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LEADER 21735cam a2204897 a 4500
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991001611829707546
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20220623143544.0
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130708s2014 nyua b 001 0 eng
010
a| 2013027471
020
a| 9780393913484 (hardcover)
020
a| 0393913481 (hardcover)
035
a| (HKSYU)b14899450-852hksyu_inst
040
a| DLC
e| rda
b| eng
c| DLC
d| YDX
d| OCLCO
d| YDXCP
d| NhCcYME
d| HK-SYU
042
a| pcc
050
4
a| QP360.5
b| .G39 2014
082
0
0
a| 612.8/233
2| 23
092
0
a| 612.8233
b| GAZ 2014
100
1
a| Gazzaniga, Michael S.
245
1
0
a| Cognitive neuroscience :
b| the biology of the mind /
c| Michael S. Gazzaniga, University of California, Santa Barbara; Richard B. Ivry, University of California, Berkeley; George R. Mangun, University of California, Davis.
250
a| Fourth edition.
260
a| New York, NY :
b| W. W. Norton & Company, Inc.,
c| c2014.
300
a| 645 pages :
b| illustrations (some color) ;
c| 29 cm.
336
a| text
2| rdacontent.
337
a| unmediated
2| rdamedia.
338
a| volume
2| rdacarrier.
504
a| Includes bibliographical references and index.
650
0
a| Cognitive neuroscience.
700
1
a| Ivry, Richard B.
700
1
a| Mangun, G. R.
q| (George Ronald),
d| 1956-
907
a| b14899450
b| 08-01-22
c| 09-06-14
910
a| nlw
b| df
935
a| (HK-SYU)500839341
9| ExL
970
0
1
t| Boxes
p| xii
970
0
1
t| Preface
p| xiii
970
0
1
t| Acknowledgments
p| xv
970
1
1
l| pt. I
t| Background and Methods
970
1
1
l| 1.
t| A Brief History of Cognitive Neuroscience
p| 2
970
1
1
t| A Historical Perspective
p| 4
970
1
1
t| The Brain Story
p| 5
970
1
1
t| The Psychological Story
p| 10
970
1
1
t| The Instruments of Neuroscience
p| 14
970
1
1
t| The Electroencephalograph
p| 14
970
1
1
t| Measuring Blood Flow in the Brain
p| 15
970
1
1
t| Computerized Axial Tomography
p| 15
970
1
1
t| Positron Emission Tomography and Radioactive Tracers
p| 16
970
1
1
t| Magnetic Resonance Imaging
p| 17
970
1
1
t| Functional Magnetic Resonance Imaging
p| 17
970
1
1
t| The Book in Your Hands
p| 19
970
1
1
l| 2.
t| Structure and Function of the Nervous System
p| 22
970
1
1
t| The Structure of Neurons
p| 24
970
1
1
t| Neuronal Signaling
p| 27
970
1
1
t| The Membrane Potential
p| 27
970
1
1
t| The Action Potential
p| 30
970
1
1
t| Synaptic Transmission
p| 32
970
1
1
t| Chemical Transmission
p| 32
970
1
1
t| Neurotransmitters
p| 33
970
1
1
t| Inactivation of Neurotransmitters after Release
p| 34
970
1
1
t| Electrical Transmission
p| 35
970
1
1
t| The Role of Glial Cells
p| 35
970
1
1
t| The Bigger Picture
p| 37
970
1
1
t| Overview of Nervous System Structure
p| 37
970
1
1
t| The Autonomic Nervous System
p| 38
970
1
1
t| The Central Nervous System
p| 38
970
1
1
t| A Guided Tour of the Brain
p| 40
970
1
1
t| The Spinal Cord
p| 40
970
1
1
t| The Brainstem: Medulla, Pons, Cerebellum, and Midbrain
p| 43
970
1
1
t| The Diencephalon: Thalamus and Hypothalamus
p| 45
970
1
1
t| The Telencephalon: Limbic System, Basal Ganglia, and Cerebral Cortex
p| 47
970
1
1
t| The Cerebral Cortex
p| 49
970
1
1
t| Dividing the Cortex Anatomically
p| 50
970
1
1
t| Dividing the Cortex Cytoarchitectonically
p| 51
970
1
1
t| Functional Divisions of the Cortex
p| 53
970
1
1
t| Development of the Nervous System
p| 60
970
1
1
t| Overview of Gross Development
p| 60
970
1
1
t| Birth of New Neurons Throughout Life
p| 64
970
1
1
t| The Baby Brain: Ready to Rock วน' Roll?
