Property:Reference group
From Thermodynamics of Computation
This is a property of type Text.
It can be set to the following values:
- Artificial Biological Computation
- Chemical Reaction Networks
- Computer Science Engineering to Address Energy Costs
- Computer Science Theory
- General Non-equilibrium Statistical Physics
- Logically Reversible Computing
- Naturally Occurring Biological Computation
- Quantum Thermodynamics and Information Processing
- Review Articles and Books
- Stochastic Thermodynamics
- Thermodynamics of Neurobiology
- Thermodynamics of Single Cells
- Tutorials
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M
Artificial Biological Computation +
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Artificial Biological Computation +
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Artificial Biological Computation +
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Artificial Biological Computation +
C
Cooperative multicomponent self-assembly of nucleic acid structures for the activation of DNAzyme cascades: A paradigm for DNA sensors and aptasensors +
Artificial Biological Computation +
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Artificial Biological Computation +
D
Artificial Biological Computation +
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Artificial Biological Computation +
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Artificial Biological Computation +
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M
Artificial Biological Computation +
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Artificial Biological Computation +
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Artificial Biological Computation +
F
Artificial Biological Computation +
D
Artificial Biological Computation +
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Artificial Biological Computation +
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Artificial Biological Computation +
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Artificial Biological Computation +
M
Artificial Biological Computation +
V
Artificial Biological Computation +
C
Artificial Biological Computation +
Artificial Biological Computation +
L
Artificial Biological Computation +
V
Artificial Biological Computation +
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Artificial Biological Computation +
B
Artificial Biological Computation +
A
Artificial Biological Computation +
S
Artificial Biological Computation +
C
Artificial Biological Computation +
E
Artificial Biological Computation +
G
Genetic screens and selections for small molecules based on a synthetic riboswitch that activates protein translation +
Artificial Biological Computation +
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Artificial Biological Computation +
C
Artificial Biological Computation +
E
Artificial Biological Computation +
Artificial Biological Computation +
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S
A
Artificial Biological Computation +
C
Artificial Biological Computation +
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Taming the complexity of biochemical models through bisimulation and collapsing: Theory and practice +
Artificial Biological Computation +
D
Artificial Biological Computation +
A
Artificial Biological Computation +
G
General peroxidase activity of G-quadruplex-hemin complexes and its application in ligand screening +
Artificial Biological Computation +
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A
Artificial Biological Computation +
C
U
S
T
A
Chemical Reaction Networks +
D
Chemical Reaction Networks +
C
Chemical Reaction Networks +
T
L
Chemical Reaction Networks +
T
The topology of energy hypersurfaces III. The fundamental group of reaction mechanisms on potential energy hypersurfaces +
Chemical Reaction Networks +
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Chemical Reaction Networks +
C
Chemical Reaction Networks +
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Chemical Reaction Networks +
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Chemical Reaction Networks +
G
Chemical Reaction Networks +
A
Chemical Reaction Networks +
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Chemical Reaction Networks +
D
Does replication‐induced transcription regulate synthesis of the myriad low copy number proteins of Escherichia coli? +
Chemical Reaction Networks +
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Chemical Reaction Networks +
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Chemical Reaction Networks +
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Chemical Reaction Networks +
F
Chemical Reaction Networks +
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Chemical Reaction Networks +
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M
Chemical Reaction Networks +
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Chemical Reaction Networks +
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Chemical Reaction Networks +
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Chemical Reaction Networks +
D
Chemical Reaction Networks +
Chemical Reaction Networks +
A
An efficient graph theory based method to identify every minimal reaction set in a metabolic network +
Chemical Reaction Networks +
F
Chemical Reaction Networks +
A
Chemical Reaction Networks +
O
On a hypothetical generational relationship between HCN and constituents of the reductive citric acid cycle +
Chemical Reaction Networks +
S
Chemical Reaction Networks +
A
Chemical Reaction Networks +
R
Chemical Reaction Networks +
P
Chemical Reaction Networks +
M
Chemical Reaction Networks +
C
Chemical Reaction Networks +
Chemical Reaction Networks +
R
Chemical Reaction Networks +
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Chemical Reaction Networks +
Chemical Reaction Networks +
A
Chemical Reaction Networks +
R
Chemical Reaction Networks +
P
Chemical Reaction Networks +
T
Chemical Reaction Networks +
A
Chemical Reaction Networks +
F
Chemical Reaction Networks +
C
Chemical Reaction Networks +
A
Chemical Reaction Networks +
Chemical Reaction Networks +
G
Chemical Reaction Networks +
O
On the Relation between Gradient Flows and the Large-Deviation Principle, with Applications to Markov Chains and Diffusion +
Chemical Reaction Networks +
S
Chemical Reaction Networks +
Z
Chemical Reaction Networks +
D
Chemical Reaction Networks +
O
Chemical Reaction Networks +
F
Chemical Reaction Networks +
A
