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The Global Market for Non-Graphene 2D Materials https://marketpublishers.com/r/G5580C8AD94FEN.html Date: June 2021 Pages: 125 Price: US$ 700.00 (Single User License) ID: G5580C8AD94FEN

Abstracts

Due to its exceptional transport, mechanical and thermal properties, has been at the forefront of research over the past few years. Its development has enabled researchers to explore other 2D layered materials, such as the transition metal dichalcogenides (TMD), a wide variety of oxides and nitrides and clays. Several types are now commercially available from advanced materials producers.

2D materials covered in this report include:

transition metal dichalcogenides (TMD).

hexagonal boron nitride (h-BN).

MXenes.

.

phosphorene.

graphitic carbon nitride.

graphane.

graphdiyne.

stanene/tinene.

The Global Market for Non-Graphene 2D Materials +44 20 8123 2220 [email protected]

tungsten diselenide.

rhenium disulfide.

diamene.

.

antimonene.

indium selenide.

layered double hydroxides.

Report contents include:

Properties of 2D materials.

Applications of 2D materials.

Addressable markets for 2D materials.

Production and pricing of 2D materials.

Profiles of 2D materials producers and suppliers.

The Global Market for Non-Graphene 2D Materials +44 20 8123 2220 [email protected]

Contents

1 INTRODUCTION

1.1 What are 2D materials? 1.2 Exceptional properties 1.3 Comparative analysis of graphene and other 2D materials 1.4 Commercial opportunities

2 TYPES OF 2D MATERIALS

2.1.1 Layered van der Waals solids 2.1.2 Layered ionic solids 2.1.3 Surface-assisted elemental nanolayered solids

3 2D MATERIALS PRODUCTION METHODS

3.1 Top-down exfoliation 3.2 Bottom-up synthesis

4 HEXAGONAL BORON-NITRIDE (H-BN)

4.1 Properties 4.2 Applications and markets 4.2.1 Electronics 4.2.2 Fuel cells 4.2.3 Adsorbents 4.2.4 Photodetectors 4.2.5 Textiles 4.2.6 Biomedical 4.3 Market opportunity for hexagonal boron-nitride

5 MXENES

5.1 Properties 5.2 Applications 5.2.1 Catalysts 5.2.2 Hydrogels 5.2.3 Energy storage devices

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5.2.3.1 Electrodes for Li-ion batteries 5.2.3.2 Na-ion batteries 5.2.3.3 Supercapacitors 5.2.4 Sensors 5.2.4.1 Wearable sensors 5.2.4.2 Stain sensors 5.2.4.3 Pressure sensors 5.2.4.4 Biosensors 5.2.4.5 Gas sensors 5.2.5 Adsorbents 5.2.6 Membrane separation 5.3 Market opportunity for MXenes

6 TRANSITION METAL DICHALCOGENIDES

6.1 Properties 6.1.1 Molybdenum disulphide (MoS2) 6.1.2 Tungsten ditelluride (WTe2) 6.2 Applications 6.2.1 Electronics 6.3 Properties 6.4 Applications 6.4.1 Electronics 6.4.2 Photovoltaics 6.4.3 Electrocatalysis 6.4.4 Piezoelectrics 6.4.5 Sensors 6.4.6 Filtration 6.4.7 Batteries and supercapacitors 6.4.8 Fiber lasers 6.5 Market opportunity for TMDs

7 BOROPHENE

7.1 Properties 7.2 Applications 7.2.1 Energy storage 7.2.2 Electronics 7.2.3 Sensors

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7.2.4 Hydrogen storage 7.3 Market opportunity for borophene

8 PHOSPHORENE

8.1 Properties 8.1.1 Fabrication methods 8.1.2 Challenges for the use of phosphorene in devices 8.2 Applications 8.2.1 Electronics 8.2.2 Field effect 8.2.3 Batteries 8.2.3.1 Lithium-ion batteries (LIB) 8.2.3.2 Sodium-ion batteries 8.2.3.3 Lithium–sulfur batteries 8.2.4 Supercapacitors 8.2.5 Photodetectors 8.2.6 Sensors 8.3 Market opportunity for phosphorene

9 GRAPHITIC CARBON NITRIDE (G-C3N4)

9.1 Properties 9.2 Synthesis 9.3 C2N 9.4 Applications 9.4.1 Electronics 9.4.2 Filtration membranes 9.4.3 Photocatalysts 9.4.4 Batteries 9.4.5 Sensors 9.5 Market opportunity for graphitic carbon nitride

10 GERMANENE

10.1 Properties 10.2 Applications 10.2.1 Electronics 10.2.2 Batteries

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10.3 Market opportunity for germanene