p| 66
970
1
1
l| 3.
t| Methods of Cognitive Neuroscience
p| 70
970
1
1
t| Cognitive Psychology and Behavioral Methods
p| 74
970
1
1
t| Ferreting Out Mental Representations and Transformations
p| 74
970
1
1
t| Constraints on Information Processing
p| 78
970
1
1
t| Studying the Damaged Brain
p| 78
970
1
1
t| Causes of Neurological Dysfunction
p| 79
970
1
1
t| Studying Brain-Behavior Relationships Following Neural Disruption
p| 83
970
1
1
t| Functional Neurosurgery: Intervention to Alter or Restore Brain Function
p| 86
970
1
1
t| Methods to Perturb Neural Function
p| 86
970
1
1
t| Pharmacology
p| 87
970
1
1
t| Transcranial Magnetic Stimulation
p| 88
970
1
1
t| Transcranial Direct Current Stimulation
p| 89
970
1
1
t| Genetic Manipulations
p| 89
970
1
1
t| Structural Analysis of the Brain
p| 91
970
1
1
t| Computed Tomography
p| 91
970
1
1
t| Magnetic Resonance Imaging
p| 92
970
1
1
t| Diffusion Tensor Imaging
p| 93
970
1
1
t| Methods for the Study of Neural Function
p| 9
970
1
1
t| Single-Cell Recording in Animals
p| 95
970
1
1
t| Single-Cell Recordings in Humans
p| 98
970
1
1
t| Electroencephalography
p| 98
970
1
1
t| Event-Related Potential
p| 100
970
1
1
t| Magnetoencephatography
p| 102
970
1
1
t| Electrocortogram
p| 102
970
1
1
t| The Marriage of Function and Structure: Neuroimaging
p| 104
970
1
1
t| Positron Emission Tomography
p| 105
970
1
1
t| Functional Magnetic Resonance Imaging
p| 107
970
1
1
t| Limitations of PET and fMRI
p| 110
970
1
1
t| Brain Graphs
p| 110
970
1
1
t| Computer Modeling
p| 111
970
1
1
t| Representations in Computer Models
p| 113
970
1
1
t| Models Lead to Testable Predictions
p| 113
970
1
1
t| Converging Methods
p| 114
970
1
1
l| pt. II
t| Core Processes
970
1
1
l| 4.
t| Hemispheric Specialization
p| 120
970
1
1
t| Anatomy of the Hemispheres
p| 125
970
1
1
t| Anatomical Correlates of Hemispheric Specialization
p| 125
970
1
1
t| Function of the Corpus Callosum
p| 129
970
1
1
t| Splitting the Brain: Cortical Disconnection
p| 133
970
1
1
t| The Surgery
p| 133
970
1
1
t| Methodological Considerations in Studying Split-Brain Patients
p| 134
970
1
1
t| Functional Consequences of the Split-Brain Procedure
p| 135
970
1
1
t| Hemispheric Specialization
p| 136
970
1
1
t| Evidence From Split-Brain Patients
p| 136
970
1
1
t| Theory of Mind
p| 145
970
1
1
t| The Interpreter
p| 146
970
1
1
t| Evidence From Patients With Unilateral Cortical Lesions
p| 149
970
1
1
t| Evidence From the Normal Brain
p| 150
970
1
1
t| The Evolutionary Basis of Hemispheric Specialization
p| 153
970
1
1
t| Hemispheric Specialization in Nonhumans
p| 153
970
1
1
t| Modularity
p| 154
970
1
1
t| Hemispheric Specialization: A Dichotomy in Function or Stylishly Different?
