designed to isolate the lateral heat conduction through the passivation dielectric films which is crucial to the measurement accuracy.

FIG. 2 depicts a side view for a pictorial illustration of a conventional MEMS thermal flow sensor (prior art). A suspending membrane structure is illustrated.

FIG. 3( a) through (h) illustrates the detailed micro-fabrication process of one of the preferred embodiments. Referring to FIG. 3(a), a silicon nitride film, 210, of 0.1˜0.3 μm is first deposited on silicon substrate, 200, preferably using LPCVD. A conductive (doped with either phosphorus or boron) polycrystalline silicon film, 220, with a thickness of 0.1˜0.5 μm is subsequently deposition using LPCVD process followed by the deposition of metal electrode, 240.

A standard spin-on glass (SOG) process is then followed to construct the cavity support, 230, with a thickness preferably in the range of 0.8˜5.0 μm (FIG. 3(b)).

In view of FIG. 3 (c), doping the glass either using ion implantation or conventional doping process to define the sacrificial area, 250 and 260, can significantly enhance the etch rate of the glass using hydrofluoric acid. The detailed doping process can be found in U.S. Pat. No. 6,620,712 as previously described.

The upper conductive layer, 280, of the said cavity is preferably made by polycrystalline silicon film, 280, with a thickness of 0.1˜0.5 μm. This is followed by the deposition of the electrode 245. (FIG. 3(d))

In view of FIG. 3(e), the sensor membrane is preferably made by LPCVD silicon nitride film, 290, with a thickness of 0.8˜2.0 μm.

Subsequently is the process of making mass flow sensors for which the detailed process can be found in US Pat. Pub. App. No. 2007-0011867. As shown in FIG. 3(f), it includes deposition of sensing elements 350, fabrication of reference thermistor 320, deposition of bonding pads 330, etch open for pads opening 340 as well as open of isolation openings 310, 312, 314, and 316.

In view of FIG. 3(g), either dry or wet etch can be performed to open the path to the upper capacitor cavity electrodes 245

Finally, as shown in FIG. 3(h), hydrofluoric acid etch of the sacrificial glass will remove the glass in the defined cavity and open the path to the lower electrode, 240, and consequently conclude the fabrication process.

In this preferred embodiments, the thermal mass flow sensing elements are well isolated with the air while the voltage applied to the upper and lower electrodes of the cavity shall excite the vibration modes of the cavity causing the membrane to vibrate such that any foreign materials on the surface could be removed.

FIG. 4 illustrates the basic structure of a thermally induced ultrasound emitter from porous silicon 410 on silicon substrate 400. Due to the excellent thermal insulation property of porous silicon 410, temperature fluctuations induced by electrical high frequency pulse signals at the top surface are promptly transmitted into air as sound pressure. The electrical pulse signals are applied to the metal heater layer 420 through the electrodes 430. Since there are no moving parts in the ultrasonic emitter, therefore it would not affect the measurement accuracy and repeatability of flow sensor.

From FIG. 5 (a) through FIG. 5 (i), the figures demonstrate a process for forming a new type of MEMS thermal flow sensor with self-cleaning capability according to the preferred embodiment of the present invention.

Referring to FIG. 5 (a), a LPCVD silicon nitride layer 120 is formed on both sides of the silicon substrate 100. After the bottom side of the nitride layer is removed, an aluminum layer 110 is deposited thereafter on the bottom of the wafer as ohmic contact electrode for electrochemical anodization.

In view of FIG. 5 (b), the first mask is used to pattern the silicon nitride as the open window for selective formation of porous silicon. The silicon wafer is then placed in an anodizing chamber filled with prepared electrolyte. The electrolyte is a mixture of hydrofluoric acid (HF), nitric acid (HNO₃), and isopropyl alcohol (IPA) with certain ratio. In order to achieve high porosity (higher than 50%) of porous silicon, a p-type silicon wafer with resistivity of 1˜10 Ω·cm is preferred. The current density is set up in the range of 50 to 150 mA/cm². It would take about 30 min of anodization to attain approximate 200 μm thick of porous silicon as shown in the 130 region of FIG. 5 (c).

