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1. Performance analysis of DNA crossbar arrays for high-density memory storage applications

   https://doi.org/10.1038/s41598-023-33004-6  

   De, Arpan; Mohammad, Hashem; Wang, Yiren; Kubendran, Rajkumar; Das, Arindam K.; Anantram, M. P. (April 2023, Scientific Reports)

   Abstract Deoxyribonucleic acid (DNA) has emerged as a promising building block for next-generation ultra-high density storage devices. Although DNA has high durability and extremely high density in nature, its potential as the basis of storage devices is currently hindered by limitations such as expensive and complex fabrication processes and time-consuming read–write operations. In this article, we propose the use of a DNA crossbar array architecture for an electrically readable read-only memory (DNA-ROM). While information can be ‘written’ error-free to a DNA-ROM array using appropriate sequence encodings its read accuracy can be affected by several factors such as array size, interconnect resistance, and Fermi energy deviations from HOMO levels of DNA strands employed in the crossbar. We study the impact of array size and interconnect resistance on the bit error rate of a DNA-ROM array through extensive Monte Carlo simulations. We have also analyzed the performance of our proposed DNA crossbar array for an image storage application, as a function of array size and interconnect resistance. While we expect that future advances in bioengineering and materials science will address some of the fabrication challenges associated with DNA crossbar arrays, we believe that the comprehensive body of results we present in this paper establishes the technical viability of DNA crossbar arrays as low power, high-density storage devices. Finally, our analysis of array performance vis-à-vis interconnect resistance should provide valuable insights into aspects of the fabrication process such as proper choice of interconnects necessary for ensuring high read accuracies. 

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2. Superconductor bistable vortex memory for data storage and readout

   https://doi.org/10.1088/1361-6668/ad9863  

   Karamuftuoglu, M A; Ucpinar, B Z; Razmkhah, S; Pedram, M (December 2024, Superconductor Science and Technology)

   Abstract Despite superconductor electronics (SCE) advantages, the realization of SCE logic faces a significant challenge due to the absence of dense and scalable nonvolatile memory. While various nonvolatile memory technologies, including Non-destructive readout, vortex transitional memory, and magnetic memory, have been explored, designing a dense crossbar array and achieving a superconductor random-access memory remains challenging. This work introduces a novel, nonvolatile, high-density, and scalable vortex-based memory design for SCE logic called bistable vortex memory. Our proposed design addresses scaling issues with an estimated area of 10 × 10 um²while boasting zero static power with the dynamic energy consumption of 12 aJ for single-bit read and write operations. The current summation capability enables analog operations for in-memory or near-memory computational tasks. We demonstrate the efficacy of our approach with a 32 × 32 superconductor memory array operating at 20 GHz. Additionally, we showcase the accumulation property of the memory through analog simulations conducted on an 8 × 8 superconductor crossbar array. 

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3. Advancing Archival Data Storage: The Promises and Challenges of DNA Storage System

   https://doi.org/10.1145/3723166  

   Sensintaffar, Alex; Wei, Yixun; Ou, Li; Du, David; Li, Bingzhe (March 2025, ACM Transactions on Storage)

