The document provides an introduction to the 2010 edition of Prekindergarten-Grade 8 Science Curriculum Standards for Connecticut. It outlines that the standards include Grade-Level Concepts (GLCs), Grade-Level Expectations (GLEs), and Key Concept Words to provide clear guidelines for developing curriculum and instruction. GLCs describe the conceptual boundaries for each standard, GLEs are measurable learner outcomes that demonstrate understanding, and Key Concept Words highlight important science vocabulary. The standards were developed by Connecticut science educators and reviewed by experts.
This document provides an overview of key concepts in science education, including:
1. Definitions of science as a body of knowledge and a process for understanding the natural world.
2. The benefits of an inquiry-based approach to science instruction that parallels scientific practice.
3. The importance of developing conceptual understanding in students through engagement with concepts and building conceptual frameworks.
This document provides an overview of key concepts in science education, including:
1. Definitions of science as a body of knowledge and a process of inquiry.
2. The importance of an inquiry-based approach to science instruction that parallels scientific practice.
3. National standards and frameworks that aim to define what students should know in science, including Science for All Americans and the National Science Education Standards.
4. Current reforms advocating reducing science content standards to allow for more in-depth study of core concepts.
The document outlines a lesson plan for a course introduction that covers instructor expectations, an assessment of student academic levels, an introduction to the scientific method, and exposure to the definition of science. Key objectives are for students to understand instructor expectations, define science, describe the abilities and limitations of science, and describe parts of the scientific method. Students will sign a behavior contract, take part in a non-science task, learn about Cornell note-taking, and work in partners to take notes on a reading about the nature of science. The lesson incorporates state science standards and includes teacher presentations, student activities, assessments, and a closing summary.
Metodologi Penelitian - Utilitas Laboratorium Program Studi Teknik Industri F...Endang Hidayat
Ringkasan dokumen tersebut adalah:
1. Dokumen tersebut membahas survei tentang utilisasi laboratorium di Program Studi Teknik Industri Universitas Pasundan.
2. Survei ini menilai tingkat kenyamanan, sarana prasarana, penguasaan materi dosen, dan peran tenaga pengajar di laboratorium.
3. Hasilnya menunjukkan bahwa laboratorium memiliki tingkat kenyamanan dan penguasaan materi dosen yang baik, tetapi sarana prasarana mas
Electricity is a form of energy that occurs naturally from lightning or is produced in generators through the movement and interaction of electrons. Materials that allow electricity to pass through are called conductors, such as scissors, paper clips, aluminum foil, iron, steel and copper. Materials that do not allow electricity to pass through are called insulators, like cotton, paper, plastic, glass and rubber. The complete path that electricity flows through is called a circuit, which must be unbroken to allow electricity to flow. Electricity can be dangerous if not used properly.
Презентация Виталия Панарина с конференции РИФ+КИБ 2014. Тема доклада - контент маркетинг в действии.
В презентации идет речь о привлечении пользователей в интернет-магазин за счет создания интересного контента.
This document provides an overview of key concepts in science education, including:
1. Definitions of science as a body of knowledge and a process for understanding the natural world.
2. The benefits of an inquiry-based approach to science instruction that parallels scientific practice.
3. The importance of developing conceptual understanding in students through engagement with concepts and building conceptual frameworks.
This document provides an overview of key concepts in science education, including:
1. Definitions of science as a body of knowledge and a process of inquiry.
2. The importance of an inquiry-based approach to science instruction that parallels scientific practice.
3. National standards and frameworks that aim to define what students should know in science, including Science for All Americans and the National Science Education Standards.
4. Current reforms advocating reducing science content standards to allow for more in-depth study of core concepts.
The document outlines a lesson plan for a course introduction that covers instructor expectations, an assessment of student academic levels, an introduction to the scientific method, and exposure to the definition of science. Key objectives are for students to understand instructor expectations, define science, describe the abilities and limitations of science, and describe parts of the scientific method. Students will sign a behavior contract, take part in a non-science task, learn about Cornell note-taking, and work in partners to take notes on a reading about the nature of science. The lesson incorporates state science standards and includes teacher presentations, student activities, assessments, and a closing summary.
Metodologi Penelitian - Utilitas Laboratorium Program Studi Teknik Industri F...Endang Hidayat
Ringkasan dokumen tersebut adalah:
1. Dokumen tersebut membahas survei tentang utilisasi laboratorium di Program Studi Teknik Industri Universitas Pasundan.
2. Survei ini menilai tingkat kenyamanan, sarana prasarana, penguasaan materi dosen, dan peran tenaga pengajar di laboratorium.
3. Hasilnya menunjukkan bahwa laboratorium memiliki tingkat kenyamanan dan penguasaan materi dosen yang baik, tetapi sarana prasarana mas
Electricity is a form of energy that occurs naturally from lightning or is produced in generators through the movement and interaction of electrons. Materials that allow electricity to pass through are called conductors, such as scissors, paper clips, aluminum foil, iron, steel and copper. Materials that do not allow electricity to pass through are called insulators, like cotton, paper, plastic, glass and rubber. The complete path that electricity flows through is called a circuit, which must be unbroken to allow electricity to flow. Electricity can be dangerous if not used properly.
Презентация Виталия Панарина с конференции РИФ+КИБ 2014. Тема доклада - контент маркетинг в действии.
В презентации идет речь о привлечении пользователей в интернет-магазин за счет создания интересного контента.
This document discusses client service in Ukrainian contact centers. It identifies four main vectors to focus on: 1) reducing informational calls through alternative communication channels, 2) analyzing past activity to forecast fluctuations and allocate resources efficiently, 3) implementing quality control methods to improve agents' work, and 4) using contact centers for additional sales opportunities. Proper handling of these vectors can lead to reduced expenses, higher service quality, increased loyalty and sales. The acceptable working hours for agents in Ukraine are listed as well as typical call volume breakdowns and average call durations and costs.
This document provides information about making inferences when reading. It discusses how readers must use clues from stories to draw conclusions about what is not directly stated. It provides several examples of scenarios and asks the reader to make inferences based on the clues. It encourages readers to practice making inferences to get better at detecting clues and drawing conclusions from texts.
The document defines key terms related to presentations including print preview, which shows how a presentation will appear when printed; grayscale, which saves colored ink by printing in black and white; notes, which are additional information not seen by the audience; layout, which refers to the arrangement of placeholders on a slide; demote, which decreases the outline level of a paragraph; thumbnail, which is a small preview of a slide; indent level, which is the distance from the left border of a placeholder; template, which is a predesigned presentation; and handout, which is a printed copy for audience use. Presenter view allows seeing notes while the audience views slides.
The document discusses the key elements of an integrated marketing communications strategy, including advertising, sales promotion, publicity, personal selling, and social media. It provides details on the marketing, creative, media and assessment decisions involved in advertising. It also outlines various sales promotion techniques for consumers and trade partners, and how publicity and personal selling are used to communicate with stakeholders.
This document outlines the curriculum for Integrated Science in the first quarter. Students will learn about the scientific method and how to apply it through a teacher-guided community investigation. They will formulate problems, hypotheses, experiment designs and analyze results to draw conclusions. The goal is for students to understand how scientific inquiry helps solve problems and make informed decisions to protect the environment.
Georgia Third Grade Performance Standards in Science. From the Georgia Department of Education website: https://www.georgiastandards.org/Standards/Pages/BrowseStandards/ScienceStandardsK-5.aspx
The document outlines a first grade science curriculum that is aligned with national standards. It focuses on developing students' skills in asking questions, making observations, and conducting simple investigations about patterns in nature. The curriculum covers earth science topics like weather and seasons, physical science topics like sound and magnets, and life science topics like the basic needs of plants and animals. It emphasizes hands-on, inquiry-based learning and using tools to explore scientific concepts.
Human anatomyandphysiology approved2006wellmaker786
The document outlines the anatomy and physiology curriculum for human body studies. It is designed to build upon science concepts from K-8 and high school biology, with a focus on structure/function relationships, cellular processes, growth, homeostasis, heredity, and system interactions. The curriculum emphasizes hands-on learning and real-world applications. It integrates chemistry concepts and highlights related careers. Students are expected to demonstrate skills in scientific investigation, safe practices, use of tools and technology, data analysis, problem-solving, and clear communication.
1 Grade One Science Standards of Learning for Virginia PAbbyWhyte974
1
Grade One Science Standards of Learning for Virginia
Public Schools – January 2010
Introduction
The Science Standards of Learning for Virginia Public Schools identify academic content
for essential components of the science curriculum at different grade levels. Standards are
identified for kindergarten through grade five, for middle school, and for a core set of
high school courses — Earth Science, Biology, Chemistry, and Physics. Throughout a
student’s science schooling from kindergarten through grade six, content strands, or
topics are included. The Standards of Learning in each strand progress in complexity as
they are studied at various grade levels in grades K-6, and are represented indirectly
throughout the high school courses. These strands are
Scientific Investigation, Reasoning, and Logic;
Force, Motion, and Energy;
Matter;
Life Processes;
Living Systems;
Interrelationships in Earth/Space Systems;
Earth Patterns, Cycles, and Change; and
Earth Resources.
Five key components of the science standards that are critical to implementation and
necessary for student success in achieving science literacy are 1) Goals; 2) K-12 Safety;
3) Instructional Technology; 4) Investigate and Understand; and 5) Application. It is
imperative to science instruction that the local curriculum consider and address how these
components are incorporated in the design of the kindergarten through high school
science program.
