サマリー
この調査レポートはスマートシティの先進材料市場を調査し、交通機関、水環境のトレンド、ゼロエミッションなどについて詳細に調査・分析しています。
主な掲載内容(目次より抜粋)
-
全体概要および結論
-
はじめに
-
建物、車両、部品の3Dプリント用材料、3Dエレクトロニクス
-
多機能複合材料と構造エレクトロニクス
-
スマートガラス、透明スマートプラスチック、スマートとグリーンコンクリート
Report Details
Smart cities are now much more ambitious. That means new materials are their biggest enabler, with information and computer technology dropping to an important support role. In its lucid information-packed 340 pages, the IDTechEx report, "Smart Cities Emerging Materials Markets 2021-2041" explains. Researched by IDTechEx multilingual PhD level analysts across the world and constantly updated, the emphasis of the report is commercial opportunities and benefits to society. No nostalgia and no academic obscurity. Many new billion-dollar businesses will be created from this emerging market of hundreds of billions of dollars yearly for largely new materials for new requirements.
Consider the $0.5 trillion NEOM smart city being reclaimed from the Saudi desert and the $0.1 trillion Forest City being reclaimed from the Malaysian sea. Forest City names smart materials as pivotal.
Zero-emission smart cities will gain energy, food and water independence. That means materials requirements for far-away power stations, hydro dams, reservoirs, oil, gas and coal extraction and their long supply lines to cities will increasingly be replaced materials requirements for the very different city alternatives such as solar everywhere, gravity storage using green concrete, open-water power, better self-powered desalination. Materials supply lines get shorter, involve different materials and end up at different customers. Time to pay attention!
Adaptable energy-positive buildings will make food and electricity and human activities while treating their own sewage but only if environmental, affordable new materials are forthcoming. The city robot shuttles replacing up to ten existing vehicles have special materials with more to come, partly because some are 3D printed and some replace dumb windows and bodywork with electrically- and optically-multifunctional materials and dock sideways. This is definitely not a story of selling the same old stuff more to cities in future.
This report answers questions such as
-
Objectives and potential of smart cities and material companies involved
-
Which are spending the big money and what is their materials focus?
-
What 50 gaps exist in the city materials market and what are the possible solutions?
-
What are the big materials failures that I can solve to create large sales?
-
Which can create billion-dollar businesses?
-
Relevant 20-year forecasts and roadmaps resulting from the research?
-
Why are water-related and multifunctional materials increasingly important?
-
Materials for 3D printing of city buildings, robot shuttles, motors, parts, 3DP electronics?
-
Multifunctional composites and structural electronics for cities. What becomes possible?
-
Smart glass, transparent smart plastic, transparent, magnetic and green concrete?
-
Flexible organics, membranes, bioplastics, advanced polymers for cities?
-
Thermal interface materials and thermal insulation challenges in cities?
-
2D and 3D molecules, graphene, CNT applications in cities?
-
Materials for 5G, 6G and THz electronics in cities 2021-2041?
-
Why so many materials needed for photovoltaics beyond silicon? Where? Why?
-
What newly-possible recycling underwrites success?
The 99 page Executive Summary and Conclusions is sufficient for those in a hurry. It presents new infograms, comparison tables and graphics with 13 primary conclusions. 70 forecasts are on further pages. The extensive Introduction explains smart cities and their reinvented transport, buildings and trends to water environments, simplification, moveable equipment, zero-emission throughout. This is all in the context of the next twenty years.
Chapter 3 concerns materials for 3D printing of buildings, vehicles such as the Olli city robot shuttle and 3DP electronics.
Chapter 4 addresses multifunctional composites and structural electronics for future cities.
Chapter 5 explains and forecasts the surprisingly varied and large requirements for smart glass, transparent smart plastic such as headlamp RadarGlass™ and the new microLED billboards and windows. Transparent, magnetic and green concrete variously enable city buildings, bridges, solar roads, charge vehicles in motion and make recyclable long-term storage and more but with mixed results. Your opportunity?