p| 155
970
1
1
t| Is There a Connection Between Handedness and Left-Hemisphere Language Dominance?
p| 156
970
1
1
t| Split-Brain Research as a Window into Conscious Experience
p| 159
970
1
1
l| 5.
t| Sensation and Perception
p| 162
970
1
1
t| Senses, Sensation, and Perception
p| 164
970
1
1
t| Sensation: Early Perceptual Processing
p| 164
970
1
1
t| Shared Processing From Acquisition to Anatomy
p| 164
970
1
1
t| Receptors Share Responses to Stimuli
p| 165
970
1
1
t| Audition
p| 167
970
1
1
t| Neural Pathways of Audition
p| 168
970
1
1
t| Computational Goals in Audition
p| 170
970
1
1
t| Olfaction
p| 172
970
1
1
t| Neural Pathways of Olfaction
p| 173
970
1
1
t| The Role of Sniffing in Olfactory Perception
p| 174
970
1
1
t| One Nose, Two Odors
p| 175
970
1
1
t| Gustation
p| 176
970
1
1
t| Neural Pathways of Gustation
p| 176
970
1
1
t| Gustatory Processing
p| 178
970
1
1
t| Somatosensation
p| 179
970
1
1
t| Neural Pathways of Somatosensation
p| 179
970
1
1
t| Somatosensory Processing
p| 180
970
1
1
t| Plasticity in the Somatosensory Cortex
p| 181
970
1
1
t| Mechanisms of Cortical Plasticity
p| 184
970
1
1
t| Vision
p| 184
970
1
1
t| Neural Pathways of Vision
p| 184
970
1
1
t| Cortical Visual Areas
p| 187
970
1
1
t| From Sensation to Perception
p| 197
970
1
1
t| Where Are Percepts Formed?
p| 197
970
1
1
t| Individual Differences in Perception
p| 200
970
1
1
t| Deficits in Visual Perception
p| 201
970
1
1
t| Deficits in Color Perception: Achromatopsia
p| 201
970
1
1
t| Deficits in Motion Perception: Akinetopsia
p| 203
970
1
1
t| Perception Without a Visual Cortex
p| 206
970
1
1
t| Multimodal Perception: I See What You're Sayin'
p| 207
970
1
1
t| Multimodal Processing in the Brain
p| 208
970
1
1
t| Errors in Multimodal Processing: Synesthesia
p| 211
970
1
1
t| Perceptual Reorganization
p| 213
970
1
1
l| 6.
t| Object Recognition
p| 218
970
1
1
t| Principles of Object Recognition
p| 220
970
1
1
t| Multiple Pathways for Visual Perception
p| 222
970
1
1
t| The What and Where Pathways
p| 224
970
1
1
t| Representational Differences Between the Dorsal and Ventral Streams
p| 224
970
1
1
t| Perception for Identification Versus Perception for Action
p| 225
970
1
1
t| Computational Problems in Object Recognition
p| 228
970
1
1
t| Variability in Sensory Information
p| 230
970
1
1
t| View-Dependent Versus View-Invariant Recognition
p| 231
970
1
1
t| Shape Encoding
p| 232
970
1
1
t| Grandmother Cells and Ensemble Coding
p| 233
970
1
1
t| Summary of Computational Problems
p| 236
970
1
1
t| Failures in Object Recognition: The Big Picture
p| 236
970
1
1
t| Apperceptive Agnosia
p| 237
970
1
1
t| Integrative Agnosia
p| 239
970
1
1
t| Associative Agnosia
p| 240
970
1
1
t| Category Specificity in Agnosia: The Devil Is in the Details
p| 241
970
1
1
t| Animate Versus Inanimate?