Goals
The purposes of scientific investigation and discovery are to satisfy humankind’s quest
for knowledge and understanding and to preserve and enhance the quality of the human
experience. Therefore, as a result of science instruction, students will be able to achieve
the following objectives:
1. Develop and use an experimental design in scientific inquiry.
2. Use the language of science to communicate understanding.
3. Investigate phenomena using technology.
4. Apply scientific concepts, skills, and processes to everyday experiences.
2
5. Experience the richness and excitement of scientific discovery of the natural
world through the collaborative quest for knowledge and understanding.
6. Make informed decisions regarding contemporary issues, taking into account the
following:
public policy and legislation;
economic costs/benefits;
validation from scientific data and the use of scientific reasoning and logic;
respect for living things;
personal responsibility; and
history of scientific discovery.
7. Develop scientific dispositions and habits of mind including:
curiosity;
demand for verification;
respect for logic and rational thinking;
consideration of premises and consequences;
respect for historical contributions;
attention to accuracy and precision; and
patience and persistence.
8. Develop an understanding of the interrelationship of science with technology,
engineering and mathematics.
9. Exp ...
1
Grade One Science Standards of Learning for Virginia
Public Schools – January 2010
Introduction
The Science Standards of Learning for Virginia Public Schools identify academic content
for essential components of the science curriculum at different grade levels. Standards are
identified for kindergarten through grade five, for middle school, and for a core set of
high school courses — Earth Science, Biology, Chemistry, and Physics. Throughout a
student’s science schooling from kindergarten through grade six, content strands, or
topics are included. The Standards of Learning in each strand progress in complexity as
they are studied at various grade levels in grades K-6, and are represented indirectly
throughout the high school courses. These strands are
Scientific Investigation, Reasoning, and Logic;
Force, Motion, and Energy;
Matter;
Life Processes;
Living Systems;
Interrelationships in Earth/Space Systems;
Earth Patterns, Cycles, and Change; and
Earth Resources.
Five key components of the science standards that are critical to implementation and
necessary for student success in achieving science literacy are 1) Goals; 2) K-12 Safety;
3) Instructional Technology; 4) Investigate and Understand; and 5) Application. It is
imperative to science instruction that the local curriculum consider and address how these
components are incorporated in the design of the kindergarten through high school
science program.
Goals
The purposes of scientific investigation and discovery are to satisfy humankind’s quest
for knowledge and understanding and to preserve and enhance the quality of the human
experience. Therefore, as a result of science instruction, students will be able to achieve
the following objectives:
1. Develop and use an experimental design in scientific inquiry.
2. Use the language of science to communicate understanding.
3. Investigate phenomena using technology.
4. Apply scientific concepts, skills, and processes to everyday experiences.
2
5. Experience the richness and excitement of scientific discovery of the natural
world through the collaborative quest for knowledge and understanding.
6. Make informed decisions regarding contemporary issues, taking into account the
following:
public policy and legislation;
economic costs/benefits;
validation from scientific data and the use of scientific reasoning and logic;
respect for living things;
personal responsibility; and
history of scientific discovery.
7. Develop scientific dispositions and habits of mind including:
curiosity;
demand for verification;
respect for logic and rational thinking;
consideration of premises and consequences;
respect for historical contributions;
attention to accuracy and precision; and
patience and persistence.
8. Develop an understanding of the interrelationship of science with technology,
engineering and mathematics.
9. Exp ...
This document outlines performance tasks and rubrics to assess students' inquiry skills for the New England Common Assessment Program (NECAP) exam. It describes four broad areas of inquiry: formulating questions and hypotheses, planning and critiquing investigations, conducting investigations, and developing and evaluating explanations. For each area, it lists constructs detailing the skills students should demonstrate, such as analyzing data, identifying variables, and communicating conclusions. It provides examples of grade-level tasks and expectations for grades 4, 8, and 11 to elicit evidence of students' inquiry abilities in a manner appropriate to their level of learning. The purpose is to prepare students for success on the NECAP by evaluating their proficiency in critical scientific inquiry practices.
1) This document outlines the curriculum guide for the Science Research course for 7th grade students in the Special Program in Science.
2) The course aims to equip students with essential scientific attitudes and science process skills to conduct simple science investigations within the school premises, including observing, measuring, classifying, predicting, and communicating.
3) Over the course of the school year, students will learn about scientific attitudes, basic and integrated science process skills, variables, formulating hypotheses, experimental design, gathering and organizing data, analyzing and interpreting results, and communicating their findings.
The document outlines the curriculum for level two science for year 5 pupils. It aims to develop pupils' interest in science through investigations and activities that promote scientific thinking skills and attitudes. The curriculum focuses on integrating knowledge, skills and values through inquiry learning and problem solving. It is organized into themes, learning areas, objectives, activities and outcomes. Scientific process skills, thinking skills, attitudes and teaching strategies are also discussed.
(1) This document discusses science as a subject in education and the importance of teaching science processes. (2) It outlines various science processes like inferring, predicting, controlling variables, interpreting data, and experimenting that are essential for students to develop. (3) The document also emphasizes the abundance of instructional materials available to facilitate effective science teaching.
This document provides a daily lesson log for a 7th grade science teacher covering a week of lessons on microscopy, biological organization, and plant and animal cells. The log outlines objectives aligned to standards, topics to be covered each day, learning resources, teaching procedures and activities, and a reflection on student progress and areas for improvement. The lessons guide students to identify microscope parts, focus specimens, describe levels of biological organization, and differentiate plant and animal cells. Formative and summative assessments are used to evaluate learning.
Teachers Corinne Smith and Rebecca West are collaborating on a 7th grade life science lesson about cells with the school media specialist. The lesson will have students build on their prior knowledge of cells by researching cell structures and functions using multiple resources, both print and digital. Students will answer questions about cells during their research and use the information to create a model of a cell. The lesson will focus on using various informational materials in the media center and online to gain further understanding of cells.
This document outlines the agenda for a 6-day teacher training workshop on teaching science based on Pakistan's Single National Curriculum (SNC). Day 1 focuses on orienting teachers to the SNC and science textbooks. Teachers explore the SNC's key components and features of the textbooks. They analyze the alignment between curriculum, assessment, and instruction. Teachers also divide into groups to identify standards, benchmarks and learning outcomes for assigned science content from the SNC and textbooks. By the end of Day 1, teachers reflect on connecting the SNC and textbooks.
This document provides a unit plan template for a science unit focusing on scientific skills and science notebooks. The unit is designed for middle school students and will last approximately 2 weeks. It introduces students to concepts like the scientific method, science process skills, and using a science notebook. Students will participate in various lessons and activities to help them better understand these concepts, including exploring lab tools, doing a science process skills webquest, and viewing digital stories about using science notebooks. The goal is for students to develop scientific skills and use an investigative approach through regular use of an interactive science notebook.
Syllabus in Teaching Science in Elementary.docxEduardBrandia
This document outlines the syllabus for a course on teaching science in elementary school, focusing on physics, earth, and space science. The 3-credit course aims to develop understanding of basic science concepts and application of inquiry-based learning. It covers topics like force and motion, energy, geology, meteorology, and astronomy. Assessment includes coursework, lesson plans, class demonstrations, and exams. The course outcomes are for students to demonstrate science concept understanding, employ varied teaching strategies, and design assessment tools for elementary science learning.
3rd Q (2021-2022)_Feb.docx PRACTICAL RESEARCH I LESSON PLAN APPLYING KNOWLED...solthereseamericandr
CONTEXTUALIZED LESSON PLAN FOR 3RD QUARTER COT. THE LEARNING COMPETENCY IS EXPLAINS THEIMPORTANCE OF RESEARCH IN DAILY LIFE. I INTEGRATE THE LESSON IN ARALING PANLIPUNAN ( SHOWING DIFFERENT TOURIST SPOTS IN LEYTE AND ALSO VALUES EDUCATION INTEGRATION, GLOBAL WARMING INTEGRATION. I ALSO INCLUDE LITERACY AND NUMERACY SKILLS IN THIS LESSON PLAN.
This document discusses client service in Ukrainian contact centers. It identifies four main vectors to focus on: 1) reducing informational calls through alternative communication channels, 2) analyzing past activity to forecast fluctuations and allocate resources efficiently, 3) implementing quality control methods to improve agents' work, and 4) using contact centers for additional sales opportunities. Proper handling of these vectors can lead to reduced expenses, higher service quality, increased loyalty and sales. The acceptable working hours for agents in Ukraine are listed as well as typical call volume breakdowns and average call durations and costs.
This document provides information about making inferences when reading. It discusses how readers must use clues from stories to draw conclusions about what is not directly stated. It provides several examples of scenarios and asks the reader to make inferences based on the clues. It encourages readers to practice making inferences to get better at detecting clues and drawing conclusions from texts.
The document defines key terms related to presentations including print preview, which shows how a presentation will appear when printed; grayscale, which saves colored ink by printing in black and white; notes, which are additional information not seen by the audience; layout, which refers to the arrangement of placeholders on a slide; demote, which decreases the outline level of a paragraph; thumbnail, which is a small preview of a slide; indent level, which is the distance from the left border of a placeholder; template, which is a predesigned presentation; and handout, which is a printed copy for audience use. Presenter view allows seeing notes while the audience views slides.
The document discusses the key elements of an integrated marketing communications strategy, including advertising, sales promotion, publicity, personal selling, and social media. It provides details on the marketing, creative, media and assessment decisions involved in advertising. It also outlines various sales promotion techniques for consumers and trade partners, and how publicity and personal selling are used to communicate with stakeholders.