Chapter 6 focuses on flexible organics, membranes for the widespread sensors, energy storage, fuel cells. It reveals new bioplastics and advanced polymers. Their new virtuosity addresses both electronics and electrical engineering challenges, recyclability, biodegradability, multifunctionality.
Chapter 7 Thermal interface materials TIM are conductive and thermal insulation the opposite, these deserving a chapter because so many opportunities arise from so many unmet needs here.
Chapter 8 analyses which 2D and 3D molecules such as graphene, CNT and MXenes are enabling future energy harvesting, energy storage, even self-healing, energy-storing vehicle bodywork.
Chapter 9 acknowledges the pervasive rollout of 5G communications now and then 6G starting 2030-2035 at terahertz frequencies and indeed the new THz electronics in general from a materials viewpoint because most rollout and innovation will to the requirements of cities.
Chapter 10 concerns the many materials and formats emerging for ubiquitous photovoltaic power in cities from solar roads, plazas, buses and boats to facades, windows, solar paint, agrivoltaics, floatovoltaics and tracking lll-V solar.
Chapter 11 concerns newly possible recycling benefitting the environment and making certain materials more acceptable. That include plastics, even fluoropolymers, next batteries and next wind turbine blades.
Most of the largest cities are on the sea or a large river and, with rising sea levels, more will be water-based. Threads running through all the chapters are trends to cities spending heavily on water-related activities from supply and conservation of clean water in desert cities to the more common cities in, by and on water. They will use sea and river water for drinking, fish and vegetable cultivation, leisure, transport, power and more. Learn gaps in these markets such as materials for wave power not destroyed by storms and buildings surviving rising sea levels. Learn why multifunctional materials, components, systems and infrastructure are also a common theme for all smart cities. There you can prosper. The report comes with 30 minutes free consultancy to fill in the gaps.
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目次
|
1. |
EXECUTIVE SUMMARY AND CONCLUSIONS |
|
1.1. |
Purpose and scope of this report |
|
1.1.1. |
Who it assists |
|
1.1.2. |
Scope: 34 emerging material families prioritised |
|
1.2. |
Infogram: Some materials in future zero-emission smart cities |
|
1.3. |
Infogram: Some materials companies transforming future zero-emission cities |
|
1.4. |
Infogram: Next smart city devices in action |
|
1.5. |
Some pervasive emerging materials for smart cities |
|
1.6. |
Emerging photovoltaic technology |
|
1.7. |
Electrical device membranes |
|
1.8. |
Cognitive responsive smart materials |
|
1.9. |
Multifunctional polymer composites |
|
1.10. |
Structural electronics |
|
1.11. |
Research interest in reshapable smart materials for electronics and electrics by application |
|
1.12. |
Primary conclusions |
|
1.13. |
70 Market forecasts |
|
1.13.1. |
Multifunctional composite forecasts 2012-2029 |
|
1.13.2. |
Fluoropolymers for electronics and electrics value market 2031: by primary applications |
|
1.13.3. |
Fluoropolymers for electronics and electrics value market 2031 by primary application |
|
1.13.4. |
Thermal interface materials TIM forecast |
|
1.13.5. |
Market forecast: TIM for EV battery packs |
|
1.13.6. |
Market forecast: TIM for power electronic modules |
|
1.13.7. |
Market forecast: TIM in LED for general lighting |
|
1.13.8. |
Market forecast: TIM in 4G/LTE base stations |
|
1.13.9. |
Market forecast: TIM for consumer electronics |
|
1.13.10. |
Graphene market breakdown by revenue and volume |
|
1.13.11. |
Market forecast for metals for 3DP |
|
1.13.12. |
Metal 3DP market forecast - industry segmentation |
|
1.13.13. |
Metal 3DP material forecast - technology segmentation |
|
1.13.14. |
Metal for 3DP forecast - alloy segmentation |
|
1.13.15. |
Low-loss materials forecast in 5G by revenue |
|
1.13.16. |
