CN102864410A - Preparation method of high dielectric constant gate dielectric lanthanum titanium oxide amorphous film - Google Patents

Preparation method of high dielectric constant gate dielectric lanthanum titanium oxide amorphous film Download PDF

Info

Publication number
CN102864410A
CN102864410A CN2012103189798A CN201210318979A CN102864410A CN 102864410 A CN102864410 A CN 102864410A CN 2012103189798 A CN2012103189798 A CN 2012103189798A CN 201210318979 A CN201210318979 A CN 201210318979A CN 102864410 A CN102864410 A CN 102864410A
Authority
CN
China
Prior art keywords
titanium oxide
amorphous film
lanthanum
noncrystal membrane
lanthanum titanium
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Pending
Application number
CN2012103189798A
Other languages
Chinese (zh)
Inventor
樊慧庆
杨陈
***
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Northwestern Polytechnical University
Original Assignee
Northwestern Polytechnical University
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Northwestern Polytechnical University filed Critical Northwestern Polytechnical University
Priority to CN2012103189798A priority Critical patent/CN102864410A/en
Publication of CN102864410A publication Critical patent/CN102864410A/en
Pending legal-status Critical Current

Links

Images

Landscapes

  • Insulated Gate Type Field-Effect Transistor (AREA)

Abstract

The invention discloses a preparation method of a high dielectric constant gate dielectric lanthanum titanium oxide amorphous film, for solving the technical problem that the leakage current density of the lanthanum titanium oxide amorphous film prepared by the existing method is high. According to the technical scheme, LaTiO3.5 particles are used as the coating material for evaporation, p-type Si(100) is used as a substrate; after the substrate is washed, a heating system is used to heat and evaporate the substrate in a vacuum chamber, wherein the temperature is kept at 100-250 DEG C, the evaporation time is 1-6min, the electronic gun beam is 70-90mA, the vacuum degree of the vacuum chamber is less than 3*10<-3>Pa, and O2 of which the purity is 99.99% is used as a reaction gas in the evaporation process; a deposited lanthanum titanium oxide amorphous film is obtained; and rapid annealing is performed on the deposited lanthanum titanium oxide amorphous film at 700-900 DEG C for 1-5min to obtain the lanthanum titanium oxide amorphous film. By optimizing the formula and technology of the lanthanum titanium oxide amorphous film, the lanthanum titanium oxide amorphous film with low leakage current density and high dielectric constant is obtained. The prepared lanthanum titanium oxide amorphous film has low leakage current density which is reduced from 10<-6>A/cm<2> in the background technology to 6.5*10<-7>A/cm<2>.

