`
`I Brand et a1.
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`[19]
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`1541
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`[75]
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`173]
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`[22]
`[211
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`[521
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`[51]
`[58]
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`[56]
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`MOS SEMICONDUCTOR STRUCTURE
`WITH INCREASED FIELD THRESHOLD
`AND METHOD FOR MAKING THE SAME
`Inventors: Warren L. Brand, Saratoga;
`Farajollah Kashkooli, San Jose, both
`of Calif.
`'
`Signetics Corporation, Sunnyvale,
`Calif.
`Apr. 24, 1972
`Filed:
`Appl. No.: 246,918
`
`Assignee:
`
`us. c1 ................ .. '148/187, 148/188, 11_7/200,
`317/235 B
`1111. c1. ............................................ .. H011 7/44
`Field of Search.... 148/187, 188; 117/200, 118,
`117/229, 215, 47 R; 317/235 B
`
`References Cited
`UNITED STATES PATENTS
`
`3,447,238
`3,345,275
`3,402,081
`
`6/1969 Heynes et a1. ...................... .. 29/590
`10/1967
`Schmidt et al....
`9/1968 Lehman ............................ .. 148/188
`
`[ll]
`[45] Jan. 22, 1974
`
`3,386,163
`3,547,717
`3,560,280
`
`6/1968 Brennemann et al~ ............... .. 29/571
`12/1970 Lindmayer ..................... .. 148/187
`2/1971
`Nishida ............................... .. 156/17
`
`Primary Examiner—l~lyland Bizot
`Assistant Examiner-J. M. Davis
`Attorney, Agent, or Firm—-Paul D. Flehr et al.
`
`ABSTRACT '
`[57]
`An MOS semiconductor structure and method for
`making the same in which a semiconductor wafer is
`treated to form an thin oxide layer having a net
`charge. In a speci?c embodiment a positive net charge
`is introduced into the'oxide layer through introduction
`of chrome ions. Field oxide is then grown over the
`thin oxide layer. The ?eld oxide and thin oxide layers
`are removed from selective portions of the semicon
`ductor wafer. Source and drain diffusions are made
`into the semiconductor wafer and a gate oxide along
`with gate source and drain electrodes are formed. The
`introduction of the positive oxide charge over the ?eld
`region increases the ?eld voltage threshold and per
`mits use of a thinner ?eld oxide.
`4 Claims, 5 Drawing Figures
`
`M++++++++H~
`
`Global Foundaries US v. Godo Kaisha
`Global Ex. 1007
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`Page 1 of 4
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`PATENTED JAN2 21974
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`3,787,251
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`Page 2 of 4
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`Page 2 of 4
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`I
`MOS SEMICONDUCTOR STRUCTURE WITH
`INCREASED FIELD THRESHOLD AND METHOD
`F OR MAKING THE SAME
`
`BACKGROUND OF THE INVENTION
`This invention relates to integrated circuits and more
`speci?cally relates to an integrated circuit which in
`cludes an MOS semiconductor structure with an in
`creased ?eld voltage threshold and a method for mak
`ing the same.
`,
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`3,787,251
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`2
`P-N-P transistor effects ‘caused by the N+ ?eld doping.
`
`Therefore, what is needed is an MOS integrated cir
`cuit having a high ?eld voltage threshold without re
`quiring a very thick ?eld oxide and without requiring
`N+ ?eld doping.
`
`5
`
`Integrated circuit technology for forming integrated
`circuits including a plurality of MOS devices imposes
`some restrictions on the portions of semiconductor wa
`fers between the MOS devices. The area of a semicon
`ductor wafer outside of the source and drain regions
`and the channel of a MOS device is referred to as the
`field region. Generally a relatively thick layer of oxide,
`which is known as ?eld oxide, is deposited on top of the
`surface of the ?eld regions of the integrated circuit.
`Metallization is then formed on top of the ?eld oxide
`with such metal conductor lines running back and forth
`to connect various of the devices together and to make
`external connection to the integrated circuit.
`Taking as an example P-channel type MOS devices,
`such devices comprise P~type source and drain regions
`separated by an N-type channel._A negative voltage is
`supplied to a gate electrode on top of the gate oxide
`overlying the channel and functions to invert the N
`type semiconductor region immediately under the gate
`and connecting the P-type source and drain regions.
`This inversion occurs at a particular value of negative
`voltage applied to the gate electrode which is called the
`threshold voltage.
`In integrated circuits involving a plurality of such P
`channel MOS devices, problems sometimes exist with
`undesired inversion of N-type semiconductor material
`at field regions thereof; that is, at locations between
`devices for example. This occurs because of the volt
`ages present on conductor lines which run overthe
`field oxide. This undesired inversion really creates par
`asitic devices since it can link a P-region in one MOS
`device to a P-region in another MOS device.