11 GRAPHDIYNE

11.1 Properties 11.2 Applications 11.2.1 Electronics 11.2.2 Batteries 11.2.2.1 Lithium-ion batteries (LIB) 11.2.2.2 Sodium ion batteries 11.2.3 Separation membranes 11.2.4 Water filtration 11.2.5 Photocatalysts 11.2.6 Photovoltaics 11.3 Market opportunity for graphdiyne

12 GRAPHANE

12.1 Properties 12.2 Applications 12.2.1 Electronics 12.2.2 Hydrogen storage 12.3 Market opportunity for graphane

13 RHENIUM DISULFIDE (RES2) AND DISELENIDE (RESE2)

13.1 Properties 13.2 Applications 13.2.1 Electronics 13.3 Market opportunity for rhenium disulfide (ReS2) and diselenide (ReSe2)

14 SILICENE

14.1 Properties 14.2 Applications 14.2.1 Electronics 14.2.2 Photovoltaics 14.2.3 Thermoelectrics 14.2.4 Batteries

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14.2.5 Sensors 14.3 Market opportunity for silicene

15 STANENE/TINENE

15.1 Properties 15.2 Applications 15.2.1 Electronics 15.3 Market opportunity for stanine/tinene

16 ANTIMONENE

16.1 Properties 16.2 Applications 16.3 Market opportunity for antimonene

17 DIAMENE

17.1 Properties 17.2 Applications 17.3 Market opportunity for diamene

18 INDIUM SELENIDE

18.1 Properties 18.2 Applications 18.2.1 Electronics 18.3 Market opportunity for indium selenide

19 LAYERED DOUBLE HYDROXIDES

19.1 Properties 19.2 Applications 19.2.1 Environmental 19.2.2 Hydrogen generation 19.2.3 Supercapacitors 19.2.4 Batteries 19.2.5 Photovoltaics 19.2.6 Catalysis

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19.2.7 Biomaterials 19.3 Market opportunity for layered double hydroxides

20 2D MATERIALS PRODUCER AND SUPPLIER PROFILES

21 RESEARCH METHODOLOGY

21.1 Technology Readiness Level (TRL)

22 REFERENCES

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Tables

TABLES

Table 1. Comparative analysis of graphene and other 2-D nanomaterials. Table 2. Applications analysis of 2D materials. Table 3. 2D materials types. Table 4. Comparison of top-down exfoliation methods to produce 2D materials. Table 5. Comparison of the bottom-up synthesis methods to produce 2D materials. Table 6. 2D Materials production methods. Table 7. Applications of MXenes. Table 8. TRL for transition metal dichalcogenides (TMD). Table 9. Electronic and mechanical properties of monolayer phosphorene, graphene and MoS2. Table 10. Prices of commercially available 2D materials. Table 11. Technology Readiness Level (TRL) Examples.

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Figures

FIGURES

Figure 1. Schematic of 2-D materials. Figure 2. Structure of hexagonal boron nitride. Figure 3. BN nanosheet textiles application. Figure 4. TRL for hexagonal boron-nitride. Figure 5. Structure diagram of Ti3C2Tx. Figure 6. TRL for MXenes. Figure 7. Left: Molybdenum disulphide (MoS2). Right: Tungsten ditelluride (WTe2) Figure 8. SEM image of MoS2. Figure 9. image of a representative MoS2 thin-film . Figure 10. Schematic of the molybdenum disulfide (MoS2) thin-film sensor with the deposited molecules that create additional charge. Figure 11. Borophene schematic. Figure 12. TRL for hexagonal borophene. Figure 13. Black structure. Figure 14. Black Phosphorus crystal. Figure 15. Bottom gated flexible few-layer phosphorene transistors with the hydrophobic dielectric encapsulation. Figure 16. TRL for hexagonal phosphorene. Figure 17: Graphitic carbon nitride. Figure 18. Structural difference between graphene and C2N-h2D crystal: (a) graphene; (b) C2N-h2D crystal. Credit: Ulsan National Institute of Science and Technology. Figure 19. TRL for Graphitic carbon nitride. Figure 20. Schematic of germanene. Figure 21. TRL for Germanene. Figure 22. Graphdiyne structure. Figure 23. TRL for Graphdiyne. Figure 24. Schematic of Graphane crystal. Figure 25. TRL for Graphane. Figure 26. Schematic of a monolayer of rhenium disulfide. Figure 27. TRL for rhenium disulfide (ReS2) and diselenide (ReSe2). Figure 28. Silicene structure. Figure 29. Monolayer silicene on a silver (111) substrate. Figure 30. Silicene transistor. Figure 31. TRL for silicene. Figure 32. Crystal structure for stanene.

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Figure 33. Atomic structure model for the 2D stanene on Bi2Te3(111). Figure 34. TRL for Stanene/tinene. Figure 35. TRL for Antimonene Figure 36. TRL for diamene. Figure 37. Schematic of Indium Selenide (InSe). Figure 38. TRL for indium selenide. Figure 39. TRL for layered double hydroxides.

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