Trends Identified
Next-generation orbital stations
The creation of next-generation orbital stations is a breakthrough innovation in this field and could make it possible to manufacture special materials, microchips and nanostructures on industrial scales in space. The development of space (orbital) groups, including by creating new space instruments and improving existing rockets and stations and the expansion of ground-based infrastructure, including the creation of new and improved existing cosmodromes, control centres and communications, have already started to take shape. Next-gene- ration orbital stations will have greater levels of energy efficiency, comfort and safety. Moreover, the operating principles of orbital “factories” and automated research complexes will be developed, and foundations for the construction of robotic methods to carry out orbital operations and technical servicing in automated and adaptive modes will be established to provide automated docking technologies and to bring together the modules of a multi- functional orbital complex.
2016
Russia 2030: science and technology foresight
Russia, Ministry of Education and Science of the Russian Federation
Next-generation genomics
Fast, low-cost gene sequencing, advanced big data analytics, and synthetic biology (“writing” DNA)
2013
Disruptive technologies: Advances that will transform life, business, and the global economy
McKinsey
Next-generation carrier rockets
Next-generation carrier rockets making wide use of new polymer composite materials (composite proportions 20% higher than in the Proton-M rocket) will have better characteristics compared with existing counterparts by almost twofold. A distinguishing feature of these carrier rockets will be modularity. Such a construction concept firstly helps to simplify delivery of a ready-made product to the launch site by rail transport; secondly, it makes it possible to create a whole family of carrier rockets – from light (based on a single first stage module) launching a ground payload of 1.5 tons into low-earth orbit, to very heavy (up to 50 tons). With the introduction of such systems it will be possible to place payloads of over 50 tons into an orbit of 200 km, which increases the opportunities for space tourism allows to use modular carrier rockets to launch spacecraft to the Moon or nearby planets in the Solar System, and they could even be adapted for the development of deep space. One expected production benefit is linked to economies of scale: modular systems make it possible to move from modern small-scale or even individual production of rocket modules to medium-scale output.
2016
Russia 2030: science and technology foresight
Russia, Ministry of Education and Science of the Russian Federation
Next-generation biofuels
Efficient technologies to generate biofuels (including motor fuels) will save non-renewable supplies of fossil hydrocarbons, allowing for a significant expansion in the current resource base of the economy, a reduction in greenhouse gas emissions and, ultimately, a reduction in the negative impact of the energy sector on the planet’s climate. The main developmental directions in bioenergy technologies are increases in the energy efficiency of bio-conversion of carbon dioxide gas into motor fuel, reductions in the cost of biofuels, an expanded raw materials base for biofuels (for example, the development of technologies to convert lignocellulose into biofuel), and improvements in quality (stability, environmental cleanliness).
2016
Russia 2030: science and technology foresight
Russia, Ministry of Education and Science of the Russian Federation
Next-Gen Workforce
The retirement of baby boomers and the growth in the millennial workforce requires organizations to create new incentives to attract, develop, and retain a more competitive and flexible labor pool.
2017
Beyond the Noise- The Megatrends of Tomorrow’s World
Deloitte
Next-gen nuclear fusion materials withstanding extreme environments
(Definition) Materials technologies relating to materials for the blanket that converts the energy generated from the deuterium-tritium reaction into thermal energy and divertor reducing charged particles and thermal fluxes from plasma by using the magnetic field structure for the development of nuclear fusion technology (Use) Secure a clean and safe source of energy in large volume by commercializing nuclear reactors based on the development of fusion materials.
2019
KISTEP 10 Emerging Technologies 2019
South Korea, Korea Institute of S&T Evaluation and Planning (KISTEP)
Next generation genome sequencing
The technology can transcript genome at superhigh speed with extreme sensitivity and low price as well as compare it to the standard genome sequence in order to identify mutations. It is expected that medical demand will rise due to rapid aging society, and this technology can provide personalized diagnosis and treatment from reading the patient’s genome.
2013
KISTEP 10 Emerging Technologies 2013
South Korea, Korea Institute of S&T Evaluation and Planning (KISTEP)
Next Generation Batteries
Solar and wind power capacity have been growing at double-digit rates, but the sun sets, and the wind can be capricious. Although every year wind farms get larger and solar cells get more efficient, thanks to advances in materials such as perovskites, these renewable sources of energy still satisfy less than five percent of global electricity demand. In many places, renewables are relegated to niche roles because of the lack of an affordable, reliable technology to store the excess energy that they make when conditions are ideal and to release the power onto the grid as demand picks up. Better batteries could solve this problem, enabling emissions-free renewables to grow even faster—and making it easier to bring reliable electricity to the 1.2 billion people who currently live without it. Within the past few years, new kinds of batteries have been demonstrated that deliver high enough capacity to serve whole factories, towns, or even “mini-grids” connecting isolated rural communities. These batteries are based on sodium, aluminium or zinc. They avoid the heavy metals and caustic chemicals used in older lead-acid battery chemistries. And they are more affordable, more scalable, and safer than the lithium batteries currently used in advanced electronics and electric cars. The newer technology is much better suited to support transmissions systems that rely heavily on solar or wind power. Last October, for example, Fluidic Energy announced an agreement with the government of Indonesia to deploy 35 megawatts of solar panel capacity to 500 remote villages, electrifying the homes of 1.7 million people. The system will use Fluidic’s zinc-air batteries to store up to 250 megawatt-hours of energy in order to provide reliable electricity regardless of the weather. In April, the company inked a similar deal with the government of Madagascar to put 100 remote villages there on a solar-powered mini-grid backed by zinc-air batteries. For people who currently have no access to the grid—no light to work by at night, no Internet to mine for information, no power to do the washing or to irrigate the crops—the combination of renewable generation and grid-scale batteries is utterly transformative, a potent antidote for poverty. But better batteries also hold enormous promise for the rich world as it struggles to meet the formidable challenge of removing most carbon emissions from electricity generation within the next few decades—and doing so at the same time that demand for electricity is growing. The ideal battery is not yet in hand. The new technologies have plenty of room for further improvement. But until recently, advances in grid-scale batteries had been few and far between. So it is heartening to see the pace of progress quickening.
2016
Top 10 Emerging Technologies of 2016
World Economic Forum (WEF)