`In the prior art two techniques are commonly used to
`prevent such undesired inversion. One of these is to
`form a very thick field oxide layer on MOS integrated
`circuits. Providing such a thick ?eld oxide brings with
`it problems of its own, such as the fact that when the
`field oxide is etched to form the MOS devices, there re
`sults very steep and long slopes of oxide leading down
`to the devices and problems occur in depositing metal
`lization for connecting the MOS devices. Another prior
`art technique comprises doping the outside portion of
`the ?eld with a higher concentration of impurity. Thus
`for P-channel type MOS devices the N-type semicon
`ductor material would be doped with a higher concen'
`tration of N-type impurity. Such doping requires an
`extra masking step however. That is, the portion of the
`N-type semiconductor material forming a channel be
`tween source and drain regions of P-type cannot be
`doped with a higher concentration of N-type impurity
`because this would lead to a very high threshold voltage
`for the MOS device. Therefore, an extra masking step
`is required so as to increase the N-type impurity con
`centration only in the ?eld areas. Where such N+ ?eld
`opening is used, besides'the extra masking step re
`quired, there are also very real problems of lateral
`
`20
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`OBJECTS AND SUMMARY OF THE INVENTION
`It is accordingly an object of this invention to provide
`an MOS integrated circuit and method for making the
`same which exhibits a very high ?eld threshold voltage
`for preventing parasitic linking of MOS devices.
`It is a more speci?c object of this invention to pro
`vide such an MOS integrated circuit structure and
`method without requiring thick ?eld oxide or addi
`tional ?eld doping.
`-
`Brie?y, in accordance with one embodiment of the
`invention, the top surface of a semiconductor wafer is
`treated with an oxidizing solution having ions in solu- I
`tion so that a thin layer of xoide is formed thereon with
`ions trapped in the thin oxide layer. Next, the ?eld
`oxide is deposited or thermally grown over the thin
`layer of oxide and portions of both the ?eld oxide and
`the thin layer of oxide are removed from selected por-v
`tions of the semiconductor wafer. Source and drain re
`gions are formed in the selected portions where the
`oxide layers have been removed. Gate oxide as well as
`gate electrodes and source and drain electrodes are
`then formed. The net charge due to the ions associated
`with the thin oxide layer overlying the ?eld region be
`tween MOS devices raises the threshold voltage of such
`?eld regions.
`
`BRIEF DESCRIPTION- OF THE DRAWINGS
`FIGS. 1 through 5 show various steps in the method
`of constructing an integrated circuit having MOS de
`vices with increased ?eld voltage thresholds.
`In particular, FIG. 1 is a cross-sectional diagram of a
`semiconductor wafer having been treated to form a
`thin oxide layer having a net charge thereon.
`FIG. 2 shows the structure of FIG. 1 after the ?eld
`oxide has been deposited or thermally grown.
`FIG. '3 shows the structure of FIG. 2 after selected
`portions of the oxide layers have been removed.
`FIG. 4 shows the structure of FIG. 3 after source and
`drain diffusions have been made.
`FIG. 5 shows the structure of FIG. 4 after a gate
`oxide has been formed and gate and source and drain
`electrodes have been formed.
`
`DESCRIPTION OF THE PREFERRED
`EMBODIMENTS
`The method of this invention involves treating a
`semiconductor surface with an oxidizing solution hav
`ing ions in solution so that a thin oxide layer is formed
`on the semiconductor surface which has ions therein so
`that the oxide has a net electrical charge. As a speci?c
`example and in accordance with one embodiment of
`the invention, a starting wafer of silicon which is doped
`for example to have an N-type impurity throughout is
`immersed in an oxidizing solution including positive
`ions in solution. One particular solution for treating wa- -
`fers in a manner according to this invention may consist
`.of 12 grams of CrO3, 100 milliliters of deionized H20,
`and 1,000 milliliters of concentrated I-IZSO4. These
`concentrations are not critical. The solution is prefera
`bly maintained at an elevated temperature, something
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`Page 3 of 4
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`4
`vices. Thus when windows are opened by etching
`through the ?eld oxide 13 and oxide layer 12 the oxide
`layer 12 along with the chrome ions retained therein is
`removed from that selective portion of the semicon
`ductor wafer. The positive charges associated with re
`moved layer 12 are completely gone and do not enter
`into or affect the portion of the semiconductor wafer
`11 where the MOS devices are formed. Further, the
`positive chrome ions overlying the ?eld regions of MOS
`integrated circuits have been found to be very stable
`both with temperature variations and time. That is,
`they do not migrate or disburse but remain adjacent to
`the surface of the semiconductor wafer 11 and the ?eld
`regions thereof for contributing a net positive charge
`which is effective to increase the voltage inversion
`threshold for these ?eld regions of the MOS semicon
`ductor wafer 11.
