Methods and computer system for combinatorial analysis of lighting phosphors

BACKGROUND OF THE INVENTION

The present invention relates in general to methods and systems for analyzing selected chemical or physical traits via combinatorial techniques. Specifically, the present invention relates to a computer system and method for recording, organizing, and analyzing selected luminescent properties of lighting phosphors in the combinatorial synthesis and screening of such phosphors.

Combinatorial methodologies have been used in various industries for high-throughput production and screening of desired products with certain physical or chemical traits. A well-known example is combinatorial chemistry methods that have been widely utilized in the pharmaceutical industry for fast synthesizing and screening of chemical compounds and building compound libraries (e.g., U.S. Pat. No. 5,424,186). Another example is a technique for, generating arrays of peptides and other molecules using light-directed, spatially-addressable synthesis (U.S. Pat. No. 5,143,854). More recently, combinatorial methodologies have been applied to inorganic materials in the form of thin films deposited or evaporated onto a substrate (U.S. Pat. No. 5,985,356). In this connection, methods and instruments have been developed to search for new phosphors in a high-throughput fashion (Sun, T., Biotechnology and Bioengineering Combinatorial Chemistry, 61, 4 (1998/1999), using a combination of a thin-film deposition and a masking strategy to generate a thin film spatially addressable library).

Phosphors, i.e., luminescent materials, convert a certain type of energy into electromagnetic radiation over thermal radiation. A phosphor is usually composed of a host lattice doped with fluorescent-active elements (activator) present in up to a few mole %. Phosphors have been widely used in fluorescent lamps, displays, scintillators, etc. Although the search for advanced phosphors started about a century ago, the new photonic technologies, including mercury-free fluorescent lamps, various flat panel displays, computed topography (CT), etc., require new phosphors with advanced properties such as, high quantum efficiency, good absorption of the excitation energy, adequate color coordinates, long lifetime, and low cost.

The discovery of advanced oxide phosphors with multiple superior qualities for display applications continues to be a challenge. The specific spectral properties, absorption, quantum efficiencies, and lumen maintenance depend on complex interactions between the excitation source, host lattice, structural defects, and fluorescent dopants. Luminescence properties are highly sensitive to the changes in dopant composition, host stoichiometry, and processing conditions. Consequently, the identification of phosphors that are ideally suited to the requirements of a given display technology is highly empirical.

Such empiricism demands high processing capacity both for synthesis and for screening of the phosphors. More importantly, the vast amount of data generated from the fast-speed synthesis and screening must be duly sorted, recorded, and analyzed to achieve the overall efficiency of this discovery process. It is impracticable to rely on conventional lab notebooks to track thousand of data entries, let alone to analyze and make sense of them. There is therefore a need for a computer system and method to enable high-throughput combinatory analysis of luminescent properties of phosphors, a need that parallels the need for combinatory chemical compound library systems in the pharmaceutical industry. The latter need has been met with the development of electronic compound libraries that support query and visualization of the chemical structure and other-properties of the compounds. The former need, however, remains unmet. The system and method required must be uniquely designed to analyze photo-metric properties and to seamlessly integrate into the synthesis and screening instrumentation.

BRIEF SUMMARY OF THE INVENTION

There is provided a computer system for combinatorial synthesis, screening, and analysis of luminescent materials, which system comprises: a database having recorded therein information relating to said synthesis, said screening, said analysis, and results of said analysis; an analysis module performing analytic operations to derive said results; and an interface allowing a user to input instructions to said computer system and the computer system to present said information to the user, wherein said database, said analysis module, and said interface are inter-connected. Various alternative configurations of the computer system are provided in the following detailed descriptions.

There is also provided a method for combinatorial synthesis, screening, and analysis of luminescent materials, which method comprises: obtaining a first combinatory library of luminescent materials; digitally recording properties of said luminescent materials in said first combinatory library; and performing computerized analyses based on said properties and the information relating to said combinatorial synthesis and screening.

There is also provided a computer system for combinatorial synthesis, screening, and analysis of luminescent materials, which system comprises: a database means for recording information relating to said synthesis, said screening, said analysis, and results of said analysis; an analysis means for performing analytic operations to derive said results; and an interface means for allowing a user to input instructions to said computer system and the computer system to present said information to the user, wherein said database means, said analysis means, and said interface means are inter-connected.