This document outlines the curriculum for Integrated Science in the first quarter. Students will learn about the scientific method and how to apply it through a teacher-guided community investigation. They will formulate problems, hypotheses, experiment designs and analyze results to draw conclusions. The goal is for students to understand how scientific inquiry helps solve problems and make informed decisions to protect the environment.
Georgia Third Grade Performance Standards in Science. From the Georgia Department of Education website: https://www.georgiastandards.org/Standards/Pages/BrowseStandards/ScienceStandardsK-5.aspx
The document outlines a first grade science curriculum that is aligned with national standards. It focuses on developing students' skills in asking questions, making observations, and conducting simple investigations about patterns in nature. The curriculum covers earth science topics like weather and seasons, physical science topics like sound and magnets, and life science topics like the basic needs of plants and animals. It emphasizes hands-on, inquiry-based learning and using tools to explore scientific concepts.
Human anatomyandphysiology approved2006wellmaker786
The document outlines the anatomy and physiology curriculum for human body studies. It is designed to build upon science concepts from K-8 and high school biology, with a focus on structure/function relationships, cellular processes, growth, homeostasis, heredity, and system interactions. The curriculum emphasizes hands-on learning and real-world applications. It integrates chemistry concepts and highlights related careers. Students are expected to demonstrate skills in scientific investigation, safe practices, use of tools and technology, data analysis, problem-solving, and clear communication.
1 Grade One Science Standards of Learning for Virginia PAbbyWhyte974
1
Grade One Science Standards of Learning for Virginia
Public Schools – January 2010
Introduction
The Science Standards of Learning for Virginia Public Schools identify academic content
for essential components of the science curriculum at different grade levels. Standards are
identified for kindergarten through grade five, for middle school, and for a core set of
high school courses — Earth Science, Biology, Chemistry, and Physics. Throughout a
student’s science schooling from kindergarten through grade six, content strands, or
topics are included. The Standards of Learning in each strand progress in complexity as
they are studied at various grade levels in grades K-6, and are represented indirectly
throughout the high school courses. These strands are
Scientific Investigation, Reasoning, and Logic;
Force, Motion, and Energy;
Matter;
Life Processes;
Living Systems;
Interrelationships in Earth/Space Systems;
Earth Patterns, Cycles, and Change; and
Earth Resources.
Five key components of the science standards that are critical to implementation and
necessary for student success in achieving science literacy are 1) Goals; 2) K-12 Safety;
3) Instructional Technology; 4) Investigate and Understand; and 5) Application. It is
imperative to science instruction that the local curriculum consider and address how these
components are incorporated in the design of the kindergarten through high school
science program.
Goals
The purposes of scientific investigation and discovery are to satisfy humankind’s quest
for knowledge and understanding and to preserve and enhance the quality of the human
experience. Therefore, as a result of science instruction, students will be able to achieve
the following objectives:
1. Develop and use an experimental design in scientific inquiry.
2. Use the language of science to communicate understanding.
3. Investigate phenomena using technology.
4. Apply scientific concepts, skills, and processes to everyday experiences.
2
5. Experience the richness and excitement of scientific discovery of the natural
world through the collaborative quest for knowledge and understanding.
6. Make informed decisions regarding contemporary issues, taking into account the
following:
public policy and legislation;
economic costs/benefits;
validation from scientific data and the use of scientific reasoning and logic;
respect for living things;
personal responsibility; and
history of scientific discovery.
7. Develop scientific dispositions and habits of mind including:
curiosity;
demand for verification;
respect for logic and rational thinking;
consideration of premises and consequences;
respect for historical contributions;
attention to accuracy and precision; and
patience and persistence.
8. Develop an understanding of the interrelationship of science with technology,
engineering and mathematics.
9. Exp ...
1
Grade One Science Standards of Learning for Virginia
Public Schools – January 2010
Introduction
The Science Standards of Learning for Virginia Public Schools identify academic content
for essential components of the science curriculum at different grade levels. Standards are
identified for kindergarten through grade five, for middle school, and for a core set of
high school courses — Earth Science, Biology, Chemistry, and Physics. Throughout a
student’s science schooling from kindergarten through grade six, content strands, or
topics are included. The Standards of Learning in each strand progress in complexity as
they are studied at various grade levels in grades K-6, and are represented indirectly
throughout the high school courses. These strands are
Scientific Investigation, Reasoning, and Logic;
Force, Motion, and Energy;
Matter;
Life Processes;
Living Systems;
Interrelationships in Earth/Space Systems;
Earth Patterns, Cycles, and Change; and
Earth Resources.
Five key components of the science standards that are critical to implementation and
necessary for student success in achieving science literacy are 1) Goals; 2) K-12 Safety;
3) Instructional Technology; 4) Investigate and Understand; and 5) Application. It is
imperative to science instruction that the local curriculum consider and address how these
components are incorporated in the design of the kindergarten through high school
science program.
Goals
The purposes of scientific investigation and discovery are to satisfy humankind’s quest
for knowledge and understanding and to preserve and enhance the quality of the human
experience. Therefore, as a result of science instruction, students will be able to achieve
the following objectives:
1. Develop and use an experimental design in scientific inquiry.
2. Use the language of science to communicate understanding.
3. Investigate phenomena using technology.
4. Apply scientific concepts, skills, and processes to everyday experiences.
2
5. Experience the richness and excitement of scientific discovery of the natural
world through the collaborative quest for knowledge and understanding.
6. Make informed decisions regarding contemporary issues, taking into account the
following:
public policy and legislation;
economic costs/benefits;
validation from scientific data and the use of scientific reasoning and logic;
respect for living things;
personal responsibility; and
history of scientific discovery.
7. Develop scientific dispositions and habits of mind including:
curiosity;
demand for verification;
respect for logic and rational thinking;
consideration of premises and consequences;
respect for historical contributions;
attention to accuracy and precision; and
patience and persistence.
8. Develop an understanding of the interrelationship of science with technology,
engineering and mathematics.
9. Exp ...
This document outlines performance tasks and rubrics to assess students' inquiry skills for the New England Common Assessment Program (NECAP) exam. It describes four broad areas of inquiry: formulating questions and hypotheses, planning and critiquing investigations, conducting investigations, and developing and evaluating explanations. For each area, it lists constructs detailing the skills students should demonstrate, such as analyzing data, identifying variables, and communicating conclusions. It provides examples of grade-level tasks and expectations for grades 4, 8, and 11 to elicit evidence of students' inquiry abilities in a manner appropriate to their level of learning. The purpose is to prepare students for success on the NECAP by evaluating their proficiency in critical scientific inquiry practices.
1) This document outlines the curriculum guide for the Science Research course for 7th grade students in the Special Program in Science.
2) The course aims to equip students with essential scientific attitudes and science process skills to conduct simple science investigations within the school premises, including observing, measuring, classifying, predicting, and communicating.
3) Over the course of the school year, students will learn about scientific attitudes, basic and integrated science process skills, variables, formulating hypotheses, experimental design, gathering and organizing data, analyzing and interpreting results, and communicating their findings.
The document outlines the curriculum for level two science for year 5 pupils. It aims to develop pupils' interest in science through investigations and activities that promote scientific thinking skills and attitudes. The curriculum focuses on integrating knowledge, skills and values through inquiry learning and problem solving. It is organized into themes, learning areas, objectives, activities and outcomes. Scientific process skills, thinking skills, attitudes and teaching strategies are also discussed.
(1) This document discusses science as a subject in education and the importance of teaching science processes. (2) It outlines various science processes like inferring, predicting, controlling variables, interpreting data, and experimenting that are essential for students to develop. (3) The document also emphasizes the abundance of instructional materials available to facilitate effective science teaching.
This document provides a daily lesson log for a 7th grade science teacher covering a week of lessons on microscopy, biological organization, and plant and animal cells. The log outlines objectives aligned to standards, topics to be covered each day, learning resources, teaching procedures and activities, and a reflection on student progress and areas for improvement. The lessons guide students to identify microscope parts, focus specimens, describe levels of biological organization, and differentiate plant and animal cells. Formative and summative assessments are used to evaluate learning.
Teachers Corinne Smith and Rebecca West are collaborating on a 7th grade life science lesson about cells with the school media specialist. The lesson will have students build on their prior knowledge of cells by researching cell structures and functions using multiple resources, both print and digital. Students will answer questions about cells during their research and use the information to create a model of a cell. The lesson will focus on using various informational materials in the media center and online to gain further understanding of cells.
This document outlines the agenda for a 6-day teacher training workshop on teaching science based on Pakistan's Single National Curriculum (SNC). Day 1 focuses on orienting teachers to the SNC and science textbooks. Teachers explore the SNC's key components and features of the textbooks. They analyze the alignment between curriculum, assessment, and instruction. Teachers also divide into groups to identify standards, benchmarks and learning outcomes for assigned science content from the SNC and textbooks. By the end of Day 1, teachers reflect on connecting the SNC and textbooks.
This document provides a unit plan template for a science unit focusing on scientific skills and science notebooks. The unit is designed for middle school students and will last approximately 2 weeks. It introduces students to concepts like the scientific method, science process skills, and using a science notebook. Students will participate in various lessons and activities to help them better understand these concepts, including exploring lab tools, doing a science process skills webquest, and viewing digital stories about using science notebooks. The goal is for students to develop scientific skills and use an investigative approach through regular use of an interactive science notebook.
Syllabus in Teaching Science in Elementary.docxEduardBrandia
This document outlines the syllabus for a course on teaching science in elementary school, focusing on physics, earth, and space science. The 3-credit course aims to develop understanding of basic science concepts and application of inquiry-based learning. It covers topics like force and motion, energy, geology, meteorology, and astronomy. Assessment includes coursework, lesson plans, class demonstrations, and exams. The course outcomes are for students to demonstrate science concept understanding, employ varied teaching strategies, and design assessment tools for elementary science learning.
