1739712835371_65220_doc

Page 1: Syllabus

Overview

  • Batch: 2024-25

  • Date: 13/02/2025

  • Subjects:

    • Physics: Ray Optics

    • Chemistry: Electrochemistry

    • Biology: Molecular Basis of Inheritance, Principles of Inheritance and Variation


Page 2: Physics Revision/Test Series

Academics

  • Institute: Sri Vidya Aradhana Academy, Latur

  • Test Series Details: NEET-RCWT-02

  • Date: 13/02/2025

Physics Questions

  1. Critical Angle: Minimum for which color as light passes from glass to air?

    • Options: Red, Green, Yellow, Violet

  2. Concave Lens: Object at focus - determine image distance and magnification.

  3. Refractive Index: Calculate based on depth and apparent height.

  4. Image in Mirror: Identify type of mirror based on specific image size relation.

  5. Lens in Liquid: Focal length alteration when immersed in liquid.

  6. Real Image with Biconvex Lens: Effect of immersion in water on real image.

  7. Prism Deviation: Determine ratio of dispersive powers for prisms.

  8. Bubble Reflection: Statement validation about air bubble behavior in water.

  9. Convex Lens Magnification: Determine object distance producing magnified image.


Page 3: Detailed Questions

Topics of Interest

  1. Spherical Mirror: Relation between focal length and radius of curvature.

  2. Image Properties: Identify image nature and magnification based on object position in front of mirror.

  3. Apparent Depth: Calculate using refractive indices of immiscible liquids.

  4. Phase Change: Reflection of light - determine phase change at interface.

  5. Prism Incident Light: Understand deviations in minimum position.

  6. Ray Reflection: Analyze angles in relation to horizontal plane.

  7. Convex Mirror Imaging: Understand image formation distances and outcome.

  8. Equilateral Prism and Wavelength: To find refractive index involving wavelength.


Page 4: Matching and Statement Validation

Inquiry Focus

  1. Optical Types: Match various lens types to their definitions.

  2. Assertion and Reasoning: Evaluate correctness about optical principles.

  3. Refractive Index Relation: Clarify relationships between incidence and refraction.

  4. Telescope Design: Find power requirements for telecope components.

  5. Incidence Angle: Calculate for light ray incidents on a prism.

  6. Ray Path Parallelism: Determine conditions for parallel rays post-emergence.

  7. Reflected Ray Analysis: Image formation resulting from mirror reflection.

  8. Path Representation: Identify least time path for light from rarer to denser medium.


Page 5: Image Formation in Lenses

Key Points

  1. Convex Mirror Imaging: Determine image characteristics related to distance.

  2. Distance Calculation: Real-world application of refractive index principles.

  3. Light Dispersion: Recognize correct representation in diagrams.

  4. Light Emission Radius: Based on depth and indexed properties of water.

  5. Image Formation: Effects of lens covering on image stability and visibility.

  6. Lens Division: Understand power dynamics after lens cutting.

  7. Plano-Concave Lens: Calculate refractive index given curvatures.

  8. Object Placement and Image Distance: Formulations and calculations based on distances.

  9. Graph Measurement: Illustrate known concepts via graphical representation.


Page 6: Astronomical Telescope

Telescope Mechanics

  1. Telescope Design: Compare focal lengths of objective vs. eyepiece.

  2. Light Beam Analysis: Laser interaction with crystal structures.

  3. Image Count: Number of images resulting from multiple material lenses.

