Development of the Unprofessional Help-seeking Consciousness Scale for University students

The purpose of this study was to develop of the Unprofessional Help-seeking Consciousness Scale for University students. The preliminary investigation was administrated to 120 university students. As the result of factor analysis, three-factor-structure with affirmative manner, treatment fearfulness and fall of the self-evaluation was provided. The investigation examined the reliability and the validity of the scale. This was administrated to 142 university students. As a result, some high reliability and some validity was confirmed. The result of this study showed some utility of the scale

A Study on the Relationship Between the Unprofessional Help-seeking Consciousness for University Students and Cultural Views of Self <Original Articles>

本研究は,文化的自己観に注目し,大学生の友人に対する援助要請を促進させる要因を明らかにすることを目的とした。分析の結果,援助要請に対する肯定的態度と相互協調的自己観は有意な相関関係があることが認められた。また,援助要請意識のモデルを共分散構造分析によって検討したところ,文化的自己観から援助要請意識を経て精神的健康に至る有意なパスが認められた。大学生の友人に対する援助要請行動を促進させるためには,文化的自己観や精神的健康に注目した関わりが重要であると考えられた。The purpose of this study was to investigate the factor which promotes the unprofessional helpseeking consciousness for university students from viewpoint of cultural views of self. As a result, affirmative attitude to help-seeking and interdependent construal of self were significantly correlated. And, the process of unprofessional help-seeking consciousness model was examined an analysis of covariance structures and a significant pass from cultural views of self to mental health via helpseeking consciousness. It was thought that relation which observed cultural view of self and mental health was valuable in order to promote the unprofessional help-seeking

Carrier Concentration Dependent Conduction in Insulator-Doped Donor/Acceptor Chain Compounds

On the basis of the concept that the design of a mixed valence system is a key route to create electronic conducting frameworks, we propose a unique idea to rationally produce mixed valency in an ionic donor/acceptor chain (i.e., D⁺A^– chain). The doping of a redox-inert (insulator) dopant (P) into a D⁺A^– chain in place of neutral D enables the creation of mixed valency A⁰/A^– domains between P units: P–(D⁺A^–)_<i>n</i>A⁰–P, where <i>n</i> is directly dependent on the dopant ratio, and charge transfer through the P units leads to electron transport along the framework. This hypothesis was experimentally demonstrated in an ionic DA chain synthesized from a redox-active paddlewheel [Ru₂^II,II] complex and TCNQ derivative by doping with a redox-inert [Rh₂^II,II] complex

Carrier Concentration Dependent Conduction in Insulator-Doped Donor/Acceptor Chain Compounds

On the basis of the concept that the design of a mixed valence system is a key route to create electronic conducting frameworks, we propose a unique idea to rationally produce mixed valency in an ionic donor/acceptor chain (i.e., D⁺A^– chain). The doping of a redox-inert (insulator) dopant (P) into a D⁺A^– chain in place of neutral D enables the creation of mixed valency A⁰/A^– domains between P units: P–(D⁺A^–)_<i>n</i>A⁰–P, where <i>n</i> is directly dependent on the dopant ratio, and charge transfer through the P units leads to electron transport along the framework. This hypothesis was experimentally demonstrated in an ionic DA chain synthesized from a redox-active paddlewheel [Ru₂^II,II] complex and TCNQ derivative by doping with a redox-inert [Rh₂^II,II] complex

Carrier Concentration Dependent Conduction in Insulator-Doped Donor/Acceptor Chain Compounds

On the basis of the concept that the design of a mixed valence system is a key route to create electronic conducting frameworks, we propose a unique idea to rationally produce mixed valency in an ionic donor/acceptor chain (i.e., D⁺A^– chain). The doping of a redox-inert (insulator) dopant (P) into a D⁺A^– chain in place of neutral D enables the creation of mixed valency A⁰/A^– domains between P units: P–(D⁺A^–)_<i>n</i>A⁰–P, where <i>n</i> is directly dependent on the dopant ratio, and charge transfer through the P units leads to electron transport along the framework. This hypothesis was experimentally demonstrated in an ionic DA chain synthesized from a redox-active paddlewheel [Ru₂^II,II] complex and TCNQ derivative by doping with a redox-inert [Rh₂^II,II] complex

Carrier Concentration Dependent Conduction in Insulator-Doped Donor/Acceptor Chain Compounds

On the basis of the concept that the design of a mixed valence system is a key route to create electronic conducting frameworks, we propose a unique idea to rationally produce mixed valency in an ionic donor/acceptor chain (i.e., D⁺A^– chain). The doping of a redox-inert (insulator) dopant (P) into a D⁺A^– chain in place of neutral D enables the creation of mixed valency A⁰/A^– domains between P units: P–(D⁺A^–)_<i>n</i>A⁰–P, where <i>n</i> is directly dependent on the dopant ratio, and charge transfer through the P units leads to electron transport along the framework. This hypothesis was experimentally demonstrated in an ionic DA chain synthesized from a redox-active paddlewheel [Ru₂^II,II] complex and TCNQ derivative by doping with a redox-inert [Rh₂^II,II] complex

Carrier Concentration Dependent Conduction in Insulator-Doped Donor/Acceptor Chain Compounds

On the basis of the concept that the design of a mixed valence system is a key route to create electronic conducting frameworks, we propose a unique idea to rationally produce mixed valency in an ionic donor/acceptor chain (i.e., D⁺A^– chain). The doping of a redox-inert (insulator) dopant (P) into a D⁺A^– chain in place of neutral D enables the creation of mixed valency A⁰/A^– domains between P units: P–(D⁺A^–)_<i>n</i>A⁰–P, where <i>n</i> is directly dependent on the dopant ratio, and charge transfer through the P units leads to electron transport along the framework. This hypothesis was experimentally demonstrated in an ionic DA chain synthesized from a redox-active paddlewheel [Ru₂^II,II] complex and TCNQ derivative by doping with a redox-inert [Rh₂^II,II] complex

Carrier Concentration Dependent Conduction in Insulator-Doped Donor/Acceptor Chain Compounds

On the basis of the concept that the design of a mixed valence system is a key route to create electronic conducting frameworks, we propose a unique idea to rationally produce mixed valency in an ionic donor/acceptor chain (i.e., D⁺A^– chain). The doping of a redox-inert (insulator) dopant (P) into a D⁺A^– chain in place of neutral D enables the creation of mixed valency A⁰/A^– domains between P units: P–(D⁺A^–)_<i>n</i>A⁰–P, where <i>n</i> is directly dependent on the dopant ratio, and charge transfer through the P units leads to electron transport along the framework. This hypothesis was experimentally demonstrated in an ionic DA chain synthesized from a redox-active paddlewheel [Ru₂^II,II] complex and TCNQ derivative by doping with a redox-inert [Rh₂^II,II] complex