BRIEF DESCRIPTION OF THE DRAWINGS

The features of the method and system according to the preferred embodiments of the invention will now be described with reference to the drawings summarized below. These drawings and the associated descriptions are provided to illustrate preferred embodiments of the invention, and not to limit the scope of the invention. Throughout the drawings, reference numbers are reused to indicate correspondence between referenced elements. In addition, the first digit of each reference number indicates the figure in which the element first appears.

FIG. 1

is an organizational diagram of various components of the computer system

100

according to a preferred embodiment of the invention.

FIG. 2

is a flow chart of processing steps in the computer system

100

in one embodiment of this invention.

FIG. 3

is a schematic representation of a combi-phosphor fluorescent imaging system.

FIG. 4

is a schematic representation of fast serial fluorescent spectrum measurement system for phosphor library.

FIG. 5

is a schematic representation of a liquid dispenser, used to generate a phosphors library.

FIG. 6

is a fluorescent image of a powder phosphor library.

FIG. 7

is a screen shot of the interface

104

which prompts the user for a login name and password, according to one embodiment of this invention.

FIG. 8

is a screen shot of the interface

104

, which displays a main menu of the system

100

in one embodiment of the system.

FIG. 9

is a screen shot of the interface

104

, which demonstrates the registration process to establish a library.

FIG. 10

is a screen shot of the interface

104

, which shows that the user enters chemicals of interest for building the compound.

FIG. 11

is a screen shot of the interface

104

, which shows a composition map of the library.

FIG. 12

is a screen short of the interface

104

, demonstrating that the user chooses different methods for combinatory deposition and synthesis of the library.

FIG. 13

is a screen shot of the interface

104

, demonstrating that the user specifies thermal processing conditions for making the phosphor library.

FIG. 14

is a screen shot of the interface

104

, showing that different measurements, e.g., emission spectrum and X-ray diffraction graph may be recorded into the database

102

, as designated by the user.

FIG. 15

is a screen shot of the interface

104

, showing a particular visualization on elemental compositions of each sample in phosphor library.

FIG. 16

is a screen shot of the interface

104

, showing the emission spectrum of a phosphor sample in phosphor library.

DETAILED DESCRIPTION OF THE INVENTION

The present inventor has developed a method and a computerized system enabling high-throughput combinatorial synthesis and screening of lighting phosphors. The method and computer system links hardware instrumentation for synthesis and screening. It records, sorts, and analyzes photo-metric data gathered from the combinatorial studies.

According to one aspect of the present invention, the computer system provides a database having stored therein luminescent properties of phosphors, as well as the information on combinatorial synthesis and screening protocols. The data resides in a computer memory, whether standing alone or linked as distributed units. The system allows querying on various photo-metric attributes of the phosphors of interest. It also supports queries on the characteristics of the corresponding processes in the combinatorial experiments, including the steps of synthesis and screening of lighting phosphors.

According to another aspect of the present invention, the computer system provides an interface through which a user monitors combinatorial synthesis and screening and analyzes luminescent property data. A user may design combinatory experiments by entering key parameters via the interface; he may review the results of library synthesis by querying on the relevant parameters. Various types of analyses of the luminescent properties may be performed on the photo-metric data when the user specifies a designated identification number. The interface may support visualization capacities in some embodiments of this invention.

According to yet another aspect of the present invention, the computer system may employ a distributed client-server architecture in some embodiments, where multiple clients with multiple interfaces may serve a plurality of users concurrently. The database module operates on the server and supports the multiple clients via a computer network. In an alternative embodiment, certain clients may have a local mirrored copy of the database for fast access. In this case, distributed databases are synchronized periodically with the master database on the server.

According to a further aspect of the present invention, the computer system provides an analysis module for combinatorial analyses of phosphor luminescent properties. The analysis module is connected directly to the database and the interface; it uses the data from the database, performs analyses according to the user's request received from the interface. Various types of statistical analyses may be included in the system; visualization of the results may also be enabled as needed.

The combinatorial process includes three main elements: combinatorial deposition, parallel synthesis, and high throughput screening.

Hundreds to thousands of different elemental compositions are created on a solid support, in either multiple layer thin film or solution precursor mixing forms. This can be accomplished by either combining thin film deposition apparatus and a masking strategy, or using an automated liquid dispensing system.

