Logical circuits in colloids

Roberts, Nic; Raeisi Kheirabadi, Noushin; Tsompanas, Michail-Antisthenis; Chiolerio, Alessandro; Crepaldi, Marco; Adamatzky, Andrew

doi:10.1098/rsos.231939

R. Soc. Open Sci.

2024

DOI: 10.1098/rsos.231939

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Logical circuits in colloids

Nic Roberts,

Noushin Raeisi Kheirabadi,

Michail-Antisthenis Tsompanas

et al.

Abstract: Colloid-based computing devices offer remarkable fault tolerance and adaptability to varying environmental conditions due to their amorphous structure. An intriguing observation is that a colloidal suspension of ZnO nanoparticles in dimethylsulfoxide (DMSO) exhibits reconfiguration when exposed to electrical stimulation and produces spikes of electrical potential in response. This study presents a novel laboratory prototype of a ZnO colloidal computer, showcasing its capability to implement various Boolean fun… Show more

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Cited by 9 publications

References 37 publications

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Pavlovian Reflex in Colloids

Raeisi Kheirabadi,

Chiolerio,

Adamatzky

2024

BioNanoSci.

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Liquid computers are devices that utilise the properties of liquid volumes or reactants to represent data and outputs. A recent development in this field is the emergence of colloid computers, which employ electromagnetic interactions among functional particles for computation. To assess the potential of colloid computers in implementing neuromorphic dynamical architectures, we have focused on realising Pavlovian reflexes within colloid mixtures. The Pavlovian reflex, a fundamental function of neurological systems in living organisms, enables learning capabilities. Our approach involves implementing Pavlovian learning by associating an increase in synaptic weight with a decrease in the resistance of the colloid mixture. Through experimental laboratory conditions, we have successfully demonstrated the feasibility of Pavlovian learning in colloid systems.

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Pavlovian Reflex in Colloids

Raeisi Kheirabadi,

Chiolerio,

Adamatzky

2024

BioNanoSci.

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Boolean Circuits in Colloidal Mixtures of ZnO and Proteinoids

Fortulan,

Raeisi Kheirabadi,

Mougkogiannis

et al. 2024

ACS Omega

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Liquid computers use incompressible fluids for computational processes. Here, we present experimental laboratory prototypes of liquid computers using colloids composed of zinc oxide (ZnO) nanoparticles and microspheres containing thermal proteins (proteinoids). The choice of proteinoids is based on their distinctive neuron-like electrical behavior and their similarity to protocells. In addition, ZnO nanoparticles are chosen for their nontrivial electrical properties. Our research demonstrates the successful extraction of 2-, 4-, and 8-bit logic functions in ZnO proteinoid colloids. Our analysis shows that each material has a distinct set of logic functions and that the complexity of the expressions is directly related to each material present in a mixture. Our study shows that 2-, 4-, and 8-bit logic functions can be successfully extracted from ZnO proteinoid colloids. These findings provide a basis for the development of future hybrid liquid devices capable of general-purpose computing.

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Kombucha–Proteinoid Crystal Bioelectric Circuits

Mougkogiannis,

Nikolaidou,

Adamatzky

2024

ACS Omega

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We propose "kombucha−proteinoid crystal bioelectric circuits" as a sustainable bio-computing platform. These circuits are hybrid biological-inorganic devices that utilize crystal growth dynamics as the physical substrate to convert information. Microfluidic prototypes couple custom-synthesized thermal proteinoids within kombucha cellulose matrices and metastable calcium carbonate solutions. This bio-mineral configuration examines if precision modulation of crystal growth rates could instantiate reconfigurable logic gates for unconventional computing applications. Programming organic acid secretions allows for the adjustment of biotic-mineral polarity, thereby establishing microbial-synthetic pairings that consistently regulate the crystal growth rate of calcite deposition. By coordinating intrinsic physicochemical phenomena, accrued mineral densities literally crystallize additive/multiplicative operations via Boolean AND/OR logics. An additional way to generate structured logics similar of neural assemblies is by chaining modular crystallizer units. Proteinoid-guided carbonate crystallization may prove to be a viable material platform for unconventional computing-green, self-organizing, scalable architectures grown directly from solution-pending definitive affirmation of proof-of-concept.

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Logical circuits in colloids

Cited by 9 publications

References 37 publications

Pavlovian Reflex in Colloids

Pavlovian Reflex in Colloids

Boolean Circuits in Colloidal Mixtures of ZnO and Proteinoids

Kombucha–Proteinoid Crystal Bioelectric Circuits

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