(former CERN Teacher-in-Residence)

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Presentation transcript:

(former CERN Teacher-in-Residence) ANTIMATTER ANTIMATTER TEACHING MODULE Terrence Baine University of Oslo (former CERN Teacher-in-Residence) HST 2010, CERN Friday 9 July 2010

Teaching Modules in Particle Physics

Teaching Modules in Particle Physics Aim:

Teaching Modules in Particle Physics Aim: To make modern physics (in particular, particle physics) interesting and exciting to students

Teaching Modules in Particle Physics Aim: To make modern physics (in particular, particle physics) interesting and exciting to students AND… do so at earlier stages in their science curriculum.

We are designing Teaching Modules that…

We are designing Teaching Modules that… Target students aged 14-15 years

…and that use topics that are related to the experiments being done at CERN.

Why create such a resource?

Why create such a resource? Let’s take a look at some statistics…

Eurobarometer Special Survey (2005): (Europeans’ general attitudes towards science and technology)

Eurobarometer Special Survey (2005): (Europeans’ general attitudes towards science and technology) In a short quiz on the level of scientific knowledge in the general public, Source: http://ec.europa.eu/public_opinion/archives/ebs/ebs_224_report_en.pdf

of 13 true-or-false questions asked, Eurobarometer Special Survey (2005): (Europeans’ general attitudes towards science and technology) In a short quiz on the level of scientific knowledge in the general public, of 13 true-or-false questions asked, Source: http://ec.europa.eu/public_opinion/archives/ebs/ebs_224_report_en.pdf

Eurobarometer Special Survey (2005): (Europeans’ general attitudes towards science and technology) In a short quiz on the level of scientific knowledge in the general public, of 13 true-or-false questions asked, those related to modern physics were among the most poorly answered. Source: http://ec.europa.eu/public_opinion/archives/ebs/ebs_224_report_en.pdf

Some questions from the Eurobarometer Survey :

“Lasers work by focusing sound waves” Some questions from the Eurobarometer Survey : “Lasers work by focusing sound waves”

“Lasers work by focusing sound waves” Some questions from the Eurobarometer Survey : “Lasers work by focusing sound waves” Answered “true” 26%

“Lasers work by focusing sound waves” Some questions from the Eurobarometer Survey : “Lasers work by focusing sound waves” Answered “true” 26% “Didn’t know” 28%

Some questions from the Eurobarometer Survey : “Lasers work by focusing sound waves” Answered “true” 26% “Didn’t know” 28% “Electrons are smaller than atoms”

Some questions from the Eurobarometer Survey : “Lasers work by focusing sound waves” Answered “true” 26% “Didn’t know” 28% “Electrons are smaller than atoms” Answered “false” 29%

Some questions from the Eurobarometer Survey : “Lasers work by focusing sound waves” Answered “true” 26% “Didn’t know” 28% “Electrons are smaller than atoms” Answered “false” 29% “Didn’t know” 25%

Modern physics content in LOWER secondary school curricula:

Modern physics content in LOWER secondary school curricula: Norwegian National Curriculum in Natural Science (2006) Achievement goals for students at the end of the 10th form:

Modern physics content in LOWER secondary school curricula: Norwegian National Curriculum in Natural Science (2006) Achievement goals for students at the end of the 10th form: Topics that could be considered as “modern”, according to subject:

Modern physics content in LOWER secondary school curricula: Norwegian National Curriculum in Natural Science (2006) Achievement goals for students at the end of the 10th form: Topics that could be considered as “modern”, according to subject: Biology: 56%

Modern physics content in LOWER secondary school curricula: Norwegian National Curriculum in Natural Science (2006) Achievement goals for students at the end of the 10th form: Topics that could be considered as “modern”, according to subject: Biology: 56% Chemistry: 50%

Modern physics content in LOWER secondary school curricula: Norwegian National Curriculum in Natural Science (2006) Achievement goals for students at the end of the 10th form: Topics that could be considered as “modern”, according to subject: Biology: 56% Chemistry: 50% Physics: 35%

Modern physics content in UPPER secondary school curricula:

Modern physics content in UPPER secondary school curricula: TIMSS Advanced 2008: TIMSS Trends in International Mathematics and Science Study Countries Armenia, Iran, Italy, Lebanon, Netherlands, Norway, Philippines, Russia, Slovenia, Sweden

Modern physics content in UPPER secondary school curricula: TIMSS Advanced 2008: Modern physics topics comprised 18% of the intended curriculum [this reflected the curricular aims of the 10 participating countries— 6 from Europe, 4 from Asia]* TIMSS Trends in International Mathematics and Science Study Countries Armenia, Iran, Italy, Lebanon, Netherlands, Norway, Philippines, Russia, Slovenia, Sweden

Modern physics content in UPPER secondary school curricula: TIMSS Advanced 2008: Modern physics topics comprised 18% of the intended curriculum [this reflected the curricular aims of the 10 participating countries— 6 from Europe, 4 from Asia]* TIMSS Trends in International Mathematics and Science Study Countries Armenia, Iran, Italy, Lebanon, Netherlands, Norway, Philippines, Russia, Slovenia, Sweden * Armenia, Iran, Italy, Lebanon, Netherlands, Norway, Philippines, Russia, Slovenia, Sweden

Antimatter Teaching Module

Antimatter Teaching Module A review was conducted across a sample of national science curricula in order to establish a baseline for the background knowledge in science and mathematics of students entering the 9th form (14 years old) of lower secondary school.

Antimatter Teaching Module A review was conducted across a sample of national science curricula in order to establish a baseline for the background knowledge in science and mathematics of students entering the 9th form (14 years old) of lower secondary school. A pedagogical platform was designed to deliver the basic concepts of antimatter in a way that would be accessible to students aged 14-15 years.

Antimatter Teaching Module A review was conducted across a sample of national science curricula in order to establish a baseline for the background knowledge in science and mathematics of students entering the 9th form (14 years old) of lower secondary school. A pedagogical platform was designed to deliver the basic concepts of antimatter in a way that would be accessible to students aged 14-15 years. A teaching module was developed consisting of 8 main lesson plans, 5 background lessons, and 2 extension lessons on antimatter.