Description

The preparation method of grid medium with high dielectric lanthanum titanyl noncrystal membrane
Technical field
The invention belongs to the function ceramics field, relate to a kind of preparation method of lanthanum titanyl noncrystal membrane, particularly relate to a kind of preparation method of grid medium with high dielectric lanthanum titanyl noncrystal membrane.
Background technology
Along with the widespread use of integrated components and parts in microelectronics, moderate in the urgent need to specific inductivity under a kind of room temperature condition, leakage current is little, have simultaneously higher voltage breakdown and the functional materials of less equivalent gate oxide thickness, lanthanum titanyl noncrystal membrane is considered to a kind of candidate material that gets a good chance of.The more high k gate insulation dielectric material that conducts a research both at home and abroad at present mainly is metal oxide, such as TiO 2, ZrO 2, HfO 2, Er 2O 3, Ta 2O 5, Y 2O 3, Al 2O 3, Gd 2O 3, La 2O 3And silicate (M-Si-O, M=Zr, Hf, La, Gd etc., aluminate (M-Al-O, M=Zr, Hf, La etc.).But the specific inductivity of these materials and leakage current can not satisfy the requirement of instrument simultaneously.
Document " M.Li, Z.Zhang, S.A.Campbell et al.Electrical and material characterizations of high-permittivity Hf xTi 1-xO 2Gate insulatorsa.Journal of Applied Physics.2005,98:054506 " a kind of preparation method of lanthanum titanyl noncrystal membrane disclosed; and the method adopts traditional method for manufacturing thin film to prepare lanthanum titanyl noncrystal membrane; still, the leakage current density (~10 of prepared lanthanum titanyl noncrystal membrane -6) also undesirable.
Summary of the invention
For the large deficiency of leakage current density of the lanthanum titanyl noncrystal membrane that overcomes the preparation of existing method, the invention provides a kind of preparation method of grid medium with high dielectric lanthanum titanyl noncrystal membrane.The method can obtain the lanthanum titanyl noncrystal membrane that leakage current density is little, specific inductivity is high by optimizing the composition and engineering of lanthanum titanyl noncrystal membrane.
The technical solution adopted for the present invention to solve the technical problems is: a kind of preparation method of grid medium with high dielectric lanthanum titanyl noncrystal membrane is characterized in may further comprise the steps:
(a) with purity be 99.99% LaTiO 3.5Particle is as the coating materials of evaporation, and substrate adopts p-type Si (100);
(b) after substrate thoroughly cleans, in vacuum chamber, with heating system substrate is carried out heating evaporation, make its temperature remain on 100~250 ° of C.Evaporation time is 1~6min, and electron beam gun line size is 70~90mA.Vacuum tightness is less than 3 * 10 in the vacuum chamber -3Pa in the evaporative process, uses the O of purity 99.99% 2As reactant gases.Obtain the lanthanum titanyl noncrystal membrane of deposited.
(c) the lanthanum titanyl noncrystal membrane of deposited obtains lanthanum titanyl noncrystal membrane at 700~900 ° of C short annealing 1~5min.
Described LaTiO 3.5The diameter of particle is 2~3mm.
The diameter of described substrate is 75mm.
The resistivity of described p-type Si (100) is 2~10 Ω cm.
The invention has the beneficial effects as follows: owing to by optimizing the composition and engineering of lanthanum titanyl noncrystal membrane, obtain the lanthanum titanyl noncrystal membrane that leakage current density is little, specific inductivity is high.The leakage current density of prepared lanthanum titanyl noncrystal membrane by background technology~10 -6A/cm 2Be reduced to~6.5 * 10 -7A/cm 2Specific inductivity has reached 19.1 simultaneously, has kept higher level.
Below in conjunction with drawings and Examples the present invention is elaborated.
Description of drawings
Fig. 1 is the XRD figure spectrum of four prepared lanthanum titanyls of embodiment of the inventive method noncrystal membrane under aerobic and oxygen free condition.
Fig. 2 be four prepared lanthanum titanyls of embodiment of the inventive method noncrystal membrane under aerobic and oxygen free condition electric current with the curve of voltage change.
Fig. 3 is the time dependent curves of the inventive method embodiment 2 prepared lanthanum titanyl noncrystal membrane deposited voltage breakdowns, and voltage breakdown is 22.4V.
Fig. 4 is the time dependent curve of voltage breakdown that the inventive method embodiment 3 prepared lanthanum titanyl noncrystal membranes record after annealed, and voltage breakdown is 54.5V behind the short annealing 1min.
Fig. 5 is the time dependent curve of voltage breakdown that the inventive method embodiment 3 prepared lanthanum titanyl noncrystal membranes record after annealed, and voltage breakdown is reduced to 8.7V behind the short annealing 5min.
Embodiment
Following examples are with reference to Fig. 1~5.
Embodiment 1, and weighing purity is 99.99% LaTiO 3.5Particle is as coating materials, LaTiO 3.5Granular size is 2-3mm.Adopt diameter be the p-type Si (100) of 75mm as substrate, its resistivity is 2-10 Ω cm, thickness is 0.5mm.After substrate thoroughly cleans up, put into rapidly vacuum chamber, with heating system substrate is heated, make its temperature remain on 100 ° of C.Base vacuum is less than 3 * 10 before the evaporation -3Pa in the evaporative process, in order to obtain higher oxygen level, uses the O of purity 99.99% 2As reactant gases.Evaporation time is 6min, and electron beam gun line size is 70mA, obtains the lanthanum titanyl noncrystal membrane of deposited.The film of deposited obtains lanthanum titanyl noncrystal membrane at 700 ° of C short annealing 5min.