   As the volume of data is rapidly produced every day, there is a need for the storage media to keep up with the growth rate of digital data created. Despite emerging storage solutions that have been proposed such as Solid State Drive (SSD) with quad-level cells (QLC) or penta-level cells (PLC), Shingled Magnetic Recording (SMR), LTO-tape, etc., these technologies still fall short of meeting the demand for preserving huge amounts of available data. Moreover, current storage solutions have a limited lifespan, often lasting just a few years. To ensure long-term preservation, data must be continuously migrated to new storage drives. Therefore, there is a need for alternative storage technologies that not only offer high storage capacity but also long persistency. In contrast to existing storage devices, Synthetic Deoxyribonucleic Acid (DNA) storage emerges as a promising candidate for archival data storage, offering both high-density storage capacity and the potential for long-term data preservation. In this paper, we will introduce DNA storage, discuss the capabilities of DNA storage based on the current biotechnologies, discuss possible improvements in DNA storage, and explore further improvements with future technologies. Currently, the limitations of DNA storage are due to its weaknesses including high error rates, long access latency, etc. In this paper, we will focus on possible DNA storage research issues based on its relevant bio and computer technologies. Also, we will provide potential solutions and forward-looking predictions about the development and the future of DNA storage. We will discuss DNA storage from the following five perspectives: 1) We will describe the basic background of DNA storage including the basic technologies of read/write DNA storage, data access processes such as Polymerase Chain Reaction (PCR) based random access, encoding schemes from digital data to DNA, and required DNA storage format. 2) We will describe the issues of DNA storage based on the current technologies including bio-constraints during the encoding process such as avoiding long homopolymers and containing certain GC contents, different types of errors in synthesis and sequencing processes, low practical capacity with the current technologies, slow read and write performance, and low encoding density for random accesses. 3) Based on the previously mentioned issues, we will summarize the current solutions for each issue, and also give and discuss the potential solutions based on the future technologies. 4) From a system perspective, we will discuss how the DNA storage system will look if the DNA storage becomes commercialized and is widely equipped in archive systems. Some questions will be discussed including i) How to efficiently index data in DNA storage? ii) What is a good storage hierarchical storage system with DNA storage? iii) What will DNA storage be like with the development of technology? 5) Finally, we will provide a comparison with other competitive technologies. 

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4. An Ultra-Efficient Memristor-Based DNN Framework with Structured Weight Pruning and Quantization Using ADMM

   https://doi.org/10.1109/ISLPED.2019.8824944  

   Yuan, Geng; Ma, Xiaolong; Ding, Caiwen; Lin, Sheng; Zhang, Tianyun; Jalali, Zeinab S.; Zhao, Yilong; Jiang, Li; Soundarajan, Sucheta; Wang, Yanzhi (January 2019, IEEE/ACM International Symposium on Low Power Electronics and Design (ISLPED))

   The high computation and memory storage of large deep neural networks (DNNs) models pose intensive challenges to the conventional Von-Neumann architecture, incurring substantial data movements in the memory hierarchy. The memristor crossbar array has emerged as a promising solution to mitigate the challenges and enable low-power acceleration of DNNs. Memristor-based weight pruning and weight quantization have been separately investigated and proven effectiveness in reducing area and power consumption compared to the original DNN model. However, there has been no systematic investigation of memristor-based neuromorphic computing (NC) systems considering both weight pruning and weight quantization. In this paper, we propose an unified and systematic memristor-based framework considering both structured weight pruning and weight quantization by incorporating alternating direction method of multipliers (ADMM) into DNNs training. We consider hardware constraints such as crossbar blocks pruning, conductance range, and mismatch between weight value and real devices, to achieve high accuracy and low power and small area footprint. Our framework is mainly integrated by three steps, i.e., memristor- based ADMM regularized optimization, masked mapping and retraining. Experimental results show that our proposed frame- work achieves 29.81× (20.88×) weight compression ratio, with 98.38% (96.96%) and 98.29% (97.47%) power and area reduction on VGG-16 (ResNet-18) network where only have 0.5% (0.76%) accuracy loss, compared to the original DNN models. We share our models at anonymous link http://bit.ly/2Jp5LHJ . 

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5. 128-Channel Multi-Chip Acoustic Hologram Generator

   https://doi.org/10.23919/VLSITechnologyandCir65189.2025.11075058  

   Kustin, John; Kang, Taewook; Song, Seungheun; Naveed, Yahya; Flynn, Michael P (June 2025, IEEE)

   An ASIC combines a numerically controlled oscillator with reconfigurable amplitude and phase control of 16 channels to synthesize acoustic holograms with a phased array of ultrasonic transmitters. Multiple chiplets operate synchronously to drive arbitrarily many channels. A scalable digital delay line technique, leveraging on-chip SRAM and single-bit noise-shaped bitstreams, realizes area-efficient, high-density, and high-resolution true-time-delay phase shifts. The prototype system employs 8 chiplets to drive a 128-element array for hologram generation. 

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