Referring to

FIG. 5

, for example, a liquid dispensing system is used for generating a powder phosphor library. A sintered alumina (99.5% purity) plate

500

with 128 (8 by 16 array) cells

502

of 2 mm in diameter and about 6 mm in depth is machined and used as containing plate of liquid precursors to powder phosphors. The neighboring cells are 3 mm in center to center separation and registered in position to the array of liquid dispenser

504

. By coordinating the scanning motion of a X-Y-Z table

506

mounted with the substrate plate in the spatial resolution of 0.1 mm, and variation of liquid volumes from dispenser, a library with 128 different solution mixing precursors of powder phosphors can be generated in several minutes.

The solid support with the assembly of sample precursors is processed under identical conditions to synthesize a library of solid state materials. Referring to the same example in

FIG. 5

, high purity (≧99.9%) clear aqueous nitrate solutions are used in making the powder library: Y(NO

3

)

3

(1M), Gd(NO

3

)

3

(1M), Lu(NO

3

)

3

(1M), Al(NO

3

)

3

(1M), Ga(NO

3

)

3

(1M), Ce(NO

3

)

3

(0.5M). Following a scheme of library design, a solution precursor of the phosphor library is generated on the alumina plate

500

with 128 sample cells. The total amount of samples in each cell is approximately 10 &mgr;mole. The metal compositions of each cell is of the general formula (Y

x

A

1−x

)

3

(Al

y

Ga

1−Y

)

5

O

12

:Ce

3+

0.06

(A: Gd, Lu), where 3≧x≧0.375, 5≧y≧0.625. The identical condition is ensured by placing the library on an orbital shaker for mixing, with an IR lamp shining over to evaporate the solvent; the surface temperature is approximately 80° C. After the samples are dried, the library is placed in a reducing furnace at 1400° C. for 2 hours. The heating and cooling rate is controlled to be about 10° C./minutes.

Synthesis of the phosphor library is followed by high throughput screening process, which may reach a daily rate of 100-1000 luminescent properties.

FIG. 6

shows the fluorescent image of the powder phosphor library generated as discussed above in the example of FIG.

5

. After thermal treatment, there is no detectable cross contamination of neighboring samples, and no apparent alumina substrate effect on phosphor samples. The library is placed under a uniform long UV (370 nm) excitation. Three distinguishable emitting colors: orange-yellow-green, may be obtained from this series of phosphors, by simple elemental substitution. The brightest phosphor composition for each color may also be quickly identified.

Referring to

FIG. 3

, for example, the combi-phosphor fluorescent imaging system quickly identifies a sample lead in a phosphor library. Here, the phosphor library

304

is illuminated with a uniform UV intensity field of 254 nm through a band pass filter

302

associated with a diffused light source

300

, since fluorescent lamp phosphors have an excitation wavelength of 254 nm. A scientific grade charge coupling device (CCD) camera

306

is used to record the image of the library, such as the one shown in FIG.

6

. The brightest phosphor of a given color is then selected from the digitized fluorescent image. The identified lead compositions may be used for further validation studies.

To further characterize phosphors in a library, a fast serial fluorescent spectrum measurement system as shown in

FIG. 4

may be used to screen the emission spectrum of each phosphor in the library in a fast sequential mode. The library

400

is placed on a X-Y motion stage, and a bifurcated optical fiber

402

introduces excitation light (e.g. 254 nm) on a sample surface. The emitted fluorescent photon and reflected UV light is collected with the other branch of the bifurcated optical fiber

402

into a spectroscopy

404

, using a cooled scientific grade CCD camera

406

as detector. This measurement system takes a fraction of a second to record an emission spectrum; and thus, it typically completes an emission spectrum measurement of a phosphor library plate in a few minutes.

The efficiency and throughput of the combinatory process described above, i.e., stream-lined combinatorial deposition, parallel synthesis, and screening, is enabled by the computer system according to the preferred embodiment of the present invention. Referring to

FIG. 1

, the computer system

100

includes a database module

102

, which is connected to an analysis module

106

, and one or more interface modules

104

. Each interface module provides an interactive terminal for a user to control and monitor the combinatory synthesis and screening of the phosphor libraries, and to perform desired analytical studies on the data generated. The links among and between various modules in the system

100

may be direct network connections, connections over a wide-area network including a plurality of computers such as an enterprise intranet, or connections over an open network system such as the Internet between collaborators. In the case when open network connections are used, necessary security measures may be implemented, e.g., a virtual private network can be established.

