Robert M. Kunemund

Examiner (ID: 15355, Phone: (571)272-1464 , Office: P/1714 )

Most Active Art Unit	1714
Art Unit(s)	1103, 1107, 1722, 1109, 1714, 1765, 1763, 1792
Total Applications	3551
Issued Applications	2780
Pending Applications	190
Abandoned Applications	614

Applications

StatisticsSubscription-Only

Applications

Application number	Title of the application	Filing Date	Status
Array ( [id] => 16901019 [patent_doc_number] => 20210179935 [patent_country] => US [patent_kind] => A1 [patent_issue_date] => 2021-06-17 [patent_title] => METHODS AND DEVICES FOR GROWING SCINTILLATION CRYSTALS WITH SHORT DECAY TIME [patent_app_type] => utility [patent_app_number] => 17/186188 [patent_app_country] => US [patent_app_date] => 2021-02-26 [patent_effective_date] => 0000-00-00 [patent_drawing_sheets_cnt] => 0 [patent_figures_cnt] => 0 [patent_no_of_words] => 29723 [patent_no_of_claims] => 0 [patent_no_of_ind_claims] => -18 [patent_words_short_claim] => 128 [patent_maintenance] => 1 [patent_no_of_assignments] => 0 [patent_current_assignee] =>[type] => publication [pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 17186188 [rel_patent_id] =>[rel_patent_doc_number] =>) 17/186188	Methods and devices for growing scintillation crystals with short decay time	Feb 25, 2021	Issued
Array ( [id] => 18794244 [patent_doc_number] => 11828002 [patent_country] => US [patent_kind] => B2 [patent_issue_date] => 2023-11-28 [patent_title] => Large, UV-transparent aluminum nitride single crystals [patent_app_type] => utility [patent_app_number] => 17/181138 [patent_app_country] => US [patent_app_date] => 2021-02-22 [patent_effective_date] => 0000-00-00 [patent_drawing_sheets_cnt] => 17 [patent_figures_cnt] => 25 [patent_no_of_words] => 21949 [patent_no_of_claims] => 19 [patent_no_of_ind_claims] => 1 [patent_words_short_claim] => 378 [patent_maintenance] => 1 [patent_no_of_assignments] => 0 [patent_current_assignee] =>[type] => patent [pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 17181138 [rel_patent_id] =>[rel_patent_doc_number] =>) 17/181138	Large, UV-transparent aluminum nitride single crystals	Feb 21, 2021	Issued
Array ( [id] => 17697422 [patent_doc_number] => 11371140 [patent_country] => US [patent_kind] => B2 [patent_issue_date] => 2022-06-28 [patent_title] => Method for producing GaN crystal [patent_app_type] => utility [patent_app_number] => 17/178423 [patent_app_country] => US [patent_app_date] => 2021-02-18 [patent_effective_date] => 0000-00-00 [patent_drawing_sheets_cnt] => 18 [patent_figures_cnt] => 25 [patent_no_of_words] => 18682 [patent_no_of_claims] => 15 [patent_no_of_ind_claims] => 1 [patent_words_short_claim] => 69 [patent_maintenance] => 1 [patent_no_of_assignments] => 0 [patent_current_assignee] =>[type] => patent [pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 17178423 [rel_patent_id] =>[rel_patent_doc_number] =>) 17/178423	Method for producing GaN crystal	Feb 17, 2021	Issued
Array ( [id] => 18209669 [patent_doc_number] => 20230055929 [patent_country] => US [patent_kind] => A1 [patent_issue_date] => 2023-02-23 [patent_title] => MANUFACTURING METHOD FOR SEMICONDUCTOR SILICON WAFER [patent_app_type] => utility [patent_app_number] => 17/797874 [patent_app_country] => US [patent_app_date] => 2021-02-16 [patent_effective_date] => 0000-00-00 [patent_drawing_sheets_cnt] => 0 [patent_figures_cnt] => 0 [patent_no_of_words] => 8152 [patent_no_of_claims] => 0 [patent_no_of_ind_claims] => -6 [patent_words_short_claim] => 298 [patent_maintenance] => 1 [patent_no_of_assignments] => 0 [patent_current_assignee] =>[type] => publication [pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 17797874 [rel_patent_id] =>[rel_patent_doc_number] =>) 17/797874	Manufacturing method for semiconductor silicon wafer	Feb 15, 2021	Issued
