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Studies on adaptive capacity to climate change: a synthesis of changing concepts, dimensions, and indicators
Adaptive capacity was recognized as one of the critical components of vulnerability assessment in 2001 by the Intergovernmental Panel on Climate Change. Adaptive capacity extends beyond the mere accumulation of resources to encompass the willingness and ability to transform available resources into adaptive actions. In this context, adaptive capacity denotes the ability of social-ecological systems to adjust to the negative effects of environmental change or recovery from it. Hence, enhancing adaptive capacity enriches the ability to cope with a wider spectrum and greater magnitude of climate impacts. Based on the literature review and content analysis, this study explores the foundational concepts of adaptive capacity and further assesses the evolving focus on concept, scale, geographical emphasis, dimensions, and indicators through a systematic review. The findings underscore that adaptive capacity constitutes a multidimensional and interdisciplinary research domain characterized by a range of dimensions and indicators, and diverse methods and techniques at various geographic scales. The study found that adaptive capacity research has predominantly centered on asset-based analyses within the Sustainable Livelihoods Framework in the earlier stage. However, since the past decade, the focus has shifted to indicators like agency, technology, innovation, governance, knowledge, information, and infrastructure, besides climate variability and socio-economic and cultural diversity. It is suggested that to bridge the gap between adaptive capacity and actual adaptation action, policy interventions need to be targeted. The study concludes that, despite abundant research and available literature on climate change and adaptation, there is still a lack of context-specific understanding, particularly from an insider’s perspective in South Asia.
A combination of measures limits demand for critical materials in Sweden’s electric car transition
Electrification of passenger cars will result in an increased demand for critical raw materials. Here we estimate the quantities of nickel, manganese, cobalt, lithium, and graphite that could be required for a transition to electric cars in Sweden and how different measures can limit material demand. We find notable reduction potentials for shorter battery range—enabled by improved charging infrastructure, increased vehicle energy efficiency, and reduced travel demand compared to a reference scenario. The reduction potentials for downsizing and more lightweight cars, and car sharing are more modest. The combined impact of these measures would be 50–75% reduction in cumulative demand and 72–87% reduction in in-use stock in 2050, depending on the material and battery chemistry pathway. Generally, the reduction potentials are larger than the potential contributions from recycling, suggesting that these complementary measures may be more effective in reducing material demand.
Convergent evolution of complex adaptive traits modulates angiogenesis in high-altitude Andean and Himalayan human populations
Convergent adaptations represent paradigmatic examples of the capacity of natural selection to influence organisms’ biology. However, the possibility to investigate the genetic determinants underpinning convergent complex adaptive traits has been offered only recently by methods for inferring polygenic adaptations from genomic data. Relying on this approach, we demonstrate how high-altitude Andean human groups experienced pervasive selective events at angiogenic pathways, which resemble those previously attested for Himalayan populations despite partial convergence at the single-gene level was observed. This provides additional evidence for the drivers of convergent evolution of enhanced blood perfusion in populations exposed to hypobaric hypoxia for thousands of years.
Fabrication and modulation of flexible electromagnetic metamaterials
Flexible electromagnetic metamaterials are a potential candidate for the ideal material for electromagnetic control due to their unique physical properties and structure. Flexible electromagnetic metamaterials can be designed to exhibit specific responses to electromagnetic waves within a particular frequency range. Research shows that flexible electromagnetic metamaterials exhibit significant electromagnetic control characteristics in microwave, terahertz, infrared and other frequency bands. It has a wide range of applications in the fields of electromagnetic wave absorption and stealth, antennas and microwave devices, communication information and other fields. In this review, the currently popular fabrication methods of flexible electromagnetic metamaterials are first summarized, highlighting the electromagnetic modulation capability in different frequency bands. Then, the applications of flexible electromagnetic metamaterials in four aspects, namely electromagnetic stealth, temperature modulation, electromagnetic shielding, and wearable sensors, are elaborated and summarized in detail. In addition, this review also discusses the shortcomings and limitations of flexible electromagnetic metamaterials for electromagnetic control. Finally, the conclusion and perspective of the electromagnetic properties of flexible electromagnetic metamaterials are presented.
3D printing of micro-nano devices and their applications
In recent years, the utilization of 3D printing technology in micro and nano device manufacturing has garnered significant attention. Advancements in 3D printing have enabled achieving sub-micron level precision. Unlike conventional micro-machining techniques, 3D printing offers versatility in material selection, such as polymers. 3D printing technology has been gradually applied to the general field of microelectronic devices such as sensors, actuators and flexible electronics due to its adaptability and efficacy in microgeometric design and manufacturing processes. Furthermore, 3D printing technology has also been instrumental in the fabrication of microfluidic devices, both through direct and indirect processes. This paper provides an overview of the evolving landscape of 3D printing technology, delineating the essential materials and processes involved in fabricating microelectronic and microfluidic devices in recent times. Additionally, it synthesizes the diverse applications of these technologies across different domains.
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