3rd Q (2021-2022)_Feb.docx PRACTICAL RESEARCH I LESSON PLAN APPLYING KNOWLED...solthereseamericandr
CONTEXTUALIZED LESSON PLAN FOR 3RD QUARTER COT. THE LEARNING COMPETENCY IS EXPLAINS THEIMPORTANCE OF RESEARCH IN DAILY LIFE. I INTEGRATE THE LESSON IN ARALING PANLIPUNAN ( SHOWING DIFFERENT TOURIST SPOTS IN LEYTE AND ALSO VALUES EDUCATION INTEGRATION, GLOBAL WARMING INTEGRATION. I ALSO INCLUDE LITERACY AND NUMERACY SKILLS IN THIS LESSON PLAN.
The document discusses different perspectives on curriculum design and knowledge acquisition in geography education. It presents three potential futures for geography education: 1) "Govian Elitism" which focuses only on procedural knowledge, 2) A "Knowledge Society" which balances procedural, content, and core knowledge, and 3) "Objective Knowledge" which focuses only on core knowledge. The key idea is that students need all three types of knowledge (core, content, and procedural) to fully understand geography. Geographical inquiry is presented as a way to connect these different types of knowledge through activities that create needs to know, use data, make sense of information, and reflect on learning.
Total Credits: 4; Marks: 100; Hours: 60 for theory excluding hours to be spent by student
teachers for completing assignments
Note: Figures in the bracket show hours for curriculum transaction
Module 1: Understanding Curriculum and Aims of Science and Technology (Credit 1,
Hours 15, Marks 25)
Objectives: After learning this module the student teacher will be able to-
- explain the nature and structure of science
- understand the aims of Science education
- plan for imbibing values through Science teaching
- write instructional objectives of teaching of a topic
- analyze features of existing curriculum of Science and Technology in the light of
NCF 2005 and principles of curriculum development
- establish correlation of Science with other subjects
Contents :
1. Nature and Structure of Science: Characteristics and functions of Science and
Technology, Branches of Science; Facts, concepts, principles, laws and theories in
context of science (3)
2. Aims of teaching Science and Technology:(2)
3. Developing scientific attitude and scientific temper
4. Nurturing the natural curiosity, aesthetic senses and creativity in Science
5. Acquiring the skills to understand the method and process of science that lead to
exploration, generation and validation of knowledge in science
6. Relating Science education to the environment (natural environment, artifacts and
people)
7. Solving problems of everyday life
8. Values and Learning Science: Imbibing the values of honesty, integrity, cooperation,
concern for life and preservation of environment, health, peace, equity (2)
9. Objectives at upper primary and secondary school level as given by State curriculum (1)
10. Determining acceptable evidences that show learners‘ understanding with the help of
Bloom and Anderson‘s hierarchy of objectives of teaching ( 2)
11. Expectations about constructivist science teaching in NCF 2005, General principles of
curriculum development and Trends in Science curriculum; Consideration in developing
learner centered curriculum in science, Analysis of Features of existing curriculum of
science and technology at upper primary and secondary school level and textbooks(4)
12. Establishing correlation of Science with other school subjects and life(1)
Module 1 of SNDT University of FYBEd.
The document provides a lesson plan for teaching grade 8 science students about quarks and leptons. The lesson uses a hands-on activity where students dismantle cookies and explore the ingredients (dough, chocolate chips) as analogies for subatomic particles (protons, neutrons, quarks). Students then use sorting cards to model the patterns between cookie ingredients and subatomic particles. The lesson aims to help students understand that all matter is made of different combinations of fundamental particles like quarks and leptons. The teacher assesses students formatively through observing their card sorting and discussions.
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This document provides an overview of wound healing, its functions, stages, mechanisms, factors affecting it, and complications.
A wound is a break in the integrity of the skin or tissues, which may be associated with disruption of the structure and function.
Healing is the body’s response to injury in an attempt to restore normal structure and functions.
Healing can occur in two ways: Regeneration and Repair
There are 4 phases of wound healing: hemostasis, inflammation, proliferation, and remodeling. This document also describes the mechanism of wound healing. Factors that affect healing include infection, uncontrolled diabetes, poor nutrition, age, anemia, the presence of foreign bodies, etc.
Complications of wound healing like infection, hyperpigmentation of scar, contractures, and keloid formation.
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2. Introduction
The 2010 edition of Prekindergarten-Grade 8 Science Curriculum Standards is a resource that adds detail to the content and inquiry standards in the
2004 Core Science Curriculum Framework. It includes Grade-Level Concepts (GLCs), Grade-Level Expectations (GLEs) and Key Concept Words
that provide clear guidelines for developing curriculum and planning instructional activities.
GLCs describe what students should know in order to understand the broad idea expressed by each Framework content standard. They define the
conceptual boundaries of the learning unit, identifying subconcepts that should be included and those that can be excluded. GLCs are organized in a
suggested learning sequence that can be used as a unit pacing guide. Each GLC is typically the focus of one to three class sessions. The Key Concept
Words highlight the “science talk” that students and teachers should use fluently in oral and written discourse about their learning. Many of the
GLCs are assessed on the science portion of the Connecticut Mastery Test (CMT).
GLEs are examples of what students should be able to do to demonstrate their understanding of science concepts. They are measurable learner
outcomes that can provide evidence of learning that is richer than merely memorized facts or terminology. The GLEs reflect a range of performances
for all students, including outcomes such as describing, explaining, comparing, summarizing, evaluating and creating. Some scientific inquiry
expected performances have been integrated within GLEs as examples of how students use scientific inquiry, literacy and numeracy practices to
understand science content. Teachers have flexibility to modify, prioritize and enhance GLEs to reflect their curriculum and their students’ learning
needs. GLEs can be useful for establishing measurable unit outcomes, designing learning activities, developing common formative and summative
assessments, or for documenting and reporting student progress. While some of the GLE outcomes are assessed on the Science CMT, most are
intended as school-based assessment opportunities.
The Expected Performances in the 2004 science framework continue to be the basis for developing questions for the science CMT. However, these
Expected Performances represent only the selected content that could be assessed on this state test that covers multiple years of science learning.
Narrowing the curriculum to include only those concepts that are tested on the CMT is likely to limit students’ abilities to make sense of science and
retain what they learn. A coherent curriculum that aligns instruction with the content outlined in GLCs, GLEs and Key Concept Words will provide
students with opportunities to achieve the broader goals of scientific literacy and preparation for advanced study as well as high achievement on state
assessments.
Connecticut science educators, RESC science specialists and university scientists contributed to the development of the GLCs and GLEs. The
Leadership and Learning Center (formerly the Center for Performance Assessment) reviewed the curriculum standards and GLEs for science.
Recommendations were made and are reflected in this document. The following is a summary of the center’s comparative analysis of the Connecticut
Prekindergarten-Grade 8 Science Curriculum Standards:
“The [Connecticut Prekindergarten-Grade 8 Science Curriculum Standards] present the science content and inquiry abilities that
students need in order to be science literate. The Curriculum Standards are comparable to the National Science Education Standards
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 2
3. (National Research Council, 1996) and the Benchmarks for Science Literacy (AAAS, 1993), as well as to the science standards of two
states (South Carolina and California) whose standards have been identified by the Thomas B. Fordham Institute’s State of the State
Science Standards 2005 as being exemplary.”
Prekindergarten-Grade 8 Science Curriculum Standards is intended to raise interest and achievement in science in all Connecticut schools by
supporting local curriculum development, selection of instructional materials, design of content-rich professional development, and instructional
methods aligned with Connecticut’s 2004 Core Science Curriculum Framework.
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 3
4. Scientific knowledge is created and communicated through students’ use of the following skills. All of the
inquiry skills described below should be utilized by PK-2 students as they learn the content described by each
Content Standard on the pages that follow.
Grades PreK-2 Core Scientific Inquiry, Literacy and Numeracy
How is scientific knowledge created and communicated?
Expected Performances
A INQ.1 Make observations and ask questions about objects, organisms and the environment.
A INQ.2 Use senses and simple measuring tools to collect data.
A INQ.3 Make predictions based on observed patterns.
A INQ.4 Read, write, listen and speak about observations of the natural world.
A INQ.5 Seek information in books, magazines and pictures.
A INQ.6 Present information in words and drawings.
A INQ.7 Use standard tools to measure and describe physical properties such as weight, length and
temperature.
A INQ.8 Use nonstandard measures to estimate and compare the sizes of objects.
A INQ.9 Count, order and sort objects by their properties.
A INQ.10 Represent information in bar graphs.
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 4
5. Properties of Matter — How does the structure of matter affect the properties and uses of materials?
PREKINDERGARTEN
PK.1 - Objects have properties that can be observed and used to describe similarities and differences
Core Science Grade-Level Expectations Preschool
Curriculum Preschool Curriculum Framework Assessment
Framework Students should be able to: Framework
PK.1.a. Some
Cognitive Development: Logical- COG 1 Engages
properties can be 1. Use senses to make observations of objects and
Mathematical/Scientific Thinking - in scientific
observed with the materials within the child’s immediate environment.
inquiry
senses, and others can 1. Ask questions about and comment
be discovered by using on observations and 2. Use simple tools (e.g., balances and magnifiers) and COG 3 Sorts
simple tools or tests. experimentation; nonstandard measurement units to observe and compare objects
properties of objects and materials.