Array ( [id] => 18590551 [patent_doc_number] => 11739435 [patent_country] => US [patent_kind] => B2 [patent_issue_date] => 2023-08-29 [patent_title] => Single-crystal fiber production equipment and single-crystal fiber production method [patent_app_type] => utility [patent_app_number] => 17/610871 [patent_app_country] => US [patent_app_date] => 2021-02-12 [patent_effective_date] => 0000-00-00 [patent_drawing_sheets_cnt] => 6 [patent_figures_cnt] => 6 [patent_no_of_words] => 4307 [patent_no_of_claims] => 15 [patent_no_of_ind_claims] => 3 [patent_words_short_claim] => 94 [patent_maintenance] => 1 [patent_no_of_assignments] => 0 [patent_current_assignee] =>[type] => patent [pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 17610871 [rel_patent_id] =>[rel_patent_doc_number] =>) 17/610871	Single-crystal fiber production equipment and single-crystal fiber production method	Feb 11, 2021	Issued
Array ( [id] => 16992351 [patent_doc_number] => 20210230771 [patent_country] => US [patent_kind] => A1 [patent_issue_date] => 2021-07-29 [patent_title] => APPARATUS FOR MANIPULATING CRYSTAL MORPHOLOGY TO ACHIEVE STABLE FLUIDIZATION [patent_app_type] => utility [patent_app_number] => 17/173645 [patent_app_country] => US [patent_app_date] => 2021-02-11 [patent_effective_date] => 0000-00-00 [patent_drawing_sheets_cnt] => 0 [patent_figures_cnt] => 0 [patent_no_of_words] => 5663 [patent_no_of_claims] => 0 [patent_no_of_ind_claims] => 0 [patent_words_short_claim] => 2 [patent_maintenance] => 1 [patent_no_of_assignments] => 0 [patent_current_assignee] =>[type] => publication [pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 17173645 [rel_patent_id] =>[rel_patent_doc_number] =>) 17/173645	APPARATUS FOR MANIPULATING CRYSTAL MORPHOLOGY TO ACHIEVE STABLE FLUIDIZATION	Feb 10, 2021	Abandoned
Array ( [id] => 19277108 [patent_doc_number] => 12027239 [patent_country] => US [patent_kind] => B2 [patent_issue_date] => 2024-07-02 [patent_title] => Quality prediction method, preparation method and system of conductive gallium oxide based on deep learning and edge-defined film-fed growth method [patent_app_type] => utility [patent_app_number] => 17/760945 [patent_app_country] => US [patent_app_date] => 2021-02-08 [patent_effective_date] => 0000-00-00 [patent_drawing_sheets_cnt] => 4 [patent_figures_cnt] => 4 [patent_no_of_words] => 8942 [patent_no_of_claims] => 10 [patent_no_of_ind_claims] => 2 [patent_words_short_claim] => 160 [patent_maintenance] => 1 [patent_no_of_assignments] => 0 [patent_current_assignee] =>[type] => patent [pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 17760945 [rel_patent_id] =>[rel_patent_doc_number] =>) 17/760945	Quality prediction method, preparation method and system of conductive gallium oxide based on deep learning and edge-defined film-fed growth method	Feb 7, 2021	Issued
Array ( [id] => 18391880 [patent_doc_number] => 20230160098 [patent_country] => US [patent_kind] => A1 [patent_issue_date] => 2023-05-25 [patent_title] => QUALITY PREDICTION METHOD, PREPARATION METHOD AND SYSTEM OF HIGH RESISTANCE GALLIUM OXIDE BASED ON DEEP LEARNING AND EDGE-DEFINED FILM-FED GROWTH METHOD [patent_app_type] => utility [patent_app_number] => 17/760964 [patent_app_country] => US [patent_app_date] => 2021-02-08 [patent_effective_date] => 0000-00-00 [patent_drawing_sheets_cnt] => 0 [patent_figures_cnt] => 0 [patent_no_of_words] => 9048 [patent_no_of_claims] => 0 [patent_no_of_ind_claims] => -8 [patent_words_short_claim] => 2 [patent_maintenance] => 1 [patent_no_of_assignments] => 0 [patent_current_assignee] =>[type] => publication [pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 17760964 [rel_patent_id] =>[rel_patent_doc_number] =>) 17/760964	Quality prediction method, preparation method and system of high resistance gallium oxide based on deep learning and edge-defined film-fed growth method	Feb 7, 2021	Issued