p| 241
970
1
1
t| Organizational Theories of Category Specificity
p| 243
970
1
1
t| Prosopagnosia Is a Failure to Recognize Faces
p| 246
970
1
1
t| Processing Faces: Are Faces Special?
p| 246
970
1
1
t| Regions of the Brain Involved in Face Recognition
p| 248
970
1
1
t| Parts and Wholes in Visual Perception
p| 253
970
1
1
t| Faces Are Processed in a Holistic Manner
p| 255
970
1
1
t| Does the Visual System Contain Other Category-Specific Systems?
p| 258
970
1
1
t| Mind Reading
p| 261
970
1
1
t| Encoding and Decoding Brain Signals
p| 261
970
1
1
t| Statistical Pattern Recognition
p| 263
970
1
1
t| A Look Into the Future of Mind Reading
p| 266
970
1
1
l| 7.
t| Attention
p| 272
970
1
1
t| The Anatomy of Attention
p| 275
970
1
1
t| The Neuropsychology of Attention
p| 275
970
1
1
t| Neglect
p| 276
970
1
1
t| Neuropsychological Tests of Neglect
p| 277
970
1
1
t| Extinction
p| 278
970
1
1
t| Comparing Neglect and Balint's Syndrome
p| 279
970
1
1
t| Models of Attention
p| 280
970
1
1
t| Hermann von Helmholtz and Covert Attention
p| 280
970
1
1
t| The Cocktail Party Effect
p| 281
970
1
1
t| Early Versus Late Selection Models
p| 283
970
1
1
t| Quantifying the Role of Attention in Perception
p| 283
970
1
1
t| Neural Mechanisms of Attention and Perceptual Selection
p| 286
970
1
1
t| Voluntary Spatial Attention
p| 286
970
1
1
t| Reflexive Spatial Attention
p| 295
970
1
1
t| Visual Search
p| 297
970
1
1
t| Feature Attention
p| 301
970
1
1
t| Interplay Between Spatial and Feature Attention
p| 306
970
1
1
t| Object Attention
p| 308
970
1
1
t| Review of Attention and Perceptual Selection Mechanisms
p| 309
970
1
1
t| Attentional Control Networks
p| 311
970
1
1
t| Dorsal Attention Network: Frontoparietal Attention System
p| 313
970
1
1
t| Ventral Right Attention Network
p| 318
970
1
1
t| Subcortical Components of Attention Control Networks
p| 319
970
1
1
t| Review of Attentional Control Networks
p| 322
970
1
1
l| 8.
t| Action
p| 326
970
1
1
t| The Anatomy and Control of Motor Structures
p| 329
970
1
1
t| Muscles, Motor Neurons, and the Spinal Cord
p| 330
970
1
1
t| Subcortical Motor Structures
p| 332
970
1
1
t| Cortical Regions Involved in Motor Control
p| 334
970
1
1
t| Computational Issues in Motor Control
p| 337
970
1
1
t| Central Pattern Generators
p| 337
970
1
1
t| Central Representation of Movement Plans
p| 338
970
1
1
t| Hierarchical Representation of Action Sequences
p| 340
970
1
1
t| Physiological Analysis of Motor Pathways
p| 342
970
1
1
t| Neural Coding of Movement
p| 342
970
1
1
t| Alternative Perspectives on Neural Representation of Movement
p| 343
970
1
1
t| Goal Selection and Action Planning
p| 346
970
1
1
t| Action Goals and Movement Plans
p| 347
970
1
1
t| Representational Variation Across Motor Areas of the Cortex
p| 348
970
1
1
t| The Brain-Machine Interface
p| 352
970
1
1
t| Early Work on the Brain-Machine Interface
p| 352
970
1
1
t| Making Brain-Machine Interface Systems Stable
p| 353
970
1
1
t| Movement Initiation and the Basal Ganglia
p| 356
970
1
1
t| The Basal Ganglia as a Gatekeeper
p| 357
970
1
1
t| Disorders of the Basal Ganglia
p| 358
970
1
1
t| Action Understanding and Mirror Neurons
p| 363
970
1
1
t| Learning and Performing New Skills
p| 366
970
1
1
t| Shift in Cortical Control with Learning
p| 366
970
1
1
t| Adaptive Learning Through Sensory Feedback
p| 367
970
1
1
t| Neural Mechanisms of Adaptation
p| 368
970
1
1
t| Forward Models: Using Sensorimotor Predictions for Motor Control and Learning
p| 371
970
1
1
t| Experts
p| 373
970
1
1
l| 9.