2. Collect, describe and record COG 5 Compares
information; 3. Make comments or express curiosity about observed and orders objects
3. Use equipment for investigation; phenomena (e.g., “I notice that…” or “I wonder if…”). and events
COG 6 Relates
4. Use common instruments to 4. Count, order and sort objects (e.g. blocks, crayons, number to quantity
measure things; toys) based on one visible property (e.g., color, shape,
5. Demonstrate understanding of one- size).
to-one correspondence while
counting; 5. Conduct simple tests to determine if objects roll, slide
or bounce.
6. Order several objects on the basis
of one attribute;
7. Sort objects by one or more
attributes and regroup the objects
based on a new attribute;
8. Engage in a scientific experiment
with a peer or with a small group.
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 5
6. Heredity and Evolution — What processes are responsible for life’s unity and diversity?
PREKINDERGARTEN
PK.2 — Many different kinds of living things inhabit the earth.
Core Science Grade-Level Expectations Preschool
Curriculum Preschool Curriculum Framework Assessment
Framework Students should be able to: Framework
PK.2.a. Living things Cognitive Development: Logical- 1. Use the senses and simple tools to make COG 1 Engages
have certain Mathematical/Scientific Thinking observations of characteristics and behaviors in scientific
characteristics that of living and nonliving things. inquiry
1. Ask questions about and comment on
distinguish them from observations and experimentation; 2. Give examples of living things and nonliving COG 3 Sorts
nonliving things, things. objects
including growth, 2. Collect, describe and record information;
movement, 3. Make observations and distinguish between COG 5 Compares
3. Sort objects by one or more attributes and
reproduction and the characteristics of plants and animals. and orders objects
regroup the objects based on a new attribute;
response to stimuli. and events
4. Compare attributes of self, family members or
4. Compare and contrast objects and events.
classmates, and describe how they are similar P&S9
Personal and Social Development and different. Recognizes
1. Identify themselves by family and gender. similarities and
appreciates
2. State at least two ways in which children are differences
similar and two ways in which they are
different.
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 6
7. Energy in the earth’s Systems — How do external and internal sources of energy affect the earth’s systems?
PREKINDERGARTEN
PK.3 — Weather conditions vary daily and seasonally.
Core Science Grade-Level Expectations Preschool
Curriculum Preschool Curriculum Framework Assessment
Framework Students should be able to: Framework
PK.3.a. Daily and Cognitive Development: Logical- 1. Use the senses to observe and describe COG 1 Engages
seasonal weather Mathematical/Scientific Thinking evidence of current or recent weather in scientific
conditions affect what conditions (e.g., flags blowing, frost on inquiry
1. Ask questions about and comment on
we do, what we wear window, puddles after rain, etc.)
observations and experimentation; PHY 3 Cares for
and how we feel. 2. Notice weather conditions and use words and self independently
2. Collect, describe and record information;
numbers to describe and analyze conditions
3. Demonstrate an understanding of sequence over time (e.g., “it rained 5 times this month”.)
of events and time periods;
3. Identify the season that corresponds with
4. Make and verify predictions about what observable conditions (e.g., falling leaves,
will occur. snow vs. rain, buds on trees or greener grass).
Personal and Social Development 4. Make judgments about appropriate clothing
1. Use self-help skills and activities based on weather conditions.
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 7
8. Science and Technology in Society — How do science and technology affect the quality of our lives?
PREKINDERGARTEN
PK.4 — Some objects are natural, while others have been designed and made by people to improve the quality of life.
Core Science Grade-Level Expectations Preschool
Curriculum Preschool Curriculum Framework Assessment
Framework Students should be able to: Framework
PK.4.a. Humans select Cognitive Development: Logical- 1. Observe, describe and sort building materials by P & S 1 Shows
materials with which Mathematical/Scientific Thinking properties such as strength, weight, stiffness or self-direction with
to build structures flexibility. a range of
1. Ask questions about and comment on
based on the properties materials
observations and experimentation; 2. Pose questions and conduct simple tests to
of the materials. compare the effectiveness of different building COG 1 Engages
2. Sort objects by one or more attributes and
materials (e.g., blocks of wood, plastic, foam or in scientific
regroup the objects based on a new attribute;
cardboard) for constructing towers, bridges and inquiry
3. Make and verify predictions about what will buildings. COG 2 Uses a
occur;
3. Make judgments about the best building variety of
4. Engage in a scientific experiment with a materials to use for different purposes (e.g., strategies to solve
peer or with a small group; making the tallest tower or the longest bridge). problems
Personal and Social Development 4. Invent and explain techniques for stabilizing a COG 3 Sorts
1. Demonstrate the ability to use a minimum of structure. objects
two different strategies to attempt to solve a 5. Compare block structures to pictures and to real COG 7
problem; structures in the neighborhood. Demonstrates
Creative Expression/Aesthetic Development spatial awareness
1. Use a variety of art materials and activities CRE 1 Builds
for sensory experience and exploration. and constructs to
represent own
ideas
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 8
9. Properties of Matter — How does the structure of matter affect the properties and uses of materials?
KINDERGARTEN
K.1 - Objects have properties that can be observed and used to describe similarities and differences
Core Science Grade-Level Expectations
Grade-Level Concepts
Curriculum Assessment
Framework Students should understand that ... Students should be able to…
K.1.a. Some 1. Humans have five senses that they use to observe their environment. A 1. Match each of the five senses A1. Use the
properties can specific sense organ is associated with each sense. with its associated body part senses and
be observed and the kind of information it simple
2. Objects have properties that can be observed using the senses. Examples
with the perceives. measuring
include size, weight, shape, color, texture, transparency, etc. An object’s
senses, and observable properties do not include the object’s name or its uses. 2. Make scientific observations tools, such as
others can be rulers and
using the senses, and
discovered by 3. Sorting objects into groups based on one (or more) of their properties equal-arm
distinguish between an
using simple makes it possible to observe and describe their similarities and
object’s observable properties balances, to
tools or tests. differences. observe
and its name or its uses.
4. Placing objects in order based on their size or weight makes it possible to common
3. Classify organisms or objects objects and
observe patterns and describe relationships among the objects in a group.
by one and two observable sort them into
5. Objects can be described and sorted based on the materials from which properties and explain the groups based
they are made (for example, wood, paper, fabric, plastic, glass or metal). rule used for sorting (e.g., on size,
Objects can be made of a mixture of materials. size, color, shape, texture or weight, shape
6. Objects can be described and sorted based on the results of simple tests. flexibility). or color.
Simple tests include actions such as bending, squeezing, holding it near a 4. Use simple tools and
magnet or putting it in water. Objects can be described as nonstandard units to estimate
magnetic/nonmagnetic, flexible/not flexible, hard/soft, a floater/sinker, A2. Sort
or predict properties such as
etc. objects made
size, heaviness, magnetic
of materials
7. The heaviness of objects can be compared using the sense of touch. attraction and float/sink.
such as wood,
Balances and scales are measurement tools that allow people to observe 5. Describe properties of paper and
and compare the heaviness of objects more accurately. materials such as wood, metal into
8. The temperature of the air, water or bodies can be compared using the plastic, metal, cloth or paper, groups based
sense of touch. A thermometer is a measurement tool that allows people and sort objects by the material on properties
to compare temperatures more accurately. from which they are made. such as
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 9
10. 6. Count, order and sort objects flexibility,
9. Objects can be sorted into groups based on measurements of their size.
by their observable attraction to
Nonstandard units for measuring size include hands, footsteps, pennies or
properties. magnets, and
paper clips.
whether they
float or sink in
KEY CONCEPT WORDS: senses, observe, observation, property, sort, water.
classify, material, float, sink, flexible, heavy, magnetic, nonmagnetic,
thermometer A3. Count
objects in a
group and use
mathematical
terms to
describe
quantitative
relationships
such as: same
as, more than,
less than,
equal, etc.
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 10
11. Heredity and Evolution — What processes are responsible for life’s unity and diversity?
KINDERGARTEN
K.2 — Many different kinds of living things inhabit the earth.
Core Science Grade-Level Concepts Grade-Level Expectations
Curriculum Assessment
Framework Students should understand that… Students should be able to…
K.2.a. Living 1. Things in our environment can be classified based on whether they are 1. Observe and describe A4. Describe
things have alive, were once alive or whether they were never alive. differences between living the similarities
certain and nonliving things in terms and differences
2. Growing, responding to stimuli, and breathing are characteristics of
characteristics of growth, offspring and need in the
many living things. Many living things move, but movement alone is
that distinguish for energy from “food.” appearance and
not evidence of life. For example, cars and the wind both move, but
them from behaviors of
they are not alive. 2. Sort, count, and classify
nonliving plants, birds,
living and nonliving things in
things, 3. Reproduction is a characteristic of living things. Living things can be fish, insects and
the classroom, the schoolyard
including classified into groups based on the different ways they reproduce. For mammals
and in pictures.
growth, example, some living things lay eggs, while others produce seeds or give (including
movement, birth. 3. Use nonstandard measures to humans).
reproduction estimate and compare the
4. Living things can be classified as plants or animals. Plants have
and response to height, length or weight of A.5 Describe
characteristics (such as roots, stems, leaves and flowers) that animals do
stimuli. different kinds of plants and the similarities
not have. Animals have characteristics (such as body parts and body
animals. and differences
coverings) that plants do not have.
4. Observe and write, speak or in the
5. Animals can be classified into groups based on generally similar appearance and
draw about similarities and
characteristics such as number of legs, type of body covering, or way of behaviors of
differences between plants
moving. Some animal groups are reptiles, insects, birds, fish and adults and their
and animals.
mammals. offspring.