The overall architecture of the system

100

may be primarily standalone in one embodiment, with one database supporting the combinatorial processes and the data analyses; in alternative embodiments, the system

100

may take a client-server configuration, with multiple clients serving multiple users, communicating with the server via a computer network. In the client-server environment, for example, a client may formulate instructions for library creation which are sent to the server which accordingly controls the library synthesis and screening process; the client may fashion queries according to the user's input and fire the queries against the database

102

which resides on the server's side, the server then sends back the results of the queries after processing, which may involve comprehensive analyses performed by the analysis module

106

. A further alternative embodiment involves a client-server configuration where one or more client in the network maintains a mirror copy of the database

106

; as such, the overall processing speed of the system may increase under certain circumstances. In this situation, the mirror copies of the database are periodically synchronized with the database on the server side, the master database, to ensure the integrity of both the data and the control of the system.

The hardware instrumentations, such as the liquid dispenser in

FIG. 5

, the combi-phosphor fluorescent imaging system in

FIG. 3

, and the fast serial fluorescent spectrum measurement system in

FIG. 4

discussed supra, are linked to the computer system

100

. Data generated are directly collected by the system

100

, recorded in its database module

102

. The photo-metric properties of interest, including quantum efficiency, UV absorption, color temperature, color coordinates, etc., may in turn be calculated from the recorded emission spectrum and reflected UV intensity values. The analysis module

106

of the computer system not only provides the basic computational capacities for calculating the photo-metric properties; it is also capable of performing statistical and other comprehensive data analyses on the attributes and characteristics of the phosphors.

Paralleled to the combinatorial process of deposition, synthesis, and screening, the computer system performs distinct tasks at a number of different stages as shown in FIG.

2

: the library design

200

, the library deposition

202

, the library composition

204

, the library synthesis

206

, and the library analysis

208

. The library

210

and the master library

212

represent information deposits of the phosphors synthesized, where a particular chemical composition may be synthesized for multiple times under different conditions to generate sister libraries (

210

), which then may be combined to create the master library (

212

).

Various stages of this process are also reflected in

FIG. 8

, which is a screenshot representation of an example of a combinatory analysis computer system according to the preferred embodiment of the present invention. In this interface, the first menu item on the top menu bar is marked “combinatory process,” which includes, in sequence, the items such as “library registration” (

800

), “design chemicals” (

802

), “compositional map” (

804

), “array formulation” (

806

), “experiment setup” (

808

), and “array measurement” (

810

). Here, “library registration”

800

corresponds with the library design

200

stage, where the user specifies/registers the general parameters of the library to be synthesized; “design chemicals”

802

corresponds with the library deposition

202

stage, where the registration of chemicals used is completed; “compositional map”

804

corresponds with the library composition

204

stage, where the composition of phosphor library is recorded; “array formulation”

806

and “experiment setup”

808

correspond with the library synthesis

206

stage, where the combinatory synthesis is performed based on the synthesis parameters specified; and “array measurement”

810

corresponds with the library analysis

208

stage, where comprehensive data analyses are carried out by the analysis module

106

of the computer system

100

.

A user needs to register in advance and login the system to initialize the combinatory process. Access to the computer system

100

may be controlled by requiring a valid user name and password. As shown in

FIG. 7

, a user can type in the user name and password from a terminal, whether stand-alone having its own database and analysis modules, or networked to the server system which maintains the database and analysis modules.

At the library design

200

stage, the general information, including the date, designer, library ID, experiment ID, elemental precursors and properties of interest, etc. are entered by the user. Referring to

FIG. 9

, a dialog box

900

is presented to the user in the interface

104

of the computer system

100

. A number of text fields are included in the dialog box

900

, allowing the user to input the desired information. For example, the library identification number can be entered in the text field

902

, the date and time can be entered in the text field

904

, the designer information can be entered in the text field

906

, etc. Also at the library design

200

stage, a composition matrix is defined according to the information input by the user, which corresponds to the array of samples in the phosphor library to be produced. The design parameters and the matrix information are recorded in the database; they may be either in a textual, tabular, or graphical format. The computer system

100

has visualization capacities; the compositions of phosphors may be rendered in various graphical representations, for example (see FIG.

15

), to assist the user in viewing and analyzing the phosphor libraries of interest. Detailed discussion is included infra.