t| Memory
p| 378
970
1
1
t| The Anatomy of Memory
p| 381
970
1
1
t| Memory Deficits: Amnesia
p| 382
970
1
1
t| Brain Surgery and Memory Loss
p| 383
970
1
1
t| Recent Studies on Memory Loss
p| 384
970
1
1
t| Mechanisms of Memory
p| 384
970
1
1
t| Short-Term Forms of Memory
p| 384
970
1
1
t| Long-Term Forms of Memory
p| 389
970
1
1
t| The Medial Temporal Lobe Memory System
p| 394
970
1
1
t| Evidence From Amnesia
p| 394
970
1
1
t| Evidence From Animals With Medial Temporal Lobe Lesions
p| 397
970
1
1
t| Imaging Human Memory
p| 402
970
1
1
t| Encoding and the Hippocampus
p| 402
970
1
1
t| Retrieval and the Hippocampus
p| 404
970
1
1
t| Recognition, Familiarity, and the Medial Temporal Lobe
p| 404
970
1
1
t| Encoding, Retrieval, and the Frontal Cortex
p| 410
970
1
1
t| Retrieval and the Parietal Cortex
p| 410
970
1
1
t| Memory Consolidation
p| 413
970
1
1
t| The Hippocampus and Consolidation
p| 413
970
1
1
t| The Lateral Anterior Temporal Lobe and Consolidation
p| 414
970
1
1
t| Cellular Basis of Learning and Memory
p| 415
970
1
1
t| Long-Term Potentiation and the Hippocampus
p| 416
970
1
1
t| Long-Term Potentiation and Memory Performance
p| 418
970
1
1
l| 10.
t| Emotion
p| 424
970
1
1
t| What Is an Emotion?
p| 427
970
1
1
t| Neural Systems Involved in Emotion Processing
p| 428
970
1
1
t| Early Concepts: The Limbic System as the Emotional Brain
p| 428
970
1
1
t| Emerging Concepts of Emotional Networks
p| 429
970
1
1
t| Categorizing Emotions
p| 430
970
1
1
t| Basic Emotions
p| 431
970
1
1
t| Complex Emotions
p| 432
970
1
1
t| Dimensions of Emotion
p| 433
970
1
1
t| Theories of Emotion Generation
p| 434
970
1
1
t| James-Lange Theory
p| 434
970
1
1
t| Cannon-Bard Theory
p| 435
970
1
1
t| Appraisal Theory
p| 435
970
1
1
t| Singer-Schachter Theory: Cognitive Interpretation of Arousal
p| 435
970
1
1
t| Constructivist Theories
p| 436
970
1
1
t| Evolutionary Psychology Approach
p| 436
970
1
1
t| LeDoux's High Road and Low Road
p| 436
970
1
1
t| The Amygdala
p| 437
970
1
1
t| Interactions Between Emotion and Other Cognitive Processes
p| 438
970
1
1
t| The Influence of Emotion on Learning
p| 439
970
1
1
t| Implicit Emotional Learning
p| 439
970
1
1
t| Explicit Emotional Learning
p| 443
970
1
1
t| The Influence of Emotion on Perception and Attention
p| 446
970
1
1
t| Emotion and Decision Making
p| 447
970
1
1
t| Emotion and Social Stimuli
p| 449
970
1
1
t| Get A Grip! Cognitive Control of Emotion
p| 455
970
1
1
t| Other Areas, Other Emotions
p| 459
970
1
1
t| The Insular Cortex
p| 459
970
1
1
t| Disgust
p| 460
970
1
1
t| Happiness
p| 461
970
1
1
t| Love
p| 461
970
1
1
t| Unique Systems, Common Components
p| 464
970
1
1
l| 11.
