Announcement on the Release of the 2024 National Natural Science Foundation of China
Joint Fund for Enterprise Innovation and Development Project Guidelines (Second Batch)
National Natural Science Foundation of China Enterprise Innovation and Development in 2024
Joint Fund Project Guide (Second Batch)
The National Natural Science Foundation of China and enterprises jointly invest in the establishment of the Enterprise Innovation and Development Joint Fund, which aims to give full play to the guiding role of the National Natural Science Foundation, attract and gather superior scientific research forces across the country, and focus on the urgent needs in industrial development and focus on key technological fields. Carry out basic research on core scientific issues, promote the integration of knowledge innovation system and technological innovation system, and promote the improvement of independent innovation capabilities of Chinese enterprises.
In 2024, when applying for the Joint Fund for Innovation and Development of Pilot Enterprises, it will not be included in the total number of applications and projects undertaken. It will be included after the application is officially received.
The 2024 Enterprise Innovation and Development Joint Fund (Second Batch) will be funded in the form of key support projects or integrated projects, with a funding period of 4 years. Among them, the average direct cost funding intensity of key support projects is about 2.6 million yuan/project, and the average direct cost funding intensity of integrated projects is 10 million yuan/project.
1. Fields and main research directions
(1) Energy and chemical industry
Integration project
National Energy Investment Group Co., Ltd.
1. Research on the molecular scale catalytic reaction path and mechanism of coal-based oil hydrogenation with precise product control (for application code 1, select the subordinate code of B08)
Designing catalyst systems for coal-based oil products with different molecular structural characteristics that can accurately control target products, rationally designing and regulating the structure, chemical properties and microenvironment of active sites at the atomic level, revealing the reaction mechanism at the molecular level, and improving catalysis Reactivity and product selectivity.
(1) The relationship between changes in catalyst surface chemical structure, activity and selectivity
Study the dynamic changes in the surface chemical structure of the catalyst, the surface potential energy changes caused by the difference between the local chemical structure and the bulk structure, and the process and mechanism of surface chemical reactions, reveal the reaction characteristics of the active sites, and determine the structure-performance relationship of the catalyst at the molecular level. to reveal the intrinsic kinetics and reaction mechanism of the catalytic reaction of coal-based oil.
(2) Synergistic effect of metal phase active center and acidic active center
Based on the characteristics of coal-based oil products and target products, study the micro-control of the carrier structure to change the type and intensity of the acidic center of the catalyst, and reveal the impact of changes in the metal phase and carrier microenvironment on diffusion, adsorption, surface reaction, and desorption, from the perspective of electronic effects Elucidate the synergistic effect of metal phase structure, additives and carriers, study the matching of acidity and metallicity, and provide scientific theoretical basis for the development of high-efficiency hydrogenation catalysts suitable for different coal-based oil products.
(3) High-throughput robot experiments and artificial intelligence design and screening
Aiming at the hydrogenation catalytic reaction of coal-based oil products, a high-throughput robot small-scale experiment was carried out for the development of catalytic materials for different coal-based oil products. Develop an artificial intelligence model to accurately control coal-based oil products at the molecular scale through multi-experimental target optimization to achieve high-throughput screening of catalytic materials.
This project application should include the above three research contents at the same time, and carry out in-depth systematic research closely around the theme “Research on molecular scale coal-based oil hydrogenation catalytic reaction pathways and mechanisms with precise product control”. The results should include principles, methods, technologies and experiments. Results etc.
Key support projects
National Energy Investment Group Co., Ltd.
1. Research on the coupling of plasma and catalyst materials to enhance CO2 activation and reduction technology (for application code 1, select the subordinate code of B08)
Study the coupling enhancement effect of plasma and catalytic materials, reveal the reaction mechanism of plasma-enhanced activation and reduction of CO2 molecules to produce CO, and determine the path to reduce the reaction activation energy and improve energy utilization.
2. Research on catalysts for the conversion of n-alkanes to olefins from Fischer-Tropsch synthetic oil and the conversion of internal olefins to α-olefins (for application code 1, select the subordinate code of B08)
Focusing on the development of high-efficiency Fischer-Tropsch synthetic oil n-alkane dehydrogenation to olefins and internal olefin conversion to α-olefins catalysts, in-situ characterization technology is used to study the atomic coordination structure, electronic properties and microenvironment of the catalyst surface active center to reveal the active sites reaction mechanism, construct a catalytic conversion reaction network, determine the structure-activity relationship of the catalyst, and guide the rational design of catalysts at the molecular level.