Low-loss materials areas forecast in 5G by frequency |
|
1.13.17. |
Low-loss materials areas forecast in 5G by market segments |
|
1.13.18. |
Low-loss materials areas forecast in 5G by types of materials |
|
1.13.19. |
Low-loss materials areas forecast in 5G base station by materials types |
|
1.13.20. |
Low-loss materials areas forecast in 5G smartphones by material types |
|
1.13.21. |
Low-loss materials areas forecast in 5G CPE, hotspots by material types |
|
1.13.22. |
Global capacity of Li-ion batteries for recycling by territory 2020-2040 (GWh) |
|
1.13.23. |
Global Li-ion batteries available for recycling 2020-2040: by region (tonnes) - summary |
|
1.13.24. |
Global Li-ion batteries available for recycling 2020-2040: by chemistry (tonnes) |
|
1.13.25. |
Global Li-ion batteries available for recycling 2020-2040: by chemistry (tonnes) - summary |
|
1.13.26. |
Global recycled metals from Li-ion batteries 2020-2040 (tonnes) |
|
1.13.27. |
Global recycled metals from Li-ion batteries 2020-2040 (tonnes) |
|
1.13.28. |
Global Li-ion battery recycling market value forecast 2020-2040 ($ million) |
|
1.13.29. |
Global plastics production to grow to 485 Mt in 2028 |
|
1.13.30. |
Historical management of municipal solid waste |
|
1.13.31. |
Flexible CIGS: market forecast sqm and value by barrier technology |
|
1.13.32. |
Conductive inks and pastes split by 30 application areas 2020-2030 |
|
1.13.33. |
Forecasts for all conductive inks and pastes by application |
|
1.13.34. |
Forecasts in tonnes for all conductive inks and pastes split by application |
|
1.13.35. |
Forecasts printed sensors (piezoresistive, glucose, capacitive, touch edge electrode, ITO replacement, etc.) |
|
1.13.36. |
Forecasts for conformal metallization (aerosol and package-level conformal EMI coating) |
|
1.13.37. |
Printed electronics forecasts by component 2020-2030 |
|
1.13.38. |
Printed electronics components and materials 2020-2030 |
|
1.13.39. |
Total market value of printed versus non-printed electronics 2020-2030 |
|
1.13.40. |
Market size of Flexible/ Conformation Electronics 2020-2030 |
|
1.13.41. |
Market size of Flexible/ Conformation Electronics 2020-2030 |
|
1.13.42. |
Market value of flexible/conformal versus rigid electronics |
|
1.13.43. |
Transparent conducting film or glass markets by application |
|
1.13.44. |
Global plastics production 1950-2030 |
|
1.13.45. |
Market forecast: Thermal interface materials TIM in LED for automotive |
|
1.13.46. |
TIM forecast for power supplies |
|
1.13.47. |
Market forecast: TIM in LED for displays |
|
1.13.48. |
Global market for thin film CIGS photovoltaics $ billion and GWp 2020-2040 |
|
1.13.49. |
Global market for thin film CIGS photovoltaics GWp 2020-2030 |
|
1.13.50. |
Global market for thin film CIGS photovoltaics $ billion 2020-2030 |
|
1.13.51. |
Global market for lll-V compound semiconductor PV $ billion and GWp 2020-2040 |
|
1.13.52. |
Global market for lll-V compound semiconductor PV GWp 2020-2030 |
|
1.13.53. |
Global market for lll-V compound semiconductor PV $ billion 2020-2030 |
|
1.13.54. |
Global PV technology share $bn % 2040 |
|
1.13.55. |
Global revenues from polymer recycling |
|
1.13.56. |
Global capacity of Li-ion batteries available for recycling 2020-2040 (GWh) |
|
1.13.57. |
Global Li-ion batteries available for recycling 2020-2040: by region (tonnes) |
|
1.13.58. |
Global Li-ion batteries available for recycling by chemistry in major regions |
|
1.13.59. |
Global Li-ion battery recycling market value forecast by region 2020-2040 ($ million) |
|
1.14. |
Global market for perovskite PV $M |
|
1.15. |
Global market for organic photovoltaics OPV $M |
|
1.16. |
Roadmap for 88 advanced materials in smart cities 2021-2050 |
|
2. |
INTRODUCTION |
|
2.1. |
Smart cities |
|
2.2. |
Forest City Malaysia has $0.1 trillion to spend |
|
2.3. |
Cognitive responsive infrastructure |
|
2.4. |
Sensors throughout smart cities |
|
2.5. |
Green technologies merging and doing less damage |
|
2.6. |
Materials implications of smart cities becoming water-centric |