5. Match pictures or models of
6. Offspring generally resemble their parents but are not identical to them.
adults with their offspring A6. Describe
7. Members of the same group of animals can look and act very differently (animals and plants). characteristics
from each other. For example, goldfish and sharks are both fish, but that distinguish
6. Classify varied individuals of
there are distinct differences in their size, color and lifestyle. In living from
the same species by one and
addition, all goldfish are not identical to each other and neither are all nonliving
two attributes (e.g., rabbits or
sharks. things.
cats with different fur colors;
8. Plants can be classified into groups based on similarities in the rabbits or dogs with upright
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 11
12. appearance of their leaves, stems, blossoms or fruits. Some plant groups or floppy ears, etc.).
are grasses, vegetables, flowering plants and trees.
9. Members of the same group of plants can look and act very differently
from each other. For example, although oaks and palms are both trees,
their size, shape, leaves and growth habits are very different. In
addition, all oak trees are not identical to each other and neither are all
palms.
KEY CONCEPT WORDS: classify, reproduce, offspring, characteristics,
reptile, insect, mammal
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 12
13. Energy in the earth's systems — How do external and internal sources of energy affect the earth's systems?
KINDERGARTEN
K.3 — Weather conditions vary daily and seasonally.
Core Science Grade-Level Expectations
Grade-Level Concepts
Curriculum Assessment
Framework Students should understand that… Students should be able to…
K.3.a. Daily 1. The sun is the source of heat and light that warms the land, air and water. 1. Use the senses to observe A7. Describe
and seasonal Variations in the amount of sunlight that reaches the earth cause the daily weather conditions and and record
weather weather. record data systematically daily weather
conditions using organizers such as conditions.
2. Weather conditions can be observed and described as sunny, cloudy,
affect what we tables, charts, picture graphs
rainy, foggy, snowy, stormy, windy, hot or cold. Weather observations A8. Relate
do, what we or calendars.
can be made based on how we feel, what we see or hear, or by using seasonal
wear and how weather measurement instruments such as thermometers. 2. Analyze weather data weather
we feel. collected over time (during patterns to
3. Changes in weather conditions can be recorded during different times of
the day, from day to day, and appropriate
day, from day to day, and over longer periods of time (seasonal cycle).
from season to season) to choices of
Repeated observations can show patterns that can be used to predict
identify patterns and make clothing and
general weather conditions. For example, temperatures are generally
comparisons and predictions. activities.
cooler at night than during the day and colder in winter than in spring,
summer or fall. 3. Observe, compare and
contrast cloud shapes, sizes
4. Weather influences how we dress, how we feel, and what we do
and colors, and relate the
outside.
appearance of clouds to fair
5. Weather affects the land, animals and plants, and bodies of water. weather or precipitation.
6. When the temperature is below “freezing,” water outside freezes to ice 4. Write, speak or draw ways
and precipitation falls as snow or ice; when the temperature is above that weather influences
freezing, ice and snow melt and precipitation falls as rain. humans, other animals and
7. Clouds and fog are made of tiny drops of water. Clouds have different plants.
shapes, sizes and colors that can be observed and compared. Some 5. Make judgments about
cloud types are associated with precipitation and some with fair appropriate clothing and
weather. activities based on weather
8. Wind is moving air. Sometimes air moves fast and sometimes it hardly conditions.
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 13
14. moves at all. Wind speed can be estimated by observing the things that
it moves, such as flags, tree branches or sailboats.
KEY CONCEPT WORDS: weather, season (winter, spring, summer,
fall), thermometer, precipitation, freeze, melt
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 14
15. Science and Technology in Society — How do science and technology affect the quality of our lives?
KINDERGARTEN
K.4 — Some objects are natural, while others have been designed and made by people to improve the quality of life.
This content standard is an application of the concepts in content standard K.1 and should be integrated into the same learning unit.
Core Science Grade-Level Expectations
Grade-Level Concepts
Curriculum Assessment
Framework Students should understand that… Students should be able to…
K.4.a. Humans 1. People need shelters to keep warm or cool, dry and safe. Shelters are 1. Conduct simple tests to A9. Describe
select both made of materials whose properties make them useful for different compare the properties of the types of
natural and purposes. different materials and their materials used
man-made 2. People in different regions of the world build different kinds of shelters, usefulness for making roofs, by people to
materials to depending on the materials available to them, the local climate and their windows, walls or floors (e.g., build houses
build shelters customs. waterproof, transparent, and the
based on local 3. Traditionally, people have built shelters using materials that they find strong). properties that
climate nearby. Today, people build houses from materials that may come from make the
2. Seek information in books,
conditions, far away. materials
magazines and pictures that
properties of useful.
a. People who live in forested regions have traditionally built shelters describes materials used to
the materials,
using wood and/or leaves from nearby trees. build shelters by people in
and their different regions of the world.
availability in b. People who live in regions with clay soils have traditionally built
the shelters using bricks or adobe made from clay. 3. Compare and contrast the
environment. materials used by humans and
c. People who live in snowy regions have traditionally built shelters animals to build shelters.
using snow and ice.
d. People who live in regions with large animals have traditionally
built shelters using animal skins.
4. Although they may look quite different, most shelters have walls, roofs
and an entrance/exit; some shelters have doors, windows and floors.
Walls, roofs and windows are made of materials that have specific
properties. For example, walls require materials that are rigid, windows
require materials that are transparent, and roofs require materials that are
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 15
16. water-resistant.
5. Animals build shelters using materials that are easily available to them.
The materials they use have properties that help the animals stay warm
or cool, dry and safe.
KEY CONCEPT WORDS: shelter, rigid, transparent
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 16
17. Forces and Motion — What makes objects move the way they do?
GRADE 1
1.1 — The sun appears to move across the sky in the same way every day, but its path changes gradually over the seasons.
Core Science Grade-Level Concepts Grade-Level Expectations
Curriculum Assessment
Framework Students should understand that… Students should be able to…
1.1.a. An GRADE-LEVEL CONCEPT 1.1.a. 1. Compare and contrast the A10. Describe
object’s relative positions of objects how the motion
position can be 1. An object’s relative position can be described by comparing it to the using words (in front of, of objects can
described by position of another stationary object. One object can be in front of, behind, next to, inside of, be changed by
locating it behind, next to, inside of, above or below another object. above or below) and numbers pushing and
relative to 2. The sun’s position in the daytime sky can be described relative to (by measuring its distance pulling.
another object stationary objects on Earth. For example, the sun can be “just above the from another object).
or the treetops,” “high or low in the sky,” or “on the other side of the school.” 2. Apply direct and indirect
background. A11. Describe
3. The description of an object’s position from one observer’s point of pushes and pulls to cause the apparent
view may be different from that reported from a different observer’s objects to move (change movement of
viewpoint. For example, a box of crayons between two students is near position) in different ways
1.1.b. An the sun across
object’s motion Susan’s left hand but near John’s right hand. (e.g., straight line, forward and the sky and the
backward, zigzag, in a circle).
can be 4. When an observer changes position, different words may be needed to changes in the
described by describe an object’s position. For example, when I am sitting on the 3. Classify objects by the way length and
tracing and bench the sun is “behind” me; when I move to the slide, the sun is “in they move (e.g., spinning, direction of
measuring its front of” me. rolling, bouncing). shadows during
position over the day.
5. The same object when viewed from close up appears larger than it does 4. Conduct simple experiments
time.
when viewed from far away (although the actual size of the object does and evaluate different ways to
not change.) For example, a beach ball held in one’s arms appears change the speed and direction
larger than it does when viewed from across the playground. of an object’s motion.
6. An object’s position can be described using words (“near the door”), 5. Observe, record and predict
numbers (10 centimeters away from the door) or labeled diagrams. the sun’s position at different
times of day (morning, noon,
GRADE-LEVEL CONCEPT 1.1.b. afternoon or night).
1. Things move in many ways, such as spinning, rolling, sliding, bouncing, 6. Conduct simple investigations
flying or sailing.
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 17
18. of shadows and analyze how
2. Motion can be caused by a push or a pull. A push or pull is called a
shadows change as the relative
force. Pushes and pulls can start motion, stop motion, speed it up, slow
position of the sun (or an
it down or change its direction.
artificial light source) changes.
3. An object is in motion when its position is changing. Because the sun’s
position changes relative to objects on Earth throughout the day, it
appears to be moving across the sky.
4. Changes in the sun’s position throughout the day can be measured by
observing changes in shadows outdoors.
5. Shadows occur when light is blocked by an object. An object’s shadow
appears opposite the light source. Shadow lengths depend on the
position of the light source.
KEY CONCEPT WORDS: position, motion, shadow, push, pull, force
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 18
19. Structure and Function — How are organisms structured to ensure efficiency and survival?
GRADE 1
1.2 — Living things have different structures and behaviors that allow them to meet their basic needs.