3. Research on the molecular structure and direct liquefaction reaction mechanism of oil-rich coal (for application code 1, select the subordinate code of B08)
Establish a molecular structure model of oil-rich coal and its microscopic components, study the bond breaking rules of the bonding structure of the microscopic components, the evolution process of free radicals and intermediate products, reveal the asphaltene hydrogenation reaction behavior and product regulation mechanism, and determine The internal relationship between the composition and structure of coal-microscopic components-process conditions-product distribution.
4. Research on the mechanism of preparing mesophase pitch carbon fiber raw materials from coal liquefied pitch (for application code 1, select the subordinate code of B08)
In the process of preparing mesophase pitch carbon fiber from coal liquefied pitch, the fingerprint characteristics of coal liquefied pitch and spinnable mesophase pitch were studied, the intrinsic relationship between pitch properties and fiber properties was clarified, and the characteristics of coal liquefied pitch and mesophase spinnable pitch were constructed. The structural model reveals the evolution mechanism of the microscopic properties of mesophase pitch and provides theoretical guidance for the preparation of coal liquefied pitch-based carbon fibers.
5. Research on the mechanism of deep underground coal gasification and CO2 storage in gasification chambers ( for application code 1, select the subordinate code of E04)
Study the multiphase reactions, product enrichment and migration rules, and long-term stable gas production control factors of deep underground coal gasification, reveal the spatial evolution characteristics and control mechanism of the gasification chamber under multi-field coupling conditions, and clarify the CO 2 storage and geological response of the gasification chamber. Laws of interaction.
6. Research on the mechanical mechanism of hot dry rock reservoir stimulation and the mechanism of fracture control and earthquake control (for application code 1, select the subordinate code of E04)
Construct a damage constitutive model of hot dry rock under high temperature and high pressure, study the stress corrosion effect and fatigue degradation mechanism of hot dry rock under the coupling effect of temperature and stress, and reveal the evolution characteristics of mechanical properties of hot dry rock reservoirs during reservoir stimulation and the earthquake induced by reservoir stimulation. Mechanical mechanism, analyze the influence of factors such as fluid pressure changes, fracturing crack expansion and reservoir rock rupture on induced earthquakes, and propose control methods for reservoir stimulation-induced earthquakes.
7. Research on new materials and mechanisms for ultra-low concentration methane absorption/adsorption in underground coal mines (for application code 1, select the subordinate code of E04)
Research new ultra-low concentration methane absorption/adsorption materials suitable for high-humidity and high-dust conditions in underground coal mine total return air flow, reveal ultra-low concentration methane absorption-analysis and adsorption-desorption mechanisms, and construct low-cost disposal and utilization methods for ultra-low concentration methane.
8. Research on the anti-permeability mechanism and drainage technology of long-distance horizontal well cross-layer fracturing on the roof and floor of soft, low-permeability, high-burst coal seams (for application code 1, select the subordinate code of E04)
Study the cross-mass propagation rules of hydraulic fracturing fractures in heterogeneous coal-rock formation combination structures, reveal the anti-permeability mechanism of long-distance horizontal well cross-layer fracturing on the roof and floor of soft, low-permeability, high-outbreak coal seams, construct an anti-permeability fracture spatial network model, and propose a composite Fracturing balanced anti-reflection technology and drainage technology are used to establish a three-dimensional anti-reflection effect evaluation method for soft and low-permeability coal seams.
9. Research on the mechanism and prevention technology of water and mud breakout in thick-layer soft water-containing/aquifer layer composite roof mining (for application code 1, select the subordinate code of E04)
Analyze the sedimentary environment characteristics of thick soft water-bearing/aquiclude layers, study the fracture and dynamic evolution mechanism of weakly cemented thick soft overlying rock under mining conditions, reveal the distribution of cracks in the outburst channel, the migration rules of muddy water and the initiation conditions of outburst, and establish the hazards Based on the performance evaluation model and evaluation mechanism, a prevention and control method for water and mud outburst disasters in thick-layer soft water-containing/water-isolating layer composite roof mining was proposed.
10. Research on the mechanism of roof dynamic disasters and intelligent monitoring and early warning methods under high-intensity mining conditions (for application code 1, select the subordinate code of E04)
Study the instability characteristics of overlying rock fractures under high-intensity mining conditions, reveal the dynamic response rules of coal and rock mass structures and the disaster-causing mechanism of roof dynamic disasters under high-intensity mining conditions, clarify the precursor information of roof dynamic disasters under high-intensity mining conditions, and propose Artificial intelligence roof dynamic disaster monitoring and early warning method based on precursor information.