  4. Telescope Application: Diameter calculation for celestial objects.

  5. Lens Blocking: Runtime implications of lens portioning on image intensity.

  6. Microscope Functionality: Magnifying power calculations with components.

  7. Telescope Construction: Identify contributing lenses based on specifications.

  8. Refraction and Images: Image outcomes based on air bubble intersections.

  9. Mirror Reflection: Behavior of images related to mirror specifics.

  10. Time Interpretation: Clock interactions with reflective surfaces.

  11. Lens Combination Power: Analyze power calculations for composite lens systems.


Page 7: Electrochemistry Section

Cell Basics

  1. Electrochemical Basics: Determine electrode behaviors in specific cell setups.

  2. Spontaneous Reactions: Conditions for spontaneity in cell potentials.

  3. Daniel Cell Mechanics: Understand electron and current flows in arrangements.

  4. Silver Synthesis: Quantification of material deposition from electrochemical reactions.

  5. Reduction Potential Values: Compute potential interactions in paired reactions.

  6. Correct EMF Expression: Analyze electrochemical equations for validity.


Page 8: Conductivity in Solutions

Properties and Reactions

  1. EMF Verification: Conduct verification of electrochemical setups.

  2. Conductivity Factors: Key components affecting ionic behavior.

  3. Reducing Agents: Analyzing reducing reactions for effectiveness.

  4. Salt Bridge Construction: Reasons for salt selectivity.

  5. Electrochemical Voltage: Highest voltage provided by reactions based on potentials.


Page 9: Cell Reactions and Potential Calculations

Reaction Dynamics

  1. Zn and Ag Dynamics: Evaluating reactions and oxidation states.

  2. Polymorphism in Solutions: Analyze underlying principles of ionic behavior in solutions.

  3. Equivalent Conductance: Understanding variations in weak electrolytes.

  4. Electrode Potentials: Assess potential rankings based on electromotive capabilities.

  5. Conductivity Measurement: Understand implications of molar conductivities in reactions.


Page 10: Electrolysis Concepts

Cells Assessment

  1. Hydrogen Electrode Discourse: Explain zero potential characteristics in electrodes.

  2. Copper Interaction in Solutions: Reactions causing color changes in copper interactions.

  3. Metal Reduction Ranking: Cation evaluations based on related reduction potentials.

  4. Complex Reactions in Cells: Study potential calculations involving log applications.

  5. Half-cell Evaluations: Determine voltaic potentials from combined electrochemical identities.


Page 11: Biology: Genetic Codes and Experiments

Experimentation and Codes

  1. Protein Synthesis: Explore contributions and discoveries in genetic coding.

  2. Haemophilia Insights: Review genetic implications of diseases based on heredity.

  3. Monocistronic mRNA Definition: Understand the structural significance for proteins.

  4. Genetic Determination Methods: Match several determination systems to their applications.

  5. Start Codons: Identify key starter signals in genetic coding systems.


Page 12: Molecular Biology and Contributions

Deeper Insights

  1. DNA Structural Elements: Understand the single and double-stranded nature of bases.

  2. Pleiotropism: Evaluate single gene effects using phenotypic expressions.

  3. Hershey-Chase Experiment: Review structure and implications in genetic discoveries.

  4. Colour Blindness Mechanism: Analyze genetic patterns leading to disorders.

  5. tRNA Amino Attachment: Identify binding sites for amino acids in tRNA.