|
2.6.1. |
Treat sewage at source |
|
2.6.2. |
Floating cities? |
|
2.7. |
Solar everywhere: examples |
|
2.7.1. |
Agrivoltaics |
|
2.7.2. |
Gap in market for solar roads: inadequate materials |
|
2.7.3. |
Light duty ground solar succeeds |
|
2.7.4. |
Solar boats and airports |
|
2.7.5. |
Flexible CIGS PV to the rescue: MIT USA in Puerto Rico |
|
2.8. |
Microgrids become minimal intermittency and relocatable |
|
2.9. |
Food independent cities overview |
|
2.10. |
Aquaponics: fish and vegetables together in sea and building |
|
2.11. |
Robotics and reinvented transport overview |
|
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Summary
この調査レポートはスマートシティの先進材料市場を調査し、交通機関、水環境のトレンド、ゼロエミッションなどについて詳細に調査・分析しています。
主な掲載内容(目次より抜粋)
-
全体概要および結論
-
はじめに
-
建物、車両、部品の3Dプリント用材料、3Dエレクトロニクス
-
多機能複合材料と構造エレクトロニクス
-
スマートガラス、透明スマートプラスチック、スマートとグリーンコンクリート
Report Details
Smart cities are now much more ambitious. That means new materials are their biggest enabler, with information and computer technology dropping to an important support role. In its lucid information-packed 340 pages, the IDTechEx report, "Smart Cities Emerging Materials Markets 2021-2041" explains. Researched by IDTechEx multilingual PhD level analysts across the world and constantly updated, the emphasis of the report is commercial opportunities and benefits to society. No nostalgia and no academic obscurity. Many new billion-dollar businesses will be created from this emerging market of hundreds of billions of dollars yearly for largely new materials for new requirements.
Consider the $0.5 trillion NEOM smart city being reclaimed from the Saudi desert and the $0.1 trillion Forest City being reclaimed from the Malaysian sea. Forest City names smart materials as pivotal.
Zero-emission smart cities will gain energy, food and water independence. That means materials requirements for far-away power stations, hydro dams, reservoirs, oil, gas and coal extraction and their long supply lines to cities will increasingly be replaced materials requirements for the very different city alternatives such as solar everywhere, gravity storage using green concrete, open-water power, better self-powered desalination. Materials supply lines get shorter, involve different materials and end up at different customers. Time to pay attention!
Adaptable energy-positive buildings will make food and electricity and human activities while treating their own sewage but only if environmental, affordable new materials are forthcoming. The city robot shuttles replacing up to ten existing vehicles have special materials with more to come, partly because some are 3D printed and some replace dumb windows and bodywork with electrically- and optically-multifunctional materials and dock sideways. This is definitely not a story of selling the same old stuff more to cities in future.
This report answers questions such as
-
Objectives and potential of smart cities and material companies involved
-
Which are spending the big money and what is their materials focus?
-
What 50 gaps exist in the city materials market and what are the possible solutions?
-
What are the big materials failures that I can solve to create large sales?
-
Which can create billion-dollar businesses?
-
Relevant 20-year forecasts and roadmaps resulting from the research?
-
Why are water-related and multifunctional materials increasingly important?
-
Materials for 3D printing of city buildings, robot shuttles, motors, parts, 3DP electronics?
-
Multifunctional composites and structural electronics for cities. What becomes possible?
-
Smart glass, transparent smart plastic, transparent, magnetic and green concrete?
-
Flexible organics, membranes, bioplastics, advanced polymers for cities?
-
Thermal interface materials and thermal insulation challenges in cities?
-
2D and 3D molecules, graphene, CNT applications in cities?
-
Materials for 5G, 6G and THz electronics in cities 2021-2041?
-
Why so many materials needed for photovoltaics beyond silicon? Where? Why?
-
What newly-possible recycling underwrites success?