11. Research on the multi-phase/multi-field/multi-time-space scale coupling rules and simulation technology of the electrolysis hydrogen production process (for application code 1, select the subordinate code of E06)
Study the coupling laws of electric, thermal, mass and other physical fields of electrolytic reactor devices at multi-time scales and multi-space scales in the electrolysis hydrogen production process, focusing on the controllable construction, failure modes and decay inducements of the gas-liquid-solid three-phase interface of the electrode, as well as the working fluid Dynamic visualization of flow patterns and instability modes are used to construct a large-scale, high-precision three-dimensional simulation model of the electrolytic reactor to guide state diagnosis and regulation.
12. Research on comprehensive energy capacity planning, simulation technology and regulation rules of multi-million-kilowatt new energy bases (for application code 1, select the subordinate code of E06)
Study complementary dynamic power generation power prediction methods such as wind, solar, and thermal power, establish high-precision simulation models of power generation and energy storage systems in new energy bases, and propose new energy base capacity planning and optimization methods; study the synergy rules of complementary multi-energy sources such as wind, solar, thermal, and hydrogen storage. Propose the regulation strategy and economic operation model of the new energy system integrating source, grid, load and storage to achieve zero abandonment of wind and light.
13. Basic research on ultra-high temperature solid medium heat storage materials for efficient solar energy utilization (for application code 1, select the subordinate code of E06)
Explore ultra-high-temperature solid medium heat storage/release systems suitable for the efficient utilization of next-generation solar energy; reveal the absorption spectrum matching of heat storage materials and the microscopic evolution mechanism of materials during the heat storage/release cycle; develop suitable for non-sealed environments and are easy to scale up. Ultra-high temperature solid dielectric material with high safety and long life.
14. Design and control method of high-efficiency high-inertia constant flywheel synchronous condenser (for application code 1, select the subordinate code of E06)
Construct a dynamic operation model of the flywheel synchronous condenser system, study the flywheel electromagnetic drive structure and control principle under large slip, reveal the electromechanical-electromagnetic sequential response characteristics of the “high-speed inertia flywheel-synchronous condenser”, and propose a vacuum high-speed inertia flywheel The integration method with the atmospheric pressure synchronous phase modulator forms the inertia support and active/reactive power coordinated operation control strategy of the flywheel synchronous phase modulator.
15. Research on the clean and efficient combustion mechanism of coal mixed with hydrogen/ammonia (for application code 1, select the subordinate code of E06)
Study the multi-component mixing, multi-field coupling combustion characteristics and reaction mechanism of coal-doped hydrogen/ammonia fuel, reveal the ignition-combustion-burnout rules of mixed fuel and the pollutant generation mechanism during the mixed combustion process, and construct a simplified reaction of coal-doped hydrogen/ammonia combustion Mechanism model and pollutant generation prediction model, develop high-precision numerical simulation methods for large-scale full-furnace multi-source fuel co-combustion, and establish a clean and efficient combustion organization method for multi-source fuel co-combustion.
16. Research on high-performance CO 2 coal-based physical adsorption materials (for application code 1, select the subordinate code of E06)
For the carbon capture of coal-fired power plant flue gas, carry out research on the pore structure and surface functional group directional design of high-performance CO 2 coal-based physical adsorption materials, clarify the precise control and optimization strategies for the two, and clarify the influence mechanism of this adsorption material on CO 2 adsorption and desorption , reveal the influence rules and mechanisms of typical impurities in coal power flue gas on material properties, and propose a preparation plan for anti-pollution, low-energy CO 2 coal-based physical adsorption materials.
17. Research on technology for grid-connected energy storage to support stable operation of a high proportion of new energy in the Three-North region (for application code 1, select the subordinate code of E07)
In view of the stability problem of the high proportion of new energy connected to the grid in the Three-North region, the network-type energy storage supports the stable operation mechanism of the high proportion of new energy connected to the grid and the influence on the transient steady state characteristics of the system, revealing the relationship between massive power electronic equipment and the power grid. interaction and oscillation mechanisms, establish theoretical methods for dynamic identification, prediction and reconstruction of impedance between equipment and between equipment and systems, and propose oscillation suppression and active support control theories and theories for different types of networked energy storage under extreme weather and fault conditions. Strategy.