Core Science Grade-Level Expectations
Grade-Level Concepts
Curriculum Assessment
Framework Students should understand that… Students should be able to…
1.2.a. Animals GRADE-LEVEL CONCEPT 1.2.a. 1. Infer from direct observation A12. Describe
need air, water and print or electronic the different
and food to 1. All living things (organisms) need air, water and food to stay alive and information that most ways that
survive. grow; they meet these needs in different ways. animals and plants need animals,
2. Most animals move from place to place to find food and water. Some water, food and air to stay including
animals have two legs, four legs, six legs or more for moving. Other alive. humans,
1.2.b. Plants animals move using fins, wings or by slithering. obtain water
2. Identify structures and
need air, water
3. Animals get air in different ways. For example, humans breathe with behaviors used by mammals, and food.
and sunlight to
lungs, while fish breathe with gills. birds, amphibians, reptiles,
survive.
fish and insects to move
4. Animals get food in different ways. Some animals eat parts of plants A13. Describe
around, breathe and obtain
and others catch and eat other animals. the different
food and water (e.g., structures
5. Animals get water in different ways. Some animals have special body legs/wings/fins, gills/lungs, plants have for
parts, such as noses, tongues or beaks that help them get water. claws/fingers, etc.) obtaining
6. Fictional animals and plants can have structures and behaviors that are 3. Sort and classify plants (or water and
different than real animals and plants. plant parts) by observable sunlight.
characteristics (e.g., leaf
GRADE-LEVEL CONCEPT 1.2.b. shape/size, stem or trunk
1. Plants absorb sunlight and air through their leaves and water through covering, flower or fruit). A14. Describe
their roots. the structures
4. Use senses and simple that animals,
2. Plants use sunlight to make food from the air and water they absorb. measuring tools to measure including
the effects of water and humans, use to
3. Plants have various leaf shapes and sizes that help them absorb sunlight
sunlight on plant growth.
and air. move around.
5. Compare and contrast
4. Plant roots grow toward a source of water.
information about animals
5. Plant stems grow toward sunlight. and plants found in fiction
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 19
20. and nonfiction sources.
KEY CONCEPT WORDS: organism, plant, animal, energy, breathe, lungs,
gills, absorb
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 20
21. Structure and Function — How are organisms structured to ensure efficiency and survival?
GRADE 1
1.3 — Organisms change in form and behavior as part of their life cycles.
Core Science
Grade-Level Concepts Grade-Level Expectations
Curriculum Assessment
Framework Students should understand that… Students should be able to…
1.3.a. Some 1. Plants and animals have life cycles that include a predictable 1. Explain that living things A15. Describe
organisms sequence of stages: they begin life, develop into adults, reproduce experience a life cycle that the changes in
undergo and eventually die. includes birth, growth, organisms,
metamorphosis reproduction and death. such as frogs
2. Plants and animals produce offspring of their own kind. Offspring
during their life and butterflies,
closely resemble their parents, but individuals vary in appearance 2. Distinguish between animals
cycles; other as they undergo
and behavior. that are born alive (e.g.,
organisms metamorphosis.
humans, dogs, cows) and
grow and 3. Animals are either born alive (for example, humans, dogs and cows)
those that hatch from eggs
change, but or hatched from eggs (for example, chickens, sea turtles or
(e.g., chickens, sea turtles,
their basic crocodiles). A16. Describe
crocodiles).
form stays the life cycles
4. Animals change during their life cycle. Many animals begin life as
essentially the 3. Compare and contrast the of organisms
smaller, less capable forms of the adult. As they develop, they grow
same. changes in structure and that grow but
larger and become more independent (for example, humans, dogs or
behavior that occur during the do not
robins).
life cycles of animals that metamorphose.
5. Some animals change dramatically in structure and function during undergo metamorphosis with
their life cycle in a process called metamorphosis. those that do not.
6. Frogs are amphibians that undergo metamorphosis during their life 4. Analyze recorded
cycle. As they grow, frogs develop different structures that help observations to compare the
them meet their basic needs in water and then on land: metamorphosis stages of
a. Tadpoles hatch from eggs, live in water, breathe using gills, different animals and make
and swim using a tail. As they metamorphose into frogs, predictions based on observed
tadpoles lose their gills and their tails. patterns.
b. Adult frogs live on land and in water. They breathe air using
lungs and develop webbed feet and hinged legs for
swimming in water and hopping on land. After a female frog
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 21
22. mates, she lays her eggs, and the cycle begins again.
7. Butterflies are insects that undergo metamorphosis during their life
cycle. As they go through egg, larva, pupa and adult stages,
butterflies develop different structures that help them meet their
basic needs on land and in the air:
a. Caterpillars hatch from eggs, live on plants, get food by
chewing leaves and move about using legs. As they
metamorphose into butterflies inside a chrysalis, they
develop wings, antennae and different mouth parts.
b. Butterflies live on land and in the air. They get food by
sucking nectar from flowers and move around primarily
using wings to fly. After a female butterfly mates, she
searches for the proper host plant to lay her eggs, and the
cycle begins again.
8. Comparing the life cycle stages of different organisms shows how
they are alike in some ways and unique in other ways.
KEY CONCEPT WORDS: life cycle, egg, metamorphosis, structures
(body parts), amphibian, tadpole, gills, lungs, insect, caterpillar
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 22
23. Science and Technology in Society — How do science and technology affect the quality of our lives?
GRADE 1
1.4 — The properties of materials and organisms can be described more accurately through the use of standard measuring units.
This content standard should be integrated within all PK–5 standards.
Core Science Grade-Level Expectations
Grade-Level Concepts
Curriculum Assessment
Framework Students should understand that… Students should be able to…
1.4.a. Various 1. Observations can be expressed in words, pictures or numbers. 1. Use nonstandard and standard A17. Estimate,
tools can be Measurements add accuracy to observations. measurements to describe and measure and
used to compare the weight, length, and compare the
2. Objects and organisms can be described using nonstandard measurement
measure, size of objects and organisms. sizes and
units, such as hand-lengths, pencil-lengths, handfuls, etc.
describe and weights of
2. Show approximate size of a
compare 3. Standard measurement units are more accurate than nonstandard units different
centimeter, meter, inch, foot
different because they have consistent values agreed on by everyone. For objects and
and yard using referents such
objects and example, “My caterpillar is one finger long” is much less accurate than organisms
as a finger, a hand or a book.
organisms. “My caterpillar is 4 centimeters long.” using standard
3. Select appropriate tools for and
4. Scientists and nonscientists all over the world use the metric system of
measuring length, height, nonstandard
measurement. In the United States, the customary measurement system
weight or liquid volume. measuring
is used in daily life. Equivalent values between the two systems can be
estimated (for example, 1 inch is a little more than 2 centimeters). 4. Use metric and customary tools.
rulers to measure length,
5. Specific tools are used to measure different quantities:
height or distance in
a. Metric rulers are used to measure length, height or distance in centimeters, meters, inches,
centimeters and meters; customary rulers measure length, height or feet and yards.
distance in inches, feet or yards.
5. Use balances and scales to
b. Balances and scales are used to compare and measure the heaviness of compare and measure the
objects. Grams and kilograms are units that express mass; ounces and heaviness of objects and
pounds are units that express weight. organisms in kilograms,
c. Graduated cylinders, beakers and measuring cups are tools used to grams, pounds and ounces.
measure the volume of liquids. Volume can be expressed in 6. Use graduated cylinders,
milliliters (mL), liters (L), cups or ounces. beakers and measuring cups
d. Thermometers are tools used to measure temperature; thermometers to measure the volume of
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 23
24. can indicate temperature in degrees Celsius or degrees Fahrenheit, or liquids in milliliters, liters,
both. cups and ounces.
KEY CONCEPT WORDS: centimeter, meter, gram, kilogram, milliliter, 7. Use thermometers to measure
liter, graduated cylinder, thermometer, Celsius, Fahrenheit air and water temperature in
degrees Celsius and degrees
Fahrenheit.
8. Make graphs to identify
patterns in recorded
measurements such as growth
or temperature over time.
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 24
25. Properties of Matter — How does the structure of matter affect the properties and uses of materials?
GRADE 2
2.1 — Materials can be classified as solid, liquid or gas based on their observable properties.
Core Science Grade-Level Expectations
Grade-Level Concepts
Curriculum Assessment
Framework Students should understand that… Students should be able to…
2.1.a. Solids 1. Materials can be classified as solid, liquid or gas. All forms of matter 1. Compare and contrast the A18. Describe
tend to maintain have weight and take up space, but each form has unique properties. properties that distinguish differences in the
their own solids, liquids and gases. physical
2. Solids are the only form of matter that have a definite shape. A solid’s
shapes, while properties of
shape can be changed by hammering, twisting or stretching, but its weight 2. Classify objects and
liquids tend to solids and
remains the same. Solids can be hard, soft, bouncy, stretchy or grainy. materials according to
assume the liquids.
their state of matter.
shapes of their 3. Solids take up a definite amount of space (volume); the volume does
containers, and not change if the solid is placed in different containers. 3. Measure and compare the
gases fill their sizes of different solids.
4. Liquids do not have a definite shape; they flow to the bottom of a
containers fully. container and take on the shape of the part of the container they 4. Measure and compare the
occupy. Liquids pour and flow from a higher point to a lower point; volume of a liquid poured
some liquids flow faster than others. into different containers.
5. Liquids have a definite volume. When a liquid is poured into different 5. Design a fair test to
containers, the shape of the liquid may change, but the volume does not. compare the flow rates of
different liquids and
6. Gases are made of particles too small to see, but they still take up
granular solids.
space and have weight. Gases do not have a definite shape; they take
on the shape of whatever container they occupy. For example, the air
in an inflated balloon can be squeezed and reshaped.
7. Gases do not have a definite volume; they spread out in all directions
to fill any size container, or they keep spreading in all directions if
there is no container. For example, blowing even a small amount of
air into a balloon immediately fills the entire balloon; the smell of
baking bread eventually fills the entire house and even outside.
KEY CONCEPT WORDS: property, classify, matter, state of matter, solid,
liquid, gas, volume
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 25
26. Structure and Function — How are organisms structured to ensure efficiency and survival?
GRADE 2
2.2 — Plants change their forms as part of their life cycles.
