Lifeboat Foundation: Safeguarding Humanity
Toggle light / dark theme

Blog – Page 9

Get the latest international news and world events from around the world.

Log in for authorized contributors

Spins influence solid oxygen’s crystal structure under extreme magnetic fields, study finds

Placing materials under extremely strong magnetic fields can give rise to unusual and fascinating physical phenomena or behavior. Specifically, studies show that under magnetic fields above 100 tesla (T), spins (i.e., intrinsic magnetic orientations of electrons) and atoms start forming new arrangements, promoting new phases of matter or stretching a crystal lattice.

One physical effect that can take place under these is known as magnetostriction. This effect essentially prompts a material’s crystal structure to stretch out, shrink or deform.

When magnetic fields above 100 T are produced experimentally, they can only be maintained for a very short time, typically for only a few microseconds. This is because their generation poses great stress on the wires used to produce the fields (i.e., coils), causing them to break almost immediately.

Introducing Nested Learning: A new ML paradigm for continual learning

The last decade has seen incredible progress in machine learning (ML), primarily driven by powerful neural network architectures and the algorithms used to train them. However, despite the success of large language models (LLMs), a few fundamental challenges persist, especially around continual learning, the ability for a model to actively acquire new knowledge and skills over time without forgetting old ones.

When it comes to continual learning and self-improvement, the human brain is the gold standard. It adapts through neuroplasticity — the remarkable capacity to change its structure in response to new experiences, memories, and learning. Without this ability, a person is limited to immediate context (like anterograde amnesia). We see a similar limitation in current LLMs: their knowledge is confined to either the immediate context of their input window or the static information that they learn during pre-training.

The simple approach, continually updating a model’s parameters with new data, often leads to “catastrophic forgetting” (CF), where learning new tasks sacrifices proficiency on old tasks. Researchers traditionally combat CF through architectural tweaks or better optimization rules. However, for too long, we have treated the model’s architecture (the network structure) and the optimization algorithm (the training rule) as two separate things, which prevents us from achieving a truly unified, efficient learning system.

Mapping chromatin structure at base-pair resolution unveils a unified model of cis-regulatory element interactions

Now online! Li et al. apply base-pair resolution Micro Capture-C ultra to map chromatin contacts between individual motifs within cis-regulatory elements and reveal a unified model of biophysically mediated enhancer-promoter communication.

HCN channels in rod bipolar cells of rat retina: subcellular localization, kinetic properties and functional dynamics

  • Liu, J. H., Singh, J. B., Veruki, M. L., & Hartveit, E. (2021). Morphological properties of the axon initial segment-like process of AII amacrine cells in the rat retina. Journal of Comparative Neurology, 529 (16), 3,593 – 3,620.

    Google Scholar

    • Promising drug can inhibit aggressive breast cancer

    New research reveals a drug developed by scientists at Oregon Health & Science University may develop into a new treatment for an especially aggressive form of breast cancer.

    A developed by researchers at Oregon Health & Science University offers a promising avenue to treat intractable cases of —a form of cancer that is notoriously aggressive and lacks effective treatments.

    In a study published today in the journal Cell Reports Medicine, researchers describe the effect of a molecule known as SU212 to inhibit an enzyme that is critical to cancer progression. The research was conducted in a humanized mouse model.

    New holography-inspired reconfigurable surface developed for wireless communication

    Reconfigurable intelligent surfaces (RIS) are engineered structures comprised of several elements known as ‘meta-atoms,’ which can reshape and control electromagnetic waves in real-time. These surfaces could contribute to the further advancement of wireless communications and localization systems, as they could be used to reliably redirect, strengthen and suppress signals.

    In conventional applications of RIS for , each meta-atom is controlled by a system known as the ‘,’ which is connected to the surface via electrical cables. While surfaces following this design can attain good results, their reliance on wires and a base station could prevent or limit their real-world deployment.

    Researchers at Tsinghua University and Southeast University recently developed a new RIS that controls itself and does not need to be connected to a base station. This new surface, introduced in a paper published in Nature Electronics, draws inspiration from holography, a well-known method to record and reconstruct an object’s light pattern to produce a 3D image of it.

    /* */