The 99 page Executive Summary and Conclusions is sufficient for those in a hurry. It presents new infograms, comparison tables and graphics with 13 primary conclusions. 70 forecasts are on further pages. The extensive Introduction explains smart cities and their reinvented transport, buildings and trends to water environments, simplification, moveable equipment, zero-emission throughout. This is all in the context of the next twenty years.
Chapter 3 concerns materials for 3D printing of buildings, vehicles such as the Olli city robot shuttle and 3DP electronics.
Chapter 4 addresses multifunctional composites and structural electronics for future cities.
Chapter 5 explains and forecasts the surprisingly varied and large requirements for smart glass, transparent smart plastic such as headlamp RadarGlass™ and the new microLED billboards and windows. Transparent, magnetic and green concrete variously enable city buildings, bridges, solar roads, charge vehicles in motion and make recyclable long-term storage and more but with mixed results. Your opportunity?
Chapter 6 focuses on flexible organics, membranes for the widespread sensors, energy storage, fuel cells. It reveals new bioplastics and advanced polymers. Their new virtuosity addresses both electronics and electrical engineering challenges, recyclability, biodegradability, multifunctionality.
Chapter 7 Thermal interface materials TIM are conductive and thermal insulation the opposite, these deserving a chapter because so many opportunities arise from so many unmet needs here.
Chapter 8 analyses which 2D and 3D molecules such as graphene, CNT and MXenes are enabling future energy harvesting, energy storage, even self-healing, energy-storing vehicle bodywork.
Chapter 9 acknowledges the pervasive rollout of 5G communications now and then 6G starting 2030-2035 at terahertz frequencies and indeed the new THz electronics in general from a materials viewpoint because most rollout and innovation will to the requirements of cities.
Chapter 10 concerns the many materials and formats emerging for ubiquitous photovoltaic power in cities from solar roads, plazas, buses and boats to facades, windows, solar paint, agrivoltaics, floatovoltaics and tracking lll-V solar.
Chapter 11 concerns newly possible recycling benefitting the environment and making certain materials more acceptable. That include plastics, even fluoropolymers, next batteries and next wind turbine blades.
Most of the largest cities are on the sea or a large river and, with rising sea levels, more will be water-based. Threads running through all the chapters are trends to cities spending heavily on water-related activities from supply and conservation of clean water in desert cities to the more common cities in, by and on water. They will use sea and river water for drinking, fish and vegetable cultivation, leisure, transport, power and more. Learn gaps in these markets such as materials for wave power not destroyed by storms and buildings surviving rising sea levels. Learn why multifunctional materials, components, systems and infrastructure are also a common theme for all smart cities. There you can prosper. The report comes with 30 minutes free consultancy to fill in the gaps.
ページTOPに戻る
Table of Contents
|
1. |
EXECUTIVE SUMMARY AND CONCLUSIONS |
|
1.1. |
Purpose and scope of this report |
|
1.1.1. |
Who it assists |
|
1.1.2. |
Scope: 34 emerging material families prioritised |
|
1.2. |
Infogram: Some materials in future zero-emission smart cities |
|
1.3. |
Infogram: Some materials companies transforming future zero-emission cities |