After stripping away the front side silicon nitride and the bottom side aluminum (as shown in FIG. 5 (d)), a conductive polycrystalline silicon film, 140, with a thickness of 0.3˜0.8 μm is deposited via LPCVD and doped with either phosphorus or boron in the front side of wafer followed by deposition of electrode, 150, formed by aluminum or gold or platinum (FIG. 5 (e)).

In view of FIG. 5 (f), a silicon nitride film, 160, with a thickness of 0.2˜0.8 μm is deposited on top of the polycrystalline silicon film. The heater thermistor 170, temperature sensing thermistors 180 and 185, and reference thermistor 195 are all formed and patterned by the film deposition and second photo mask process. The preferred thermistor materials are those with high temperature coefficient of resistance (TCR) such as platinum (Pt), gold (Au), silicon carbide (SiC), and tantalum nitride (TaN). Subsequently, a third masking and patterning procedure is performed to remove the portions of interconnection metal layer and form the interconnection circuit and the bonding pads 190. Subsequently referring to FIG. 5(g), a passivation layer 200, said dielectric thin film, for the overall processed substrate structure is deposited.

In the FIG. 5 (h), a patterning procedure is performed to define the open-slots, 205, in the membrane as well as the opening in the bonding pads, 208.

In the last step of process (see FIG. 5 (i)), a very thin fluorocarbon coating, 210, (5˜15 nm) such as Teflon or Teflon-like film is deposited onto the surface of whole device by plasma enhanced deposition process. Since this thin passivation coating is hydrophobic and with low surface energy property, hence it could significantly reduce the sensor surface sticking issues of alien particles and debris within the flow media. This coating layer is especially efficient to prevent the sticking of dust and moisture mixture onto device surface. Since the fluorocarbon film has low thermal conductive property, hence it should be kept as thin as possible to remain the original functionality of device and to avoid the difficulties for wire bonding. Finally, dry or wet etch to open the path, 220, to the electrode that is used to generate acoustic wave is performed to conclude the fabrication.

Alternatively applying a high frequency pulse signal (about 1 μs width) at a sampling time of 20 msec to the heater and sensor thermistors, an ultrasonic wave with a ˜1000 Pa acoustic pressure could also be generated to clean up the active surface region at a time of desire.

While the invention has been described in terms of what are presently considered to be the most practical and preferred embodiments, it is to be understood that the invention need not be limited to the disclosed embodiment. On the contrary, it is intended to cover various modifications and similar arrangements included within the spirit and scope of the appended claims which are to be accorded with the broadest interpretation so as to encompass all such modifications and similar structures. Therefore, the above description and illustration should not be taken as limiting the scope of the present invention which is defined by the appended claims.

Claims

1. A MEMS thermal mass flow sensor comprising: a heater thermistor, a reference thermistor and two temperature sensing thermistors disposed on a silicon substrate.

2. The MEMS thermal mass flow sensor of claim 1 wherein: the sensing elements are fabricated on a membrane under which is a cavity that can be modulated by the capacitive force;

3. The MEMS thermal mass flow sensors of claim 2 wherein: the membrane providing the house for the sensing elements is made of LPCVD silicon nitride of 0.3˜1.2 μm;

4. The MEMS thermal mass flow sensors of claim 2 wherein: a self-cleaning capability is achieved via the modulation of the cavity underneath the membrane on which the sensing elements are fabricated. The modulation generates vibrations that are effective to remove foreign materials deposited on the top surfaces of the sensing elements;

5. The MEMS thermal mass flow sensors of claim 2 wherein: a self-cleaning capability is achieved via the modulation of the cavity underneath the membrane on which the sensing elements are fabricated. The modulation of the cavity can be performed by applying a pulse voltage with a desired frequency or a periodic wave function with desired amplitude.

6. The MEMS thermal mass flow sensor of claim 1 wherein: a selectively formed porous silicon island is provided on silicon substrate as thermally isolated area.