18. Wide-bandwidth and stable operation of large-scale variable-speed pumped storage units and active support for power grid control strategies (for application code 1, select the subordinate code of E09)
For large-scale doubly-fed variable-speed pumped-storage units, the unit’s wide-bandwidth operation damage mechanism and optimal design are studied, multi-physics coupling analysis and transition process control strategies of the unit are proposed, and the grid adaptability evaluation method and system stability support technology are constructed.
(2) Electronic information field
Key support projects
China United Network Communications Co., Ltd
1. Key technologies for vehicle-road-cloud integrated traffic environment perception based on multi-modal fusion (for application code 1, select the subordinate code of F01)
In view of the lack of perception collaboration capabilities among multiple agents, including cars, roads, and clouds, and the insufficient perception accuracy of traffic scenes, we conduct research on the interoperability architecture and model of perception capabilities between multiple agents, and develop a variety of traffic solutions based on multi-modal fusion. Scene perception algorithm, build a real-time, intelligent perception processing closed-loop system for scene analysis, extraction, storage and data application, and conduct experimental verification.
2. Research on 5G-A/6G ultra-high reliability and low-latency network architecture and key technologies for the industrial control field (for application code 1, select the subordinate code of F01)
In response to the challenges of 5G-A/6G ultra-high reliability and ultra-low latency in the field of industrial control, research on cross-domain system integration and protocol design to achieve resource optimization of wireless and wired integration; research on the integration of industrial Ethernet protocols and communication protocols to promote different Seamless communication between industrial equipment and communication systems; research on key technologies for sub-millisecond latency and ultra-high reliability of seven nines, research on communication protocol optimization and system architecture adjustment solutions, and conduct simulation verification.
3. Research on digital twin modeling and self-optimization for ultra-wideband optical networks (for application code 1, select the subordinate code of F01)
In response to the needs for fine management and performance optimization in high-speed transmission systems, based on artificial intelligence technology and for large-scale, multi-band, ultra-high-speed optical networks, we study cross-level digital twin models that integrate networks, transmission systems, and services, and propose self-optimization algorithms and Management mechanism, testing and verification.
4. Research on the theory and technology of integrated synaesthesia optical network (for application code 1, select the subordinate code of F01)
In response to the needs of the development of deep synaesthesia integration in communication networks, we study the theory of synaesthesia integrated optical communication, build a channel model integrating high-speed transmission and multi-dimensional perception, propose a synaesthesia function crosstalk suppression method and a dynamic synaesthesia control mechanism, and design to support multiple points. Collaborative sensing mechanisms and control protocols support enhanced sensing capabilities compatible with multiple scenarios, and prototype systems are developed and verified.
5. Research on new broadband access technology integrating optical and millimeter waves (for application code 1, select the subordinate code of F01)
Facing future indoor ultra-high-bandwidth access needs, study the broadband access theory and technology of deep integration of optical and wireless, propose optical and millimeter-wave integrated transmission channel models, and form an automatic optimization algorithm for integrated communications, aiming at high throughput, low latency, etc. Scenario, conduct simulation and experimental verification.
6. Research on distributed intelligent network technology for diversified applications of 6G (for application code 1, select the subordinate code of F01)
Research the distributed intelligent network architecture, protocol system and key technologies for 6G diverse applications, including decentralized trusted distributed network architecture, network function reconstruction and interface simplification protocols, distributed subnet collaboration and intelligent autonomy mechanisms, Key technologies such as user demand sensing and user intention analysis are used to build a 6G distributed intelligent network prototype and carry out theoretical verification and performance evaluation in typical application scenarios.
7. Research on 5G-A/6G intelligent metasurface collaborative technology (for application code 1, select the subordinate code of F01)
Research the channel estimation and beamforming technology of smart metasurfaces under far-field and near-field conditions, conduct comparative analysis and simulation verification, and improve the ability of smart metasurfaces to accurately and dynamically control beams in real time; research smart metasurface networking solutions and interference control technology, Improve network quality and performance; research low-cost, extremely low-power technology solutions for intelligent metasurfaces.
8. Research on key technologies integrating large-scale antennas and synaesthesia for high-frequency communications (for application code 1, select the subordinate code of F01)
Research on coverage enhancement technologies such as ultra-large-scale antenna array high-frequency base station beam management and intelligent energy-saving methods to build a smart green high-frequency base station prototype; for interference problems in multi-band, multi-node, multi-sensing system collaborative synaesthesia fusion networks, study interference and resource allocation optimization theory, and carry out networking solutions and technical verification in complex environments.