Use XRD that the film phase structure is analyzed; Use XPS that the composition of film is analyzed; And adopt electric impedance analyzer and semiconductor analysis instrument test platform that dielectric properties and the I-V characteristic of film are tested.The XRD figure spectrum that obtains after the annealing when curve a is 700 ° of C among Fig. 1 can be found out for still keeping amorphous structure.Fig. 2 can find out that for the changing conditions with bias voltage of gained leakage current density under the rear different oxygen atmosphere conditions of annealing leakage current density reaches 5.5 * 10 under the oxygen free condition -5A/cm 2
Embodiment 2, and weighing purity is 99.99% LaTiO 3.5Particle is as coating materials, LaTiO 3.5Granular size is 2-3mm.Adopt diameter be the p-type Si (100) of 75mm as substrate, its resistivity is 2-10 Ω cm, thickness is 0.5mm.After substrate thoroughly cleans up, put into rapidly vacuum chamber, with heating system substrate is heated, make its temperature remain on 150 ° of C.Base vacuum is less than 3 * 10 before the evaporation -3Pa in the evaporative process, in order to obtain higher oxygen level, uses the O of purity 99.99% 2As reactant gases.Evaporation time is 4min, and electron beam gun line size is 80mA, obtains the lanthanum titanyl noncrystal membrane of deposited.The film of deposited obtains lanthanum titanyl noncrystal membrane at 750 ° of C short annealing 4min.
Use XRD and SEM that film phase structure and appearance structure are analyzed; Use XPS that the composition of film is analyzed; And adopt electric impedance analyzer and semiconductor analysis instrument test platform that dielectric properties and the I-V characteristic of film are measured.Fig. 2 can find out that for the changing conditions with bias voltage of gained leakage current density under the rear different oxygen atmosphere conditions of annealing leakage current density reaches 6.5 * 10 under the aerobic conditions -7A/cm 2Under the aerobic conditions annealing after voltage breakdown change curve as shown in Figure 3, Fig. 3 represents that the deposited voltage breakdown of lanthanum titanyl noncrystal membrane is 22.4V.
Embodiment 3, and weighing purity is 99.99% LaTiO 3.5Particle is as coating materials, LaTiO 3.5Granular size is 2-3mm.Adopt diameter be the p-type Si (100) of 75mm as substrate, its resistivity is 2-10 Ω cm, thickness is 0.5mm.After substrate thoroughly cleans up, put into rapidly vacuum chamber, with heating system substrate is heated, make its temperature remain on 200 ° of C.Base vacuum is less than 3 * 10 before the evaporation -3Pa in the evaporative process, in order to obtain higher oxygen level, uses the O of purity 99.99% 2As reactant gases.Evaporation time is 2min, and electron beam gun line size is 85mA, obtains the lanthanum titanyl noncrystal membrane of deposited.The film of deposited obtains lanthanum titanyl noncrystal membrane at 800 ° of C short annealing 2min.
Use XRD and SEM that film phase structure and appearance structure are analyzed; Use XPS that the composition of film is analyzed; And adopt electric impedance analyzer and semiconductor analysis instrument test platform that dielectric properties and the I-V characteristic of film are measured.The XRD figure spectrum that obtains after the annealing when curve b is 800 ° of C among Fig. 1 can find out that film begins to change to crystalline state from non-crystalline state.Under the aerobic conditions after the annealing change curve of voltage breakdown as shown in Figure 4, Fig. 4 represents that voltage breakdown is 54.5V behind the lanthanum titanyl noncrystal membrane short annealing 1min.
Embodiment 4, and weighing purity is 99.99% LaTiO 3.5Particle is as coating materials, LaTiO 3.5Granular size is 2-3mm.Adopt diameter be the p-type Si (100) of 75mm as substrate, its resistivity is 2-10 Ω cm, thickness is 0.5mm.After substrate thoroughly cleans up, put into rapidly vacuum chamber, with heating system substrate is heated, make its temperature remain on 250 ° of C.Base vacuum is less than 3 * 10 before the evaporation -3Pa in the evaporative process, in order to obtain higher oxygen level, uses the O of purity 99.99% 2As reactant gases.Evaporation time is 1min, and electron beam gun line size is 90mA, obtains the lanthanum titanyl noncrystal membrane of deposited.The film of deposited obtains lanthanum titanyl noncrystal membrane at 900 ° of C short annealing 1min.
Use XRD and SEM that film phase structure and appearance structure are analyzed; Use XPS that the composition of film is analyzed; And adopt electric impedance analyzer and semiconductor analysis instrument test platform that dielectric properties and the I-V characteristic of film are measured.The XRD figure spectrum that obtains after the annealing when curve c is 900 ° of C among Fig. 1 can find out that for diffraction peak is more obvious, film begins to change to crystalline state from non-crystalline state.Under the aerobic conditions annealing after voltage breakdown change curve as shown in Figure 5, voltage breakdown was reduced to 8.7V after Fig. 5 represented lanthanum titanyl noncrystal membrane short annealing 5min.
In a word, the present invention has prepared lanthanum titanyl noncrystal membrane by traditional thin film preparation process, and through suitable oxygen atmosphere control and suitable temperature control, film keeps lower leakage current density (~6.5 * 10 under aerobic conditions -7A/cm 2) and higher specific inductivity (19.1).Therefore lanthanum titanyl noncrystal membrane of the present invention can well satisfy the service requirements of storer and integrated component, and its prescription and preparation method are fit to industrialization promotion and production in enormous quantities.