t| Language
p| 468
970
1
1
t| The Anatomy of Language
p| 471
970
1
1
t| Brain Damage and Language Deficits
p| 472
970
1
1
t| Broca's Aphasia
p| 472
970
1
1
t| Wernicke's Aphasia
p| 473
970
1
1
t| Conduction Aphasia
p| 474
970
1
1
t| The Fundamentals of Language in the Human Brain
p| 475
970
1
1
t| Words and the Representation of Their Meaning
p| 475
970
1
1
t| Models of the Mental Lexicon
p| 476
970
1
1
t| Neural Substrates of the Mental Lexicon
p| 477
970
1
1
t| Language Comprehension
p| 480
970
1
1
t| Perceptual Analyses of the Linguistic Input
p| 480
970
1
1
t| Spoken Input: Understanding Speech
p| 481
970
1
1
t| Written Input: Reading Words
p| 484
970
1
1
t| The Role of Context in Word Recognition
p| 489
970
1
1
t| Integration of Words in Sentences
p| 490
970
1
1
t| Semantic Processing and the N400 Wave
p| 490
970
1
1
t| Syntactic Processing and the P600 Wave
p| 491
970
1
1
t| Neural Models of Language Comprehension
p| 495
970
1
1
t| Networks of the Left-Hemisphere Language System
p| 496
970
1
1
t| Neural Models of Speech Production
p| 496
970
1
1
t| Evolution of Language
p| 500
970
1
1
t| Shared Intentionality
p| 500
970
1
1
l| pt. III
t| Control Processes
970
1
1
l| 12.
t| Cognitive Control
p| 506
970
1
1
t| What Is Cognitive Control?
p| 508
970
1
1
t| The Anatomy Behind Cognitive Control
p| 509
970
1
1
t| Subdivisions of the Frontal Lobes
p| 509
970
1
1
t| Networks Underlying Cognitive Control
p| 509
970
1
1
t| Cognitive Control Deficits
p| 510
970
1
1
t| Goal-Oriented Behavior
p| 511
970
1
1
t| Cognitive Control Requires Working Memory
p| 512
970
1
1
t| Prefrontal Cortex Is Necessary for Working Memory but Not Associative Memory
p| 512
970
1
1
t| Physiological Correlates of Working Memory
p| 513
970
1
1
t| Processing Differences Across Prefrontal Cortex
p| 517
970
1
1
t| Hierarchical Organization of Prefrontal Cortex
p| 519
970
1
1
t| Decision Making
p| 520
970
1
1
t| Is It Worth It? Value and Decision Making
p| 521
970
1
1
t| Components of Value
p| 522
970
1
1
t| Representation of Value
p| 522
970
1
1
t| More Than One Type of Decision System?
p| 525
970
1
1
t| Dopamine Activity and Reward Processing
p| 526
970
1
1
t| Alternative Views of Dopamine Activity
p| 530
970
1
1
t| Goal Planning
p| 532
970
1
1
t| Cognitive Control Is Necessary for Planning and Staying on Goal
p| 534
970
1
1
t| Retrieval and Selection of Task-Relevant Information
p| 535
970
1
1
t| Task Switching
p| 538
970
1
1
t| Goal-Based Cognitive Control
p| 539
970
1
1
t| Goal Representation and the Inhibition and Enhancement of Working Memory Representations
p| 539
970
1
1
t| Prefrontal Cortex and Modulation of Processing
p| 543
970
1
1
t| Inhibiting Activation of Long-Term Memory
p| 545
970
1
1
t| Inhibition of Action
p| 545
970
1
1
t| Ensuring That Goal-Oriented Behaviors Succeed
p| 549
970
1
1
t| The Medial Frontal Cortex as a Monitoring System
p| 550
970
1
1
t| How Does Medial Frontal Cortex Monitor Processing in Cognitive Control Networks?