Core Science Grade-Level Expectations
Grade-Level Concepts
Curriculum Assessment
Framework Students should understand that… Students should be able to…
2.2.a. The life 1. Flowering plants progress through a sequenced life cycle. First, 1. Use senses and simple tools A19. Describe the
cycles of seeds sprout (germinate), then seedlings grow into adult plants to observe and describe the life cycles of
flowering plants with leaves and flowers. If the flowers are pollinated, seeds roots, stems, leaves, flowers flowering plants as
include seed develop that will grow into new plants to continue the life cycle. and seeds of various plants they grow from
germination, (including trees, vegetables seeds, proceed
2. Roots, stems, leaves, flowers and seeds are structures that develop
growth, and grass.) through maturation
during different stages of the plant’s life cycle.
flowering, and produce new
2. Use magnifiers to observe
pollination and 3. Seeds contain the beginnings of a new plant (embryo) and the food seeds.
and diagram the parts of a
seed dispersal. (energy source) the new plant needs to grow until it is mature
flower.
enough to produce its own food. Different plant varieties produce
seeds of different size, color and shape. 3. Describe the functions of A20. Explore and
roots, stems, leaves, flowers describe the effects
4. Environmental conditions, such as temperature, amount of light,
and seeds in completing a of light and water
amount of water and type of soil, affect seed germination and plant
plant’s life cycle. on seed germination
development.
and plant growth.
4. Record observations and
5. A plant’s seed will grow into a new plant that resembles but is not
make conclusions about the
identical to the parent plant or to other new plants. For example,
sequence of stages in a
marigold plants produce marigold seeds that grow into new
flowering plant’s life cycle.
marigold plants. Individual marigolds, however, vary in height,
number of leaves, etc. 5. Compare and contrast how
seeds of different plants are
6. Seedlings are young plants that produce the structures that will be
adapted for dispersal by
needed by the plant to survive in its environment: Roots and leaves
water, wind or animals.
begin to grow and take in nutrients, water and air; and the stem
starts to grow towards sunlight. 6. Conduct a fair test to
explore factors that affect
7. Adult plants form more leaves that help the plant collect sunlight
seed germination and plant
and air to make its food. They produce flowers that are the
growth.
structures responsible for reproduction.
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 26
27. 8. Flowers have structures that produce pollen, attract pollinators and
produce seeds that can grow into new plants. Some flowers have
structures that develop into fruits, berries or nuts that contain the
seeds that can grow into new plants.
9. Some seeds fall to the ground and germinate close to the parent plant;
other seeds are carried (dispersed) by wind, animals, or water to places
far away. The structure of the seed is related to the way it is
dispersed.
KEY CONCEPT WORDS: life cycle, structures (body parts), seed,
germinate, reproduce, flower, pollen, pollinator, seed dispersal
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 27
28. The Changing Earth — How do materials cycle through the earth's systems?
GRADE 2
2.3 — Earth materials have varied physical properties that make them useful in different ways.
Core
Science Grade-Level Concepts Grade-Level Expectations
Assessment
Curriculum Students should understand that… Students should be able to…
Framework
2.3.a. Soils GRADE-LEVEL CONCEPT 2.3.a. 1. Use senses and simple tools A21. Sort
can be (e.g., sieves and settlement different soils
described by 1. Soil is a mixture of pieces of rock (particles), living and once living things tests) to separate soil into by properties,
their color, (humus), water and air. The components of soil can be separated using components such as rock such as particle
sieves and settlement tests.
texture and fragments, water, air and plant size, color and
capacity to 2. There are different types of soil that vary from place to place. Soil remains. composition.
retain water. properties can be observed and compared. Soils can be classified by
2. Classify soils by properties
properties such as color, particle size, or amount of organic material
such as color, particle size
(humus). Digging a deep hole shows that soils are often found in layers A22. Relate the
(sand, silt or clay), or amount
2.3.b. Soils that have different colors and textures. properties of
of organic material (loam).
support the different soils
3. The size of the particles in soils gives the soil its texture. Soils can be
growth of 3. Explain the importance of soil to their
classified by how they feel: Sandy soils feel gritty, silty soils feel
many kinds to plants, animals and people. capacity to
powdery, clay soils feel sticky, and soils with small rocks feel rough and
of plants, retain water
scratchy. 4. Evaluate the quality of
including and support the
different soils in terms of
those in our 4. The broken rocks that make up soils can be tiny (silt and clay), medium growth of
observable presence of air,
food supply. (sand), or large (pebbles). Soils can be classified by the size of their certain plants.
water, living things and plant
particles.
remains.
5. A soil’s texture affects how it packs together; soils that pack together
5. Conduct fair tests to
tightly hold less air and water than soils that stay loosely packed.
investigate how different soil
6. There are different types of soil that vary from place to place. Some soil types affect plant growth and
types are suited for supporting the weight of buildings and highways; write conclusions supported
other soil types are suited for planting food crops or forest growth. by evidence.
GRADE-LEVEL CONCEPT 2.3.b.
1. Many plants need soil to grow. Soil holds water and nutrients that are
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 28
29. taken in (absorbed) by plant roots.
2. Soil is a habitat for many living things. Some organisms live in the soil
and others live on the soil. Worms and other underground animals create
spaces for air, water and plant roots to move through soil.
3. Plants we eat (“crops”) grow in different soil types. Plant height, root
length, number of leaves, and number of flowers can all be affected by
how much water, air and organic material the soil holds.
4. To support the growth of different plants, people can change the
properties of soils by adding nutrients (fertilizing), water (irrigating) or
air (tilling).
KEY CONCEPT WORDS: soil, property, classify, mixture, particle, humus,
sand, silt, clay, texture, nutrients
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 29
30. Science and Technology in Society — How do science and technology affect the quality of our lives?
GRADE 2
2.4 — Human beings, like all other living things, have special nutritional needs for survival.
This content standard is an application of the concepts in content standard 2.3 and should be integrated into the same learning unit.
Core Science Grade-Level Expectations
Grade-Level Concepts
Curriculum Assessment
Framework Students should understand that… Students should be able to…
2.4.a. The GRADE-LEVEL CONCEPT 2.4.a. 1. Explain that food is a source A23. Identify
essential of carbohydrates, protein and the sources of
components of 1. People need to eat a variety of foods to get the energy and nutrients they fats —nutrients that animals common foods
balanced need to grow, move and stay healthy. Foods are classified as grains, (including humans) convert to and classify
nutrition can be fruits, vegetables, dairy, meats and beans, and oils. energy they use to stay alive them by their
obtained from 2. Some foods people eat come from plants that grow wild or are planted and grow. basic food
plant and by farmers as crops. A fruit is the ripened ovary of a flower; vegetables groups.
2. Classify foods into groups
animal sources. are the roots, stems, leaves or flowers of plants. based on their source, and
3. Some foods people eat come from animals that are wild or are raised on relate common foods to the A24. Describe
ranches. Meat, fish, dairy products and eggs all come from animals. plant or animal from which
2.4.b. People how people in
they come.
eat different 4. The types of crops that can grow in an area depend on the climate and different
foods in order soil. Some foods are grown and sold by local farms, and some foods are 3. Give examples of ways people cultures use
to satisfy grown far away and transported to local grocery stores. can improve soil quality and different food
nutritional crop growth (e.g., irrigation, sources to meet
needs for GRADE-LEVEL CONCEPT 2.4.b. fertilizer, pest control). their nutritional
carbohydrates, 1. All people need the same basic nutrients to grow, move and stay healthy; needs.
4. Compare and contrast how
proteins and different cultures satisfy these needs by consuming different foods. different cultures meet needs
fats.
2. The level of energy and nutrients individuals need depends on their age, for basic nutrients by
gender and how active they are. consuming various foods.
3. Most foods contain a combination of nutrients. Labels on food packages 5. Evaluate the nutritional value
describe the nutrients contained in the food and how much energy the of different foods by analyzing
food provides (calories). package labels.
4. Breads, cereals, rice and pasta are sources of carbohydrates, which
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 30
31. provide energy.
5. Meat, poultry, fish, beans, eggs and nuts are sources of protein, which
keeps the body working properly.
6. Fruits and vegetables are sources of vitamins and minerals, which keep
the body healthy.
7. Nuts, meats and fish are sources of fats and oils, which provide energy.
KEY CONCEPT WORDS: nutrient, crop, grain, carbohydrate, protein,
dairy, fats, oils, energy
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 31
32. Scientific knowledge is created and communicated through students’ use of the following skills. All of the
inquiry skills described below should be utilized by Grade 3-5 students as they learn the content described by
each Content Standard on the pages that follow.
Grades 3-5 Core Scientific Inquiry, Literacy and Numeracy
How is scientific knowledge created and communicated?
Expected Performances
B INQ.1 Make observations and ask questions about objects, organisms and the environment.
B INQ.2 Seek relevant information in books, magazines and electronic media.
B INQ.3 Design and conduct simple investigations.
B INQ.4 Employ simple equipment and measuring tools to gather data and extend the senses.
B INQ.5 Use data to construct reasonable explanations.
B INQ.6 Analyze, critique and communicate investigations using words, graphs and drawings.
B INQ.7 Read and write a variety of science-related fiction and nonfiction texts.
B INQ.8 Search the Web and locate relevant science information.
B INQ.9 Use measurement tools and standard units (e.g., centimeters, meters, grams, kilograms) to describe
objects and materials.
B INQ.10 Use mathematics to analyze, interpret and present data.
Connecticut State Department of Education 2010 — Bureau of Teaching and Learning 32