Claims (4)

1. the preparation method of a grid medium with high dielectric lanthanum titanyl noncrystal membrane is characterized in that may further comprise the steps:
(a) with purity be 99.99% LaTiO 3.5Particle is as the coating materials of evaporation, and substrate adopts p-type Si (100);
(b) after substrate thoroughly cleans, in vacuum chamber, with heating system substrate is carried out heating evaporation, make its temperature remain on 100~250 ° of C; Evaporation time is 1~6min, and electron beam gun line size is 70~90mA; Vacuum tightness is less than 3 * 10 in the vacuum chamber -3Pa in the evaporative process, uses the O of purity 99.99% 2As reactant gases; Obtain the lanthanum titanyl noncrystal membrane of deposited;
(c) the lanthanum titanyl noncrystal membrane of deposited obtains lanthanum titanyl noncrystal membrane at 700~900 ° of C short annealing 1~5min.
2. the preparation method of grid medium with high dielectric lanthanum titanyl noncrystal membrane according to claim 1 is characterized in that: described LaTiO 3.5The diameter of particle is 2~3mm.
3. the preparation method of grid medium with high dielectric lanthanum titanyl noncrystal membrane according to claim 1, it is characterized in that: the diameter of described substrate is 75mm.
4. the preparation method of grid medium with high dielectric lanthanum titanyl noncrystal membrane according to claim 1, it is characterized in that: the resistivity of described p-type Si (100) is 2~10 Ω cm.
CN2012103189798A 2012-08-31 2012-08-31 Preparation method of high dielectric constant gate dielectric lanthanum titanium oxide amorphous film Pending CN102864410A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN2012103189798A CN102864410A (en) 2012-08-31 2012-08-31 Preparation method of high dielectric constant gate dielectric lanthanum titanium oxide amorphous film

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN2012103189798A CN102864410A (en) 2012-08-31 2012-08-31 Preparation method of high dielectric constant gate dielectric lanthanum titanium oxide amorphous film

Publications (1)

Publication Number Publication Date
CN102864410A true CN102864410A (en) 2013-01-09

Family

ID=47443534

Family Applications (1)

Application Number Title Priority Date Filing Date
CN2012103189798A Pending CN102864410A (en) 2012-08-31 2012-08-31 Preparation method of high dielectric constant gate dielectric lanthanum titanium oxide amorphous film

Country Status (1)

Country Link
CN (1) CN102864410A (en)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN114197048A (en) * 2021-12-08 2022-03-18 电子科技大学长三角研究院(湖州) Single crystal film with two-dimensional electron gas and preparation method thereof

Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20060084251A1 (en) * 2004-10-18 2006-04-20 Fujitsu Limited Plating method, semiconductor device fabrication method and circuit board fabrication method
CN101200794A (en) * 2007-07-09 2008-06-18 昆山光铭光电子元件有限公司 Method for preparing premelting lanthanum titanate crystalloid steam plating material

Patent Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20060084251A1 (en) * 2004-10-18 2006-04-20 Fujitsu Limited Plating method, semiconductor device fabrication method and circuit board fabrication method
CN101200794A (en) * 2007-07-09 2008-06-18 昆山光铭光电子元件有限公司 Method for preparing premelting lanthanum titanate crystalloid steam plating material

Non-Patent Citations (3)