|
1.4. |
Infogram: Next smart city devices in action |
|
1.5. |
Some pervasive emerging materials for smart cities |
|
1.6. |
Emerging photovoltaic technology |
|
1.7. |
Electrical device membranes |
|
1.8. |
Cognitive responsive smart materials |
|
1.9. |
Multifunctional polymer composites |
|
1.10. |
Structural electronics |
|
1.11. |
Research interest in reshapable smart materials for electronics and electrics by application |
|
1.12. |
Primary conclusions |
|
1.13. |
70 Market forecasts |
|
1.13.1. |
Multifunctional composite forecasts 2012-2029 |
|
1.13.2. |
Fluoropolymers for electronics and electrics value market 2031: by primary applications |
|
1.13.3. |
Fluoropolymers for electronics and electrics value market 2031 by primary application |
|
1.13.4. |
Thermal interface materials TIM forecast |
|
1.13.5. |
Market forecast: TIM for EV battery packs |
|
1.13.6. |
Market forecast: TIM for power electronic modules |
|
1.13.7. |
Market forecast: TIM in LED for general lighting |
|
1.13.8. |
Market forecast: TIM in 4G/LTE base stations |
|
1.13.9. |
Market forecast: TIM for consumer electronics |
|
1.13.10. |
Graphene market breakdown by revenue and volume |
|
1.13.11. |
Market forecast for metals for 3DP |
|
1.13.12. |
Metal 3DP market forecast - industry segmentation |
|
1.13.13. |
Metal 3DP material forecast - technology segmentation |
|
1.13.14. |
Metal for 3DP forecast - alloy segmentation |
|
1.13.15. |
Low-loss materials forecast in 5G by revenue |
|
1.13.16. |
Low-loss materials areas forecast in 5G by frequency |
|
1.13.17. |
Low-loss materials areas forecast in 5G by market segments |
|
1.13.18. |
Low-loss materials areas forecast in 5G by types of materials |
|
1.13.19. |
Low-loss materials areas forecast in 5G base station by materials types |
|
1.13.20. |
Low-loss materials areas forecast in 5G smartphones by material types |
|
1.13.21. |
Low-loss materials areas forecast in 5G CPE, hotspots by material types |
|
1.13.22. |
Global capacity of Li-ion batteries for recycling by territory 2020-2040 (GWh) |
|
1.13.23. |
Global Li-ion batteries available for recycling 2020-2040: by region (tonnes) - summary |
|
1.13.24. |
Global Li-ion batteries available for recycling 2020-2040: by chemistry (tonnes) |
|
1.13.25. |
Global Li-ion batteries available for recycling 2020-2040: by chemistry (tonnes) - summary |
|
1.13.26. |
Global recycled metals from Li-ion batteries 2020-2040 (tonnes) |
|
1.13.27. |
Global recycled metals from Li-ion batteries 2020-2040 (tonnes) |
|
1.13.28. |
Global Li-ion battery recycling market value forecast 2020-2040 ($ million) |
|
1.13.29. |
Global plastics production to grow to 485 Mt in 2028 |
|
1.13.30. |
Historical management of municipal solid waste |
|
1.13.31. |
Flexible CIGS: market forecast sqm and value by barrier technology |
|
1.13.32. |
Conductive inks and pastes split by 30 application areas 2020-2030 |
|
1.13.33. |
Forecasts for all conductive inks and pastes by application |
|
1.13.34. |
Forecasts in tonnes for all conductive inks and pastes split by application |
|
1.13.35. |
Forecasts printed sensors (piezoresistive, glucose, capacitive, touch edge electrode, ITO replacement, etc.) |
|
1.13.36. |
Forecasts for conformal metallization (aerosol and package-level conformal EMI coating) |
|
1.13.37. |
Printed electronics forecasts by component 2020-2030 |
|
1.13.38. |
Printed electronics components and materials 2020-2030 |
|
1.13.39. |
Total market value of printed versus non-printed electronics 2020-2030 |
|
1.13.40. |
Market size of Flexible/ Conformation Electronics 2020-2030 |