`Whie a speci?c embodiment of the invention has
`been disclosed, it will be obvious to those skilled in the
`art that minor modi?cations and variations may be
`made therein without departing from the true spirit and
`scope of the invention.
`We claim:
`1. A method of making an integrated circuit includ
`ing an MOS semiconductor device for a semiconductor
`wafer having a top and bottom surface comprising the
`steps of treating the top surface with an oxidizing solu
`tion having ions in solution whereby a thin layer of
`oxide is formed thereon with ions trapped in the thin
`oxide layer so that the thin oxide layer has a net charge,
`forming a layer of ?eld oxide over the thin layer of ox
`ide, removing portions of both the layer of ?eld oxide
`and thin layer of oxide from a selected portion of the
`semiconductor wafer top surface, fonning source and
`drain regions in the semiconductor wafer adjacent the
`selective portion of the top surface, forming a gate
`oxide on a part of the selective portion of the wafer top
`surface, forming a gate electrode on the top of the gate
`oxide and forming source and drain electrodes for con
`tacting the source and drain regions.
`2. A method in accordance with claim 1 wherein the
`wafer top surface is treated with an oxidizing solution
`having positive ions in solution to form a thin oxide
`layer having a net positive charge,‘ and wherein the
`semiconductor wafer is of N conductivity type and the
`source and drain regions are formed to have P-type
`conductivity so that P channel MOS devices are
`formed.
`3. A method in accordance with claim 2 wherein the
`positive ions in solution are chrome ions.
`4. A method in accordance with claim 2 wherein the
`oxidizing solution comprises chromic oxide and an acid
`which yields positive chrome ions in solution.
`*
`*
`*
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`*
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`on the order of 160° C for example, and the wafer may
`be left in the solution for a time period of, say 15 min
`utes. The wafers are then removed from the solution,
`rinsed and dried. As an example, the rinsing can be
`with deionised water and the wafer may be blown dry
`in nitrogen. A structure such as shown in cross-section
`in FIG. 1 results wherein the N-type semiconductor
`wafer 11 has a thin layer of oxide 12 thereon with this
`thin layer of oxide including positively charged chrome
`ions so that the thin layer of oxide 12 has a net positive
`charge due to the presence of these chrome ions. This
`thin layer of chrome ion containing oxide 12 is on the
`order of 50 to 60 angstrom units thick.
`After treating the semiconductor wafer 11 in the
`manner described above, fabrication proceeds for
`forming MOS devices in the wafer. Thus the next step
`as shown in FIG. 2 is the growth of a relatively thick
`oxide layer 13, which is referred to as the ?eld oxide,
`on top of the thin layer of oxide 12 which is in turn on
`top of the semiconductor wafer 11. Then through suit
`able photolithographic masking techniques as are well
`known in the art, a portion of the oxide layers are re
`moved. FIG. 3 shows a construction in which the ?eld
`oxide layer 13 and the thin layer 12 have been removed
`from a selective portion of the semiconductor wafer 11
`to form a window 14 therein. It should be noted at this
`juncture that conventional etching techniques are ef
`fective to remove both ?eld oxide layer 13 and the thin
`oxide layer 12 with the chrome ions therein. Next, P+
`type diffusions are made into the semiconductor wafer
`11 to form, for example, the source and drain regions
`16 and 17.
`After the source and drain regions 16 and 17 have
`been formed, a gate oxide 18 is deposited or thermally
`grown on the surface of the semiconductor wafer 11
`along with surface passivating oxide 19 over the source
`and drain regions 16 and 17. Then a gate electrode 21
`is formed on top of the gate oxide 18 and source and
`drain electrodes 22 and 23 are formed which extend
`down and make contact with the P-type source and
`drain regions 16 and 17 respectively. Thus what results
`is an integrated circuit having MOS devices with a
`structure such as shown in FIG. 5. In the structure of
`FIG. 5 the ?eld regions of the semiconductor wafer 11;
`that is, the portions of the semiconductor wafer outside
`of and between various MOS devices, has not only the
`field oxide layer 13 thereon but also has a thin layer of
`oxide 12 which contains the positive chrome ions. The
`net positive charge resulting from the presence of the
`chrome ions increases the threshold voltage of the N
`type semiconductor material in the wafer 11 in these
`field areas.
`I
`It has been found that these chrome ions remain in
`the oxide layer 12 and do not interfere with the opening
`of windows such as window 14 for forming MOS de
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`Page 4 of 4
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