* Cited by examiner, † Cited by third party
Title
M.LI ET.AL: "Electrical and material characterizations of high-permittivity HfxTi1-xO2 gate insulators", 《JOURNAL OF APPLIED PHYSICS》 *
杨陈等: "等离子辅助电子束蒸发La2O3 薄膜的制备", 《稀有金属材料与工程》 *
郭鸣等: "新一代CMOS 器件栅介质材料研究进展", 《井冈山大学学报(自然科学版)》 *

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN114197048A (en) * 2021-12-08 2022-03-18 电子科技大学长三角研究院(湖州) Single crystal film with two-dimensional electron gas and preparation method thereof
CN114197048B (en) * 2021-12-08 2024-04-09 电子科技大学长三角研究院(湖州) Monocrystalline film with two-dimensional electron gas and preparation method thereof

Similar Documents

Publication Publication Date Title
Yang et al. Impedance studies of oxygen exchange on dense thin film electrodes of La0. 5Sr0. 5CoO3− δ
Chourashiya et al. Synthesis and characterization of 10% Gd doped ceria (GDC) deposited on NiO-GDC anode-grade-ceramic substrate as half cell for IT-SOFC
CN103219153B (en) A kind of high pressure resistant high density capacitors and preparation method thereof
Ramanathan et al. Electrical properties of thin film zirconia grown by ultraviolet ozone oxidation
Rezugina et al. Ni-YSZ films deposited by reactive magnetron sputtering for SOFC applications
Constantin et al. Interface stability of thin, dense CGO film coating on YSZ for solid oxide fuel cells
Hu et al. Preparation and dielectric properties of dense and amorphous alumina film by sol–gel technology
Ballée et al. Synthesis of a thin-layered ionic conductor, CeO2− Y2O3, by atomic layer deposition in view of solid oxide fuel cell applications
Jamale et al. Influence of substrate temperature on structural, morphological and electrical properties of La0. 6Sr0. 4Co0. 2Fe0. 8O3 thin films for IT-SOFCs
CN111676456B (en) Self-assembled Ba (Hf, ti) O 3 :HfO 2 Nano composite lead-free epitaxial single-layer film and preparation method thereof
Gaudon et al. Evaluation of a sol–gel process for the synthesis of La1− xSrxMnO3+ δ cathodic multilayers for solid oxide fuel cells
Im et al. Electrochemical properties of nanostructured lanthanum strontium manganite cathode fabricated by electrostatic spray deposition
Kuo et al. Growth of 20 mol% Gd-doped ceria thin films by RF reactive sputtering: the O2/Ar flow ratio effect
CN102864410A (en) Preparation method of high dielectric constant gate dielectric lanthanum titanium oxide amorphous film
Lin et al. Characterization of electrolyte films deposited by using RF magnetron sputtering a 20 mol% gadolinia-doped ceria target
Solovyev et al. Magnetron-sputtered La 0.6 Sr 0.4 Co 0.2 Fe 0.8 O 3 nanocomposite interlayer for solid oxide fuel cells
CN112151671A (en) Organic spin valve device based on two-dimensional metal organic framework thin film material and preparation method
Liu et al. Preparation and characterization of La0. 9Sr0. 1Ga0. 8Mg0. 2O3− δ thin film on the porous cathode for SOFC
Maglia et al. Transport properties in bulk nanocrystalline Sm-doped ceria with doping content between 2 and 30 at.%
CN102864412A (en) Preparation method of amorphous lanthanum oxide film
CN102386326B (en) Preparation method of copper nitride resistive material for high-density resistive random access memory
JP6366054B2 (en) Method for producing composite layer structure and method for producing cathode of solid oxide fuel cell
Kment et al. Role of ion bombardment, film thickness and temperature of annealing on PEC activity of very-thin film hematite photoanodes deposited by advanced magnetron sputtering
Chalermkiti et al. Fabrication of samarium doped ceria electrolyte on rough glass substrate with high electrical conductivity by electrostatic spray deposition for intermediate temperature solid oxide fuel cells
Ji et al. On the reduced electrical conductivity of radio-frequency sputtered doped ceria thin film by elevating the substrate temperature

Legal Events

Date Code Title Description
C06 Publication
PB01 Publication
C10 Entry into substantive examination
SE01 Entry into force of request for substantive examination
C02 Deemed withdrawal of patent application after publication (patent law 2001)
WD01 Invention patent application deemed withdrawn after publication

Application publication date: 20130109