  6. Human Chromosomal Structure: Confirm chromosomal arrangements in human genetics.


Page 13: Genetic Mechanisms

Genetic Definitions

  1. Gene Composition: Explain the function with respect to introns and exons.

  2. Blood Group Example: Discuss various inheritance patterns leading to outcomes.

  3. Prokaryotic DNA Characteristics: Explore compaction and organization principles.

  4. Haemophilia Misconceptions: Address misleading genetic interpretations in heredity.

  5. DNA Material Evidence: Trace claims related to DNA defining characteristics.

  6. Discovery Contributions: Analyze significance in DNA structural propositions.

  7. Genotypic and Phenotypic Ratios: Distinguish proportions in inheritance.

  8. Translation Codon Recognition: Identify stop codons in termination processes.

  9. Gene Mapping via Distances: Elucidate genetic mappings within observations.

  10. DNA Antiparallel Nature: Evaluate structural implications on functionality.


Page 14: Genetic Crosses and Principles

Cross Analysis

  1. Mendel’s Methodologies: Review foundational teachings in genetic crossings.

  2. Factors in Separation: Evaluate unique problems related to gene expressions.

  3. Genetic Dominance in Traits: Establish connections between alleles in peas.

  4. Genomic History: Describe past classifications of genetic arrangements.

  5. Codon Importance: Describe the significance of codons in protein synthesis.

  6. Human Pedigree Analysis: Learn the meanings assigned to symbols in genetic mapping.

  7. Tandem Repeats Functions: Explore applications for fingerprinting within practices.

  8. Klinefelter's Chromosomal Structure: Identify anomalies in genetic formation.

  9. Lactose Hydrolysis Process: Match enzymatic actions in biological processes.


Page 15: Genetic Characterizations and Mutations

Genetic Distinctions

  1. Seed Appearance Outcomes: Analyze outcomes from genetic plant crossings.

  2. Linkage Studies References: Connect definitions and their expectant behaviors.

  3. Linkage Mapping Principles: Understand implications in genetic distance interpretations.

  4. Lac Operon Mechanisms: Explore how regulators impact function.

  5. Gynaecomastia Associations: Distinguish symptoms related to genetic disorders.

  6. RNA Misconceptions: Identify common errors in understanding RNA functionalities.

  7. Codominance Effects: Clarify definitions and their application in genetic crosses.

  8. Sanger's Sequencing Role: Recognize sequencing contributions to molecular genetics.

  9. Phenotypic Consequences: Discuss how mutations impact variations.

  10. DNA Base Pair Calculation: Estimate pairings based on fundamental rules of pairing.


Page 16: Genetics Review and Specifics

Genetic Evaluation

  1. Blood Group Outcomes: Study inheritance through specific examples.

  2. Transcription Process Mechanism: Specify which genes are actively transcribed.

  3. Crossing Mechanism Closure: Evaluate the effects of genetic arrangements.

  4. RNA Stability Analysis: Discuss the labile nature of RNA structures.

  5. Genetic Pair Matching: Solve classifications in fundamental genetic studies.

  6. DNAbased Techniques: Identify correct procedures within fingerprinting.

  7. Variation Causes: Define causes of variation within species.

  8. Polygenic Inheritance Examples: Determine instances in genetics.

  9. SNP Variability: Analyze frequency of occurrences based on standard definitions.

  10. Molecular Length Estimation: Estimate sizes based on calculations derived from DNA structures.


Page 17: Advanced Genetic Discussions

Genetic Mechanisms

  1. True Dihybrid Conditions: Analyze concerning classifications.

  2. Synthesis and Codons: Engage in discussions regarding translations.

  3. DNA vs. Enzymes: Compare purpose and classifications for both.

  4. Mendel Recognition Factors: Establish basis for past misunderstandings.

  5. RNA Characteristics: Define standard properties and features linked to coupling.

  6. Genetic Crosses Clarity: Understand the role of diverse contributions.

  7. Gene Distribution: Discuss partitioning within genetic studies.

  8. Contribution Overview: Highlight historical breakthroughs within genetic discoveries.

  9. Pairing Structuring: Address mismatches with particular orders of traits.

  10. Fusion Definitions and Interventions: Perform comparisons of terminology accuracy.


Page 18: Review of Human Genetics

Human Chromosome Analysis

  1. Blood Group Relations: Conceptual adjustments required for multiple pairings.

  2. Discontinuous Synthesis Basis: Engage in learning differentiation of DNA structures.

  3. Test Cross Utilization: Clarify definitions in practical assessments.

  4. Polymorphic Definitions: Standardize measurements accordingly for traits.

  5. Sex Determination Factors: Study mechanisms responsible for determining sex.

  6. Trait Cross Explanations: Define principles behind recessive conditions.

  7. Gene Mapping Clarity: Analyze inaccuracies surrounding gene distances.

  8. Growth and Functionality: Discuss topic relevance in metabolism studies.

  9. False Information Identification: Standard error checks within genetic discussions.

  10. Variability in Genomic Sequence: Evaluate single nucleotide variations through potential impacts.

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