9. Research on the endogenous theory and key technologies of future network intelligence (for application code 1, choose the subordinate code of F01 or F02)
Research the integrated architecture and technology system of fixed-mobile networks with endogenous intelligence, construct intelligent agents at the network element layer and network layer, study the collaboration, decision-making and evolution mechanisms between multi-agent agents, and establish multi-agent agents at the network control plane and forwarding plane. The large model improves the intelligence level of routing decision-making, network management, traffic classification and identification, and conducts theoretical verification and performance evaluation based on the bearer network and core network.
10. Research on IPv6 network endogenous security technology (for application code 1, choose the subordinate code of F01 or F02)
Explore the network security mechanism that integrates IPv6 with AI, blockchain and other technologies, study key technologies such as risk detection and identification, active security defense, and data security transmission of IPv6 networks, and form an IPv6 network endogenous security that integrates network-data-business technical system and carry out experimental verification.
11. Key security technologies for 6G new converged network (for application code 1, select the subordinate code of F02)
In view of the new security risks brought by the evolution of 6G network architecture, the diversification of business types, and the application of new technologies such as artificial intelligence and quantum computing, explore new security threat models of 6G networks, design a universal and evolvable 6G network security architecture, and research and adapt to The key security technologies of 6G new heterogeneous networks and security solutions for new scenarios such as space and earth integration promote the comprehensive integration of 6G security and services.
12. Research on future Internet technology system (for application code 1, choose the subordinate code of F02)
Research new network identification theoretical methods, decentralized identity authentication and authorization mechanisms, etc., to enhance the credibility of network transmission; research data cross-platform (intermediary) multi-hop collaborative architecture driven by data identification to form intelligent data interaction and distribution capabilities; research Intelligent management and control theoretical methods realize dynamic allocation and management of network, VNF, computing and other resources. Conduct experiments and technical verification.
13. Research on network traffic optimization and scheduling technology for large-scale intelligent computing centers (for application code 1, select the subordinate code of F02)
To meet the demand for high-speed and lossless transmission of large-scale RDMA traffic in intelligent computing centers, research on the theory and method of network traffic optimization management and control of intelligent computing centers with end-network integration and photoelectric collaboration; research on congestion control theory and methods for RDMA traffic to improve network utilization and reduce transmission time. Yan; study the characteristics of RDMA traffic in the intelligent computing center, propose new load balancing theoretical methods, and optimize the distribution of large-scale RDMA traffic in the network; conduct experiments and technical verification.
14. Research on high-performance wide-area networks for computing power and data interconnection (for application code 1, choose the subordinate code of F02)
Facing the complex interaction and transmission requirements of high-throughput computing power and data, a high-performance transmission mechanism model for the integration of computing power and data is proposed to study the heterogeneous ubiquitous wide-area lossless computing fusion transmission mechanism; high-performance massive data for new application scenarios For performance transmission requirements, study transmission protocol optimization models such as adaptive flow control, end-network collaborative transmission, and congestion control; conduct experimental verification of transmission in typical wide-area scenarios.
15. Research on new Internet deterministic networking and protocols (for application code 1, choose the subordinate code of F02)
Facing the low-latency and low-jitter transmission requirements of industrial control, Metaverse & , to meet the cross-domain end-to-end deterministic carrying requirements, and conduct simulation and experimental verification.
16. Key technologies for multi-scenario all-day integrated communication and integration services (for application code 1, select the subordinate code of F03)
Research the theoretical methods of communication and navigation fusion system modeling based on key systems such as 5G, Beidou and low-orbit satellites, establish a system framework for unified spatiotemporal information, study dynamic adaptive fusion positioning technology, and build heterogeneous communication, navigation, and perception information fusion and Evaluation system to achieve high reliability, multi-scenario all-day communication and navigation integrated service system.
17. Research on general AIGC counterfeit content detection methods and key technologies (for application code 1, select the subordinate code of F06)
In response to the threat of the rapid development of AIGC content forgery technology, a universal AIGC counterfeit content detection method with continuous learning capabilities is studied, the characteristic boundary between AIGC content and real content is explored, the continuous evolution of the AIGC counterfeit content detection model is realized, and the detection method of fake text and speech is formed. , continuous identification ability of image and video content.