p| 550
970
1
1
l| 13.
t| Social Cognition
p| 558
970
1
1
t| Anatomical Substrates of Social Cognition
p| 561
970
1
1
t| Deficits
p| 561
970
1
1
t| Socrates' Imperative: Know Thyself
p| 563
970
1
1
t| Self-Referential Processing
p| 563
970
1
1
t| Self-Descriptive Personality Traits
p| 567
970
1
1
t| Self-Reference as a Baseline Mode of Brain Function
p| 568
970
1
1
t| Self-Perception as a Motivated Process
p| 570
970
1
1
t| Predicting Our Future Mental State
p| 572
970
1
1
t| Theory of Mind: Understanding the Mental States of Others
p| 573
970
1
1
t| Developmental Milestones
p| 573
970
1
1
t| Mechanisms for Inferring Other People's Thoughts
p| 575
970
1
1
t| Neural Correlates of Mental State Attribution
p| 580
970
1
1
t| Autism as a Window on the Role of Mental State Attribution
p| 586
970
1
1
t| Social Knowledge
p| 592
970
1
1
t| Representations of Social Knowledge
p| 593
970
1
1
t| Using Social Knowledge to Make Decisions
p| 595
970
1
1
t| Neuroeconomics
p| 596
970
1
1
t| Moral Decisions
p| 598
970
1
1
l| 14.
t| Consciousness, Free Will, and the Law
p| 604
970
1
1
t| Anatomical Orientation
p| 607
970
1
1
t| The Brainstem
p| 607
970
1
1
t| The Thalamus
p| 608
970
1
1
t| The Cerebral Cortex
p| 608
970
1
1
t| Consciousness
p| 608
970
1
1
t| Conscious Versus Unconscious Processing and the Access of Information
p| 610
970
1
1
t| The Extent of Subconscious Processing
p| 612
970
1
1
t| Gaining Access to Consciousness
p| 615
970
1
1
t| Sentience
p| 618
970
1
1
t| Neurons, Neuronal Groups, and Conscious Experience
p| 618
970
1
1
t| The Emergence of the Brain Interpreter in the Human Species
p| 620
970
1
1
t| Left- and Right-Hemisphere Consciousness
p| 621
970
1
1
t| Is Consciousness a Uniquely Human Experience?
p| 622
970
1
1
t| Abandoning the Concept of Free Will
p| 623
970
1
1
t| Determinism and Physics
p| 624
970
1
1
t| Chaos
p| 625
970
1
1
t| Quantum Theory
p| 625
970
1
1
t| Emergence
p| 626
970
1
1
t| Multiple Realiability
p| 627
970
1
1
t| Can Mental States Affect Brain Processing?
p| 628
970
1
1
t| The Layer Beyond the Brain
p| 631
970
1
1
t| The Law
p| 631
970
1
1
t| Responsibility
p| 632
970
1
1
t| Guilty-Now What?
p| 636
970
1
1
t| Born to Judge
p| 637
970
1
1
t| What's a Judge to Do?
p| 638
970
1
1
t| Crime and No Punishment?
p| 639
970
1
1
t| Taming the Wild Beast
p| 639
970
0
1
t| Glossary
p| 1
970
0
1
t| References
p| 1
970
0
1
t| Abbreviations
p| 1
970
0
1
t| Credits
p| 1
970
0
1
t| Index
p| 1
998
a| book
b| 30-06-14
c| m
d| a
e| -
f| eng
g| nyu
h| 0
i| 0
945
h| Supplement
l| location
i| barcode
y| id
f| bookplate
a| callnoa
b| callnob
n| PSY405