An examination of the role of autocatalytic cycles in the chemistry of proposed primordial reactions +
Chemical Reaction Networks +
N
Chemical Reaction Networks +
S
Chemical Reaction Networks +
C
Chemical Reaction Networks +
F
T
H
S
A
S
A
T
E
T
A
S
A
T
N
S
K
F
C
E
F
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F
A
E
G
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Q
A
G
F
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K
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K
T
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A
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N
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Computer Science Engineering to Address Energy Costs +
E
Computer Science Engineering to Address Energy Costs +
U
Computer Science Engineering to Address Energy Costs +
P
Computer Science Engineering to Address Energy Costs +
T
Computer Science Engineering to Address Energy Costs +
E
Computer Science Engineering to Address Energy Costs +
A
Computer Science Engineering to Address Energy Costs +
A 32-bit powerPC system-on-a-chip with support for dynamic voltage scaling and dynamic frequency scaling +
Computer Science Engineering to Address Energy Costs +
Computer Science Engineering to Address Energy Costs +
C
Computer Science Engineering to Address Energy Costs +
N
Computer Science Engineering to Address Energy Costs +
E
Computer Science Engineering to Address Energy Costs +
A
Computer Science Engineering to Address Energy Costs +
I
S
Computer Science Engineering to Address Energy Costs +
C
Computer Science Engineering to Address Energy Costs +
T
C
Computer Science Engineering to Address Energy Costs +
T
Computer Science Engineering to Address Energy Costs +
N
Computer Science Engineering to Address Energy Costs +
U
Ueber die bewegende Kraft der Wärme und die Gesetze, welche sich daraus für die Wärmelehre selbst ableiten lassen +
Computer Science Engineering to Address Energy Costs +
C
Computer Science Engineering to Address Energy Costs +
G
Computer Science Engineering to Address Energy Costs +
P
Computer Science Engineering to Address Energy Costs +
E
Computer Science Engineering to Address Energy Costs +
B
Computer Science Engineering to Address Energy Costs +
S
Computer Science Engineering to Address Energy Costs +
B
Computer Science Engineering to Address Energy Costs +
P
Computer Science Engineering to Address Energy Costs +
A
Computer Science Engineering to Address Energy Costs +
U
Computer Science Engineering to Address Energy Costs +
T
Computer Science Engineering to Address Energy Costs +
L
Computer Science Engineering to Address Energy Costs +
M
Computer Science Engineering to Address Energy Costs +
R
S
Computer Science Engineering to Address Energy Costs +
Computer Science Engineering to Address Energy Costs +
A
Computer Science Engineering to Address Energy Costs +
P
Computer Science Engineering to Address Energy Costs +
A
Computer Science Engineering to Address Energy Costs +
Computer Science Engineering to Address Energy Costs +
S
Computer Science Engineering to Address Energy Costs +
O
Computer Science Engineering to Address Energy Costs +
D
Computer Science Engineering to Address Energy Costs +
T
Computer Science Engineering to Address Energy Costs +
L
Computer Science Engineering to Address Energy Costs +
E
Computer Science Engineering to Address Energy Costs +
R
Computer Science Engineering to Address Energy Costs +
O
Computer Science Engineering to Address Energy Costs +
S
Computer Science Engineering to Address Energy Costs +
E
Computer Science Engineering to Address Energy Costs +
D
Computer Science Engineering to Address Energy Costs +
O
Computer Science Engineering to Address Energy Costs +
D
Computer Science Engineering to Address Energy Costs +
N
Computer Science Engineering to Address Energy Costs +
A
Computer Science Engineering to Address Energy Costs +
Computer Science Engineering to Address Energy Costs +
T
Computer Science Engineering to Address Energy Costs +
S
Computer Science Engineering to Address Energy Costs +
N
Computer Science Engineering to Address Energy Costs +
P
Computer Science Engineering to Address Energy Costs +
S
Computer Science Engineering to Address Energy Costs +
F
Computer Science Engineering to Address Energy Costs +
L
Computer Science Engineering to Address Energy Costs +
I
Computer Science Engineering to Address Energy Costs +
L
Computer Science Engineering to Address Energy Costs +
T
Computer Science Engineering to Address Energy Costs +
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Computer Science Engineering to Address Energy Costs +
E
Computer Science Engineering to Address Energy Costs +
T
Computer Science Engineering to Address Energy Costs +
P
Computer Science Engineering to Address Energy Costs +
Computer Science Engineering to Address Energy Costs +
T
Tolerating Soft Errors in Processor Cores Using CLEAR (Cross-Layer Exploration for Architecting Resilience) +
Computer Science Engineering to Address Energy Costs +
E
Computer Science Engineering to Address Energy Costs +
R
Computer Science Engineering to Address Energy Costs +
C
Computer Science Engineering to Address Energy Costs +
A
A stochastic-based FPGA controller for an induction motor drive with integrated neural network algorithms +
Computer Science Engineering to Address Energy Costs +
P
Computer Science Engineering to Address Energy Costs +
S
Computer Science Engineering to Address Energy Costs +
A
Computer Science Engineering to Address Energy Costs +
U
Ultra low-energy computing via probabilistic algorithms and devices: CMOS device primitives and the energy-probability relationship +
Computer Science Engineering to Address Energy Costs +
S
Computer Science Engineering to Address Energy Costs +
U
Computer Science Engineering to Address Energy Costs +
A
Computer Science Engineering to Address Energy Costs +
{ "type": "PROPERTY_CONSTRAINT_SCHEMA", "constraints": { "type_constraint": "_txt", "allowed_values": [ "Artificial Biological Computation", "Chemical Reaction Networks", "Computer Science Engineering to Address Energy Costs", "Computer Science Theory", "General Non-equilibrium Statistical Physics", "Logically Reversible Computing", "Naturally Occurring Biological Computation", "Quantum Thermodynamics and Information Processing", "Review Articles and Books", "Stochastic Thermodynamics", "Thermodynamics of Neurobiology", "Thermodynamics of Single Cells", "Tutorials" ] } }