|
1.13.41. |
Market size of Flexible/ Conformation Electronics 2020-2030 |
|
1.13.42. |
Market value of flexible/conformal versus rigid electronics |
|
1.13.43. |
Transparent conducting film or glass markets by application |
|
1.13.44. |
Global plastics production 1950-2030 |
|
1.13.45. |
Market forecast: Thermal interface materials TIM in LED for automotive |
|
1.13.46. |
TIM forecast for power supplies |
|
1.13.47. |
Market forecast: TIM in LED for displays |
|
1.13.48. |
Global market for thin film CIGS photovoltaics $ billion and GWp 2020-2040 |
|
1.13.49. |
Global market for thin film CIGS photovoltaics GWp 2020-2030 |
|
1.13.50. |
Global market for thin film CIGS photovoltaics $ billion 2020-2030 |
|
1.13.51. |
Global market for lll-V compound semiconductor PV $ billion and GWp 2020-2040 |
|
1.13.52. |
Global market for lll-V compound semiconductor PV GWp 2020-2030 |
|
1.13.53. |
Global market for lll-V compound semiconductor PV $ billion 2020-2030 |
|
1.13.54. |
Global PV technology share $bn % 2040 |
|
1.13.55. |
Global revenues from polymer recycling |
|
1.13.56. |
Global capacity of Li-ion batteries available for recycling 2020-2040 (GWh) |
|
1.13.57. |
Global Li-ion batteries available for recycling 2020-2040: by region (tonnes) |
|
1.13.58. |
Global Li-ion batteries available for recycling by chemistry in major regions |
|
1.13.59. |
Global Li-ion battery recycling market value forecast by region 2020-2040 ($ million) |
|
1.14. |
Global market for perovskite PV $M |
|
1.15. |
Global market for organic photovoltaics OPV $M |
|
1.16. |
Roadmap for 88 advanced materials in smart cities 2021-2050 |
|
2. |
INTRODUCTION |
|
2.1. |
Smart cities |
|
2.2. |
Forest City Malaysia has $0.1 trillion to spend |
|
2.3. |
Cognitive responsive infrastructure |
|
2.4. |
Sensors throughout smart cities |
|
2.5. |
Green technologies merging and doing less damage |
|
2.6. |
Materials implications of smart cities becoming water-centric |
|
2.6.1. |
Treat sewage at source |
|
2.6.2. |
Floating cities? |
|
2.7. |
Solar everywhere: examples |
|
2.7.1. |
Agrivoltaics |
|
2.7.2. |
Gap in market for solar roads: inadequate materials |
|
2.7.3. |
Light duty ground solar succeeds |
|
2.7.4. |
Solar boats and airports |
|
2.7.5. |
Flexible CIGS PV to the rescue: MIT USA in Puerto Rico |
|
2.8. |
Microgrids become minimal intermittency and relocatable |
|
2.9. |
Food independent cities overview |
|
2.10. |
Aquaponics: fish and vegetables together in sea and building |
|
2.11. |
Robotics and reinvented transport overview |
|
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- 本レポートと同じKEY WORDの最新刊レポートはありません。
よくあるご質問
IDTechEx社はどのような調査会社ですか?
IDTechExはセンサ技術や3D印刷、電気自動車などの先端技術・材料市場を対象に広範かつ詳細な調査を行っています。データリソースはIDTechExの調査レポートおよび委託調査(個別調査)を取り扱う日... もっと見る
調査レポートの納品までの日数はどの程度ですか?
在庫のあるものは速納となりますが、平均的には 3-4日と見て下さい。
但し、一部の調査レポートでは、発注を受けた段階で内容更新をして納品をする場合もあります。
発注をする前のお問合せをお願いします。
注文の手続きはどのようになっていますか?
1)お客様からの御問い合わせをいただきます。
2)見積書やサンプルの提示をいたします。
3)お客様指定、もしくは弊社の発注書をメール添付にて発送してください。
4)データリソース社からレポート発行元の調査会社へ納品手配します。
5) 調査会社からお客様へ納品されます。最近は、pdfにてのメール納品が大半です。
お支払方法の方法はどのようになっていますか?
納品と同時にデータリソース社よりお客様へ請求書(必要に応じて納品書も)を発送いたします。
お客様よりデータリソース社へ(通常は円払い)の御振り込みをお願いします。
請求書は、納品日の日付で発行しますので、翌月最終営業日までの当社指定口座への振込みをお願いします。振込み手数料は御社負担にてお願いします。
お客様の御支払い条件が60日以上の場合は御相談ください。
尚、初めてのお取引先や個人の場合、前払いをお願いすることもあります。ご了承のほど、お願いします。
データリソース社はどのような会社ですか?
当社は、世界各国の主要調査会社・レポート出版社と提携し、世界各国の市場調査レポートや技術動向レポートなどを日本国内の企業・公官庁及び教育研究機関に提供しております。
世界各国の「市場・技術・法規制などの」実情を調査・収集される時には、データリソース社にご相談ください。
お客様の御要望にあったデータや情報を抽出する為のレポート紹介や調査のアドバイスも致します。
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