Once a library is registered, the composition matrix is imported to the library deposition

202

stage, where the deposition process of elemental precursors are recorded, including the sequence of deposition, the deposition quantity, and the pattern of deposition. Referring to

FIG. 10

, a dialog box

1000

is presented in the interface

104

, which includes a number of specified text fields and a tabular window for the user to input the information desired. The library ID or experiment ID is passed from the library registration

200

stage, which is used here to track the libraries to be synthesized. The text field

1002

displays the library ID of this particular library. In the tabular window

1004

, various elemental chemicals are entered by the user sequentially, according to the order of their deposition. Various columns of the table include additional information such as the name (

1010

) and formula (

1008

) of the chemical precursors, their assigned ID numbers (

1006

), and the amount to be used in the synthesis, etc. Such information is immediately imported into the database module

102

when the user press the “Save” button

1012

; they may also be readily edited as necessary using the “Modify” button

1014

.

At the library composition

204

stage, the completed composition map is created, based on the composition matrix passed from the library deposition

202

stage. For example, a user may make a spreadsheet of the library composition using a ancillary macro process of the computer system in one embodiment, and import into the blank design matrix defined at the library design

200

stage which has the same dimension. Referring to

FIG. 11

, an example of a composition map is presented in the dialog box

1110

in the interface

104

of the computer system. The library identification number is shown in the text field Master Library ID

1102

. The dimension of the composition map is determined by the number of rows entered in the text field

1104

and the number of columns entered in the text field

1106

. The tabular winder

1114

displays the content of the composition map, which essentially contain an array of elemental compositions in a table. The user may use the MS Excel-like format to create and import the table or spreadsheet by pressing the button Excel Design

1108

. This functionality is implemented in Visual Basic in one embodiment of this invention, to ensure the compatibility with the typical MS desktop applications as a matter of practical convenience. The user may create the composition map using other procedures and graphical tools; the Visual Design button

1110

provides such alternatives, for example. The composition of each sample in the library as recorded in the map will be normalized by the system to represent the mole ratio of the each element in a given sample. After creating and editing the map, the user may import such compositional information into the database

102

by clicking the Save button

1112

.

After the library composition is determined, the system proceeds with the library synthesis, i.e., the library synthesis

206

stage. At this stage, the method of synthesis and the processing condition of the library are entered. Referring to

FIG. 12

, in the interface

104

, clicking on the first menu item “Combinatory Process” allows the user to bring up a dropdown list (

1200

) of items and procedures, including “Library Registration,” “Design Chemicals,” “Composition Map,” etc. as discussed supra. When highlighting “Array Formulation,” the user will see another dropdown list (

1202

) of different methods of deposition or synthesis, including “Liquid Dispensing,” “Sputtering,” and “Spray Drying,” for example. The user may choose a specific procedure based on his specific needs and availability of hardware instrumentation. For example, if the user uses a liquid dispensing method, a corresponding dialog box

1204

will pop up requesting relevant information for carrying out this method. The user then enters substrate in the text field

1206

, total volume per well in the text field

1208

, and total mole amount in the text field

1210

. Additional information such as syringe location, concentration of the chemical dispensed, etc., may be input in the tabular window

1212

as needed. These user's inputs are recorded in the database

102

of the system

100

, which forward the synthesis instruction to the connected hardware instrument. For example, a robot is driven by the system to generate a compositional phosphor library as desired.

Once generated, the phosphor libraries need to be thermally processed to make the final library products. Referring to

FIG. 13

, a dialog box

1300

is displayed when the user chooses “Experiment Setup” from the dropdown list of the first menu item “Combinatory Process.” Here, the processing condition are specified in the tabular window

1306

, including temperature, rate of temperature increase, time, atmosphere species, pressure, and flow rate of O

2

or H

2

, to name a few. It is noted that one or more libraries may be processed using the same composition. In the case when the user select to process further, multiple libraries will be made, and different processing conditions will be adopted. The identical composition libraries created as such will each be automatically assigned a reaction block identification number corresponding to each processing condition. These libraries may be combined to make a master library and share the same master library identification number; the text field

1302

displays such master library ID. The number of replicates in a master library is shown in the text field

1304

.

After the phosphor libraries are made, the computer system

100

is ready for the analyses the user wishes to run. The initial step of the library analysis

208

stage is the appropriate measurement of the phosphor libraries made. Referring to

FIG. 14

, the user will see a popup dialog box Library Measurement Setup (

1400

) when selecting “Array Measurement” from the dropdown list of “Combinatory Process,” the first menu item on the main menu of the interface

104

. Here, the user may choose emission spectrum and/or X-ray defraction from the window

1402

, for example. In emission spectrum, the intensity is recorded as the function of the wavelength value, whereas in X-ray diffraction, the intensity is plotted against the diffraction angle values. Each sample in the phosphor library will have a set of emission spectrum as well as X-ray diffraction in the preferred embodiment of this invention. The library identification number is displayed in the text field

1404

. When ready, the user may press the Import button

1406

to import the measurement selection to the database module

102

.