Array ( [id] => 18267438 [patent_doc_number] => 20230088680 [patent_country] => US [patent_kind] => A1 [patent_issue_date] => 2023-03-23 [patent_title] => FLUIDIZED BED GRANULATOR OR FLUIDIZED BED/SPOUTED BED GRANULATOR [patent_app_type] => utility [patent_app_number] => 17/909149 [patent_app_country] => US [patent_app_date] => 2021-02-08 [patent_effective_date] => 0000-00-00 [patent_drawing_sheets_cnt] => 0 [patent_figures_cnt] => 0 [patent_no_of_words] => 7130 [patent_no_of_claims] => 0 [patent_no_of_ind_claims] => -9 [patent_words_short_claim] => 252 [patent_maintenance] => 1 [patent_no_of_assignments] => 0 [patent_current_assignee] =>[type] => publication [pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 17909149 [rel_patent_id] =>[rel_patent_doc_number] =>) 17/909149	Fluidized bed granulator or fluidized bed/spouted bed granulator	Feb 7, 2021	Issued
Array ( [id] => 16871403 [patent_doc_number] => 20210164870 [patent_country] => US [patent_kind] => A1 [patent_issue_date] => 2021-06-03 [patent_title] => MICROFLUIDIC DEVICES FOR INVESTIGATING CRYSTALLIZATION [patent_app_type] => utility [patent_app_number] => 17/170022 [patent_app_country] => US [patent_app_date] => 2021-02-08 [patent_effective_date] => 0000-00-00 [patent_drawing_sheets_cnt] => 0 [patent_figures_cnt] => 0 [patent_no_of_words] => 21178 [patent_no_of_claims] => 0 [patent_no_of_ind_claims] => -19 [patent_words_short_claim] => 65 [patent_maintenance] => 1 [patent_no_of_assignments] => 0 [patent_current_assignee] =>[type] => publication [pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 17170022 [rel_patent_id] =>[rel_patent_doc_number] =>) 17/170022	Microfluidic devices for investigating crystallization	Feb 7, 2021	Issued
Array ( [id] => 18831242 [patent_doc_number] => 20230399768 [patent_country] => US [patent_kind] => A1 [patent_issue_date] => 2023-12-14 [patent_title] => PREPARATION METHOD OF CONDUCTIVE GALLIUM OXIDE BASED ON DEEP LEARNING AND HEAT EXCHANGE METHOD [patent_app_type] => utility [patent_app_number] => 18/250262 [patent_app_country] => US [patent_app_date] => 2021-02-08 [patent_effective_date] => 0000-00-00 [patent_drawing_sheets_cnt] => 0 [patent_figures_cnt] => 0 [patent_no_of_words] => 7766 [patent_no_of_claims] => 0 [patent_no_of_ind_claims] => -8 [patent_words_short_claim] => 2 [patent_maintenance] => 1 [patent_no_of_assignments] => 0 [patent_current_assignee] =>[type] => publication [pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 18250262 [rel_patent_id] =>[rel_patent_doc_number] =>) 18/250262	PREPARATION METHOD OF CONDUCTIVE GALLIUM OXIDE BASED ON DEEP LEARNING AND HEAT EXCHANGE METHOD	Feb 7, 2021	Abandoned
Array ( [id] => 18408702 [patent_doc_number] => 20230170055 [patent_country] => US [patent_kind] => A1 [patent_issue_date] => 2023-06-01 [patent_title] => PREPARATION METHOD OF CONDUCTIVE GALLIUM OXIDE BASED ON DEEP LEARNING AND VERTICAL BRIDGMAN GROWTH METHOD [patent_app_type] => utility [patent_app_number] => 17/761322 [patent_app_country] => US [patent_app_date] => 2021-02-07 [patent_effective_date] => 0000-00-00 [patent_drawing_sheets_cnt] => 0 [patent_figures_cnt] => 0 [patent_no_of_words] => 8483 [patent_no_of_claims] => 0 [patent_no_of_ind_claims] => -8 [patent_words_short_claim] => 2 [patent_maintenance] => 1 [patent_no_of_assignments] => 0 [patent_current_assignee] =>[type] => publication [pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 17761322 [rel_patent_id] =>[rel_patent_doc_number] =>) 17/761322	Preparation method of conductive gallium oxide based on deep learning and vertical Bridgman growth method	Feb 6, 2021	Issued