18. Research on efficient, accurate and low-complexity multi-modal large model network structure (application code 1, select the subordinate code of F06)
Research low-complexity multimodal network structures that are friendly to long sequence inputs, explore efficient and accurate representation methods of multimodal features, and implement new multimodal network model prototype systems to solve the current problem of limited input length of large multimodal models. Image feature extraction accuracy requires high accuracy, and the model is limited by the size/resolution of the training window.
19. Research on key technologies for safe and reliable large-scale speech generation models with high expressiveness (application code 1, select the subordinate code of F06)
Study the theoretical method of decoupling speech content, rhythm, timbre and style, and realize a large speech generation model with contextual learning ability and high expressiveness, which can generate high similarity, high expressiveness and controllable emotion based on few sample or zero sample data. Multi-language synthetic speech; research on safe and trustworthy technology for large speech generation models, achieve value alignment during the generation process, and provide safe and trustworthy evaluation methods for bias and toxicity detection.
2. Application requirements
(1) Applicant conditions.
Applicants should meet the following conditions:
1. Have experience in undertaking basic research projects or other basic research;
2. Hold senior professional and technical positions (professional titles);
Postdoctoral researchers at the station, those who are pursuing a graduate degree, and those who do not have an employer or whose unit is not a supporting unit are not allowed to apply as applicants.
(2) Regulations on limited applications.
Implement the relevant requirements of the limited application provisions in the “Application Regulations” of the “2024 National Natural Science Foundation of China Project Guide”.
3. Things to note when applying
Applicants and supporting institutions should carefully read and implement the relevant requirements in this project guide, the “2024 National Natural Science Foundation of China Project Guide” and the “Notice on 2024 National Natural Science Foundation of China Project Application and Finalization and Other Related Matters”.
1. This joint fund project adopts paperless application. The application submission time is from April 15 to 16:00 on April 20, 2024.
2. This joint fund is open to the whole country and competes fairly. Applicants are encouraged to conduct collaborative research with R&D institutions affiliated with co-sponsors. For cooperative research projects, the cooperation content and main division of labor of the cooperating parties should be clearly stated in the application. The number of cooperative research units for integrated projects shall not exceed 4, and the number of cooperative research units for key support projects shall not exceed 2.
3. Applicants can only apply for one Enterprise Innovation and Development Joint Fund project in the same year.
4. The applicant logs in to the National Natural Science Foundation of China Network Information System (referred to as the information system) and writes the application online. Applicants who do not have an information system account should apply to the fund management contact person of the supporting unit to open an account.
5. Select “Joint Fund Project” for the funding category in the application form, select “Integrated Project” or “Key Support Project” for the subcategory description, and select “Enterprise Innovation and Development Joint Fund” for “Notes”; “Application Code 1” should be as follows This joint fund project guide requires selection. “Application Code 2” independently selects the corresponding application code according to the project research field; “Field Information” selects the corresponding field name according to the project research field, such as “Energy and Chemical Industry”; “Main Research Direction” “Select the corresponding direction name according to the research direction of the project, such as “1. Research on enhanced CO 2 activation and reduction technology through coupling of plasma and catalyst materials”, and the research period should be filled in as “January 1, 2025 – December 31, 2028”.
6. The applied project should comply with the funding scope and requirements of this project guide. Applicants write applications according to the project application writing outline. If the applicant has already undertaken other national science and technology plan projects related to this joint fund project, the differences and connections between the applied project and other related projects should be discussed in the “Research Basis and Working Conditions” section of the main body of the application.
7. The research results obtained by funded projects, including published papers, monographs, research reports, software, patents, awards and achievement reports, etc., should indicate the project funding and project approval number of the National Natural Science Foundation of China Enterprise Innovation and Development Joint Fund or make relevant illustrate. The National Natural Science Foundation of China, together with two companies including China National Energy Group and China Unicom, jointly promote project data sharing and the promotion and application of research results.
8. The host unit shall complete the host unit’s commitment letter, organization application, and review of application materials as required. Submit the unit’s electronic application and attachment materials through the information system item by item before 16:00 on April 20, 2024, and submit the unit’s project application list online before 16:00 on April 21.
Contact information
National Natural Science Foundation of China Planning and Policy Bureau
Contact person: Li Zhilan Liu Quan
Tel: 010-62329897, 62326872
Science and Technology and Information Technology Department of National Energy Investment Group Co., Ltd.
Contact person: Yan Xiaohui Zhang Yong
Tel: 010-57337626
Science and Technology Innovation Department of China United Network Communications Co., Ltd.
Contact person: Zhou Xiaoxia Liu Di
Tel: 010-66259300, 66258330