The computer system

100

subsequently sends the instruction to the hardware instrumentation connected, such as a fluorescent spectrum measurement system. The result of the measurement may be recorded in the tabular format, according to the dimension and arrangement of the array of the composition map, given a certain library and a reaction identification number. The recorded data in a table or spreadsheet may be imported as a whole into the defined design matrix, corresponding to the matrix of the composition map, in one embodiment of this invention. In alternative embodiments, the measurement result may be directly imported to the matrix in the database as each measurement is obtained. The computer system provides such flexibility so that the user may choose from on-line and off-line operations under different circumstances. Further, the computer system also supports other data format; for example, the images of luminescence of phosphor library at various excitation wave lengths may be imported into the database. In one embodiment, ActiveX control is used to extend such capacity to the database

102

of the computer system

100

.

Various types of analyses may be incorporated into the computer system, including direct calculation as well as sophisticated data correlation and reference or pattern recognition analyses. Visualization capacities are provided to facilitate analyses for certain attributes of the phosphors. The system

100

update and extend the available analyses in its analysis module

106

for new properties of interest. Referring to

FIG. 15

, selecting “Library Viewer” from the dropdown list

1502

of the second item “Viewer” on the main menu of the interface

104

, the user is presented with an example of the library composition visualized as pie charts

1504

. The mole fraction of each element is plotted in the pie chart for every sample; the different elements are color coded in the pie. The chemical composition of a selected sample is displayed in the window

1506

. For example, selecting the sample pie chart

1510

in the middle of the charts, the user will see its composition in the window

1506

. The field

1508

displays the internal index of this sample, locating its position (

3

,

5

) in the phosphor library being studied. Results of a specified analysis may be displayed in the window

1512

.

Another example of the analysis performed by the analysis module

106

is illustrated in

FIG. 16

, which demonstrates a Library Element Viewer in the interface

104

. The user may input the index or position of a library element or sample in the text fields

1602

and

1604

, and select the type of analysis from the predefined list in the field

1606

. When “Emission Spectrum” is selected, the plot of intensity against wavelength is given in the window

1608

, with the characteristic features of the spectrum displayed in the window

1610

. The latter are derived from the processing of the analysis module

106

. When the user chooses to study other photo-metric properties from the field

1606

, such as color coordinates, absorption, quantum efficiency, lumen efficiency, etc, the

106

module performs the corresponding computation and the results will be displayed in the same viewer.

It is noted that the system of the preferred embodiments of the invention also provides flexibility to readily adopt or incorporate external statistical data analysis or visualization packages such as those available commercially, e.g., SPOTFIRE™. Cross referencing to the core analysis results may be presented in the same interface

104

under this situation.

As discussed above, the library

210

and the master library

212

stages represent the deposit of all information relating to the phosphor libraries created. The computer system maintains its database module

102

which contains the library and master library information. There are grand lists of composition of elements, processing conditions, and values of different properties, for example. The system of the preferred embodiments of the present invention not only serves as an information storage, it also operates as the driver for combinatorial synthesis, and the engine for data analysis and querying. The system supports searches based on a certain range of elemental compositions, e.g., according to the alphabetic order; it provides sorting feature on various numeric attributes; it analyzes and displays multiple dimensional relationships in a graphical pattern; it allows horizontal correlation studies based on elemental composition, library processing, and phosphor properties. Used in an iterative process in combinatorial discovery of advanced lighting phosphors, the system also allows the user to map out the compositional areas of high property promise, hence provides guidance for designing the subsequent library to be made.

In summary, the integration of the combinatorial hardware instrumentation with the database and analysis modules as provided by the computer system and method according to the preferred embodiments of the present invention increases the efficiency and speed of the combinatorial synthesis and screening process for identifying desired luminescent materials. Several orders of magnitudes improvement on the speed may be achieved.

The preferred embodiments have been set forth herein for the purpose of illustration. However, this description should not be deemed to be a limitation on the scope of the invention. Accordingly, various modifications, adaptations, and alternatives may occur to one skilled in the art without departing from the spirit and scope of the claimed inventive concept.