Array ( [id] => 18391878 [patent_doc_number] => 20230160096 [patent_country] => US [patent_kind] => A1 [patent_issue_date] => 2023-05-25 [patent_title] => QUALITY PREDICTION METHOD, PREPARATION METHOD AND SYSTEM OF HIGH RESISTANCE GALLIUM OXIDE BASED ON DEEP LEARNING AND CZOCHRALSKI METHOD [patent_app_type] => utility [patent_app_number] => 17/760938 [patent_app_country] => US [patent_app_date] => 2021-02-07 [patent_effective_date] => 0000-00-00 [patent_drawing_sheets_cnt] => 0 [patent_figures_cnt] => 0 [patent_no_of_words] => 8125 [patent_no_of_claims] => 0 [patent_no_of_ind_claims] => -8 [patent_words_short_claim] => 2 [patent_maintenance] => 1 [patent_no_of_assignments] => 0 [patent_current_assignee] =>[type] => publication [pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 17760938 [rel_patent_id] =>[rel_patent_doc_number] =>) 17/760938	Quality prediction method, preparation method and system of high resistance gallium oxide based on deep learning and Czochralski method	Feb 6, 2021	Issued
Array ( [id] => 19276486 [patent_doc_number] => 12026616 [patent_country] => US [patent_kind] => B2 [patent_issue_date] => 2024-07-02 [patent_title] => Preparation method of high resistance gallium oxide based on deep learning and vertical bridgman growth method [patent_app_type] => utility [patent_app_number] => 17/761030 [patent_app_country] => US [patent_app_date] => 2021-02-05 [patent_effective_date] => 0000-00-00 [patent_drawing_sheets_cnt] => 3 [patent_figures_cnt] => 4 [patent_no_of_words] => 8686 [patent_no_of_claims] => 10 [patent_no_of_ind_claims] => 2 [patent_words_short_claim] => 183 [patent_maintenance] => 1 [patent_no_of_assignments] => 0 [patent_current_assignee] =>[type] => patent [pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 17761030 [rel_patent_id] =>[rel_patent_doc_number] =>) 17/761030	Preparation method of high resistance gallium oxide based on deep learning and vertical bridgman growth method	Feb 4, 2021	Issued
Array ( [id] => 18391879 [patent_doc_number] => 20230160097 [patent_country] => US [patent_kind] => A1 [patent_issue_date] => 2023-05-25 [patent_title] => QUALITY PREDICTION METHOD, PREPARATION METHOD AND SYSTEM OF CONDUCTIVE GALLIUM OXIDE BASED ON DEEP LEARNING AND CZOCHRALSKI METHOD [patent_app_type] => utility [patent_app_number] => 17/761042 [patent_app_country] => US [patent_app_date] => 2021-02-05 [patent_effective_date] => 0000-00-00 [patent_drawing_sheets_cnt] => 0 [patent_figures_cnt] => 0 [patent_no_of_words] => 7997 [patent_no_of_claims] => 0 [patent_no_of_ind_claims] => -8 [patent_words_short_claim] => 2 [patent_maintenance] => 1 [patent_no_of_assignments] => 0 [patent_current_assignee] =>[type] => publication [pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 17761042 [rel_patent_id] =>[rel_patent_doc_number] =>) 17/761042	Quality prediction method, preparation method and system of conductive gallium oxide based on deep learning and Czochralski method	Feb 4, 2021	Issued
Array ( [id] => 18546272 [patent_doc_number] => 11719619 [patent_country] => US [patent_kind] => B2 [patent_issue_date] => 2023-08-08 [patent_title] => System and method for testing adhesion of brittle materials [patent_app_type] => utility [patent_app_number] => 17/169203 [patent_app_country] => US [patent_app_date] => 2021-02-05 [patent_effective_date] => 0000-00-00 [patent_drawing_sheets_cnt] => 23 [patent_figures_cnt] => 26 [patent_no_of_words] => 14328 [patent_no_of_claims] => 20 [patent_no_of_ind_claims] => 3 [patent_words_short_claim] => 128 [patent_maintenance] => 1 [patent_no_of_assignments] => 0 [patent_current_assignee] =>[type] => patent [pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 17169203 [rel_patent_id] =>[rel_patent_doc_number] =>) 17/169203	System and method for testing adhesion of brittle materials	Feb 4, 2021	Issued