7. The MEMS thermal mass flow sensor of claim 6 wherein: a first masking and patterning procedure is performed to define the silicon nitride window for selective formation of porous silicon.

8. The MEMS thermal mass flow sensor of claim 6 wherein: said the thickness of the porous silicon island be in the range from 100 to 200 μm.

9. The MEMS thermal mass flow sensor of claim 6 wherein: said the porosity of porous silicon island be higher than 50%.

10. The MEMS thermal mass flow sensor of claim 1 wherein: a thin layer of silicon nitride deposition is performed on top of the porous silicon layer as electrical insulation layer.

11. The MEMS thermal mass flow sensor of claim 1 wherein: a first high temperature coefficient of resistance (TCR) layer is formed on said silicon substrate

12. The MEMS thermal mass flow sensor of claim 1 wherein: a second masking and patterning procedure is performed to define thermistors including heater, temperature sensing thermistors on said the top of porous silicon island.

13. The MEMS thermal mass flow sensor of claim 1 wherein: said reference thermistor is disposed on the area of substrate other than the porous silicon island.

14. The MEMS thermal mass flow sensor of claim 1 wherein: successively an interconnection layer is formed on said substrate and a third masking and patterning procedure is performed to remove portions of said metal layer to define interconnection and bonding pads region.

15. The MEMS thermal mass flow sensor of claim 1 wherein: a passivation layer is formed and a fourth masking and patterning procedure is performed to remove portions of said passivation for forming a contact hole on said bonding pads and the open-slots on said the perimeters of porous silicon island.

16. The MEMS thermal mass flow sensor of claim 15 wherein: said the open slots around the said porous silicon island are to isolate the lateral heat conduction from heater thermistor to sensor thermistors.

17. The process according to claim 11, wherein said the layer is formed of platinum, gold, silicon carbide, tantalum nitride etc.

18. The MEMS thermal mass flow sensor of claim 12 wherein: said the temperature sensing thermistors further includes an upstream sensing thermistor and a downstream thermistor disposed on upstream and downstream locations relative to said heater on said thermally-isolated porous silicon island.

19. The MEMS thermal mass flow sensor of claim 12 further comprising: a reference resistor disposed on said substrate wherein said reference thermistor having a resistance ranging from three to twenty-five times a resistance of said sensing thermistor.

20. The MEMS thermal mass flow sensor of claim 18 wherein: said the temperature sensing thermistors disposed on the upstream and downstream locations of heater thermistor could be arranged in a symmetrical or nonsymmetrical configuration related to the center of heater thermistor.

21. The MEMS thermal mass flow sensor of claim 4 and claim 5 wherein: said self-cleaning feature is realized by ultrasonic energy agitation generated from a thermally induced ultrasonic acoustic wave emitter.

22. The MEMS thermal mass flow sensor of claim 21 wherein: a selectively formed porous silicon island is formed by electrochemical anodization as a thermally isolation area.

23. The MEMS thermal mass flow sensor of claim 22 wherein: said porous silicon with a top dielectric film and the top thermistors formed an ultrasonic acoustic wave emitter.

24. The MEMS thermal mass flow sensor of claim 23 wherein: said the ultrasonic acoustic wave emitter be used to clean up the sensor surface active region in a periodical cycle base.

25. The MEMS thermal mass flow sensor of claim 24 wherein: said the thickness of the porous silicon island be in the range from 100 to 200 um.

26. The MEMS thermal mass flow sensor of claim 22 wherein: said the porosity of porous silicon island be higher than 50%.

27. The MEMS thermal mass flow sensor of claim 1 further comprising: a thin fluorocarbon passivation coating on top surface of whole device by plasma enhanced deposition process is to eliminate the sticking issue of alien particles and debris, particularly, the mixture of dust and moisture.

28. The process according to claim 27, wherein said the thin passivation coating is formed and preferred to be hydrophobic and low surface energy with materials such as polymer, Teflon or Teflon-like films.