Array ( [id] => 18685520 [patent_doc_number] => 11781243 [patent_country] => US [patent_kind] => B2 [patent_issue_date] => 2023-10-10 [patent_title] => Method for depositing low temperature phosphorous-doped silicon [patent_app_type] => utility [patent_app_number] => 17/166160 [patent_app_country] => US [patent_app_date] => 2021-02-03 [patent_effective_date] => 0000-00-00 [patent_drawing_sheets_cnt] => 3 [patent_figures_cnt] => 3 [patent_no_of_words] => 6590 [patent_no_of_claims] => 19 [patent_no_of_ind_claims] => 2 [patent_words_short_claim] => 129 [patent_maintenance] => 1 [patent_no_of_assignments] => 0 [patent_current_assignee] =>[type] => patent [pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 17166160 [rel_patent_id] =>[rel_patent_doc_number] =>) 17/166160	Method for depositing low temperature phosphorous-doped silicon	Feb 2, 2021	Issued
Array ( [id] => 17762873 [patent_doc_number] => 20220236485 [patent_country] => US [patent_kind] => A1 [patent_issue_date] => 2022-07-28 [patent_title] => FORMING OPTICAL COMPONENTS USING SELECTIVE AREA EPITAXY [patent_app_type] => utility [patent_app_number] => 17/159406 [patent_app_country] => US [patent_app_date] => 2021-01-27 [patent_effective_date] => 0000-00-00 [patent_drawing_sheets_cnt] => 0 [patent_figures_cnt] => 0 [patent_no_of_words] => 3285 [patent_no_of_claims] => 0 [patent_no_of_ind_claims] => -19 [patent_words_short_claim] => 82 [patent_maintenance] => 1 [patent_no_of_assignments] => 0 [patent_current_assignee] =>[type] => publication [pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 17159406 [rel_patent_id] =>[rel_patent_doc_number] =>) 17/159406	Forming optical components using selective area epitaxy	Jan 26, 2021	Issued
Array ( [id] => 16839991 [patent_doc_number] => 20210148003 [patent_country] => US [patent_kind] => A1 [patent_issue_date] => 2021-05-20 [patent_title] => PYRAMIDAL GROWTH METHOD FOR LONG-SEED KDP-TYPE CRYSTAL [patent_app_type] => utility [patent_app_number] => 17/159106 [patent_app_country] => US [patent_app_date] => 2021-01-26 [patent_effective_date] => 0000-00-00 [patent_drawing_sheets_cnt] => 0 [patent_figures_cnt] => 0 [patent_no_of_words] => 3654 [patent_no_of_claims] => 0 [patent_no_of_ind_claims] => -3 [patent_words_short_claim] => 449 [patent_maintenance] => 1 [patent_no_of_assignments] => 0 [patent_current_assignee] =>[type] => publication [pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 17159106 [rel_patent_id] =>[rel_patent_doc_number] =>) 17/159106	Method for rapid growth of long seed KDP-type crystals	Jan 25, 2021	Issued
Array ( [id] => 18910600 [patent_doc_number] => 11873573 [patent_country] => US [patent_kind] => B2 [patent_issue_date] => 2024-01-16 [patent_title] => Field-editing technology for quantum materials synthesis using a magnetic field laser furnace [patent_app_type] => utility [patent_app_number] => 17/794108 [patent_app_country] => US [patent_app_date] => 2021-01-21 [patent_effective_date] => 0000-00-00 [patent_drawing_sheets_cnt] => 19 [patent_figures_cnt] => 25 [patent_no_of_words] => 10027 [patent_no_of_claims] => 19 [patent_no_of_ind_claims] => 3 [patent_words_short_claim] => 85 [patent_maintenance] => 1 [patent_no_of_assignments] => 0 [patent_current_assignee] =>[type] => patent [pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 17794108 [rel_patent_id] =>[rel_patent_doc_number] =>) 17/794108	Field-editing technology for quantum materials synthesis using a magnetic field laser furnace	Jan 20, 2021	Issued

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