4 research outputs found
Physical Therapy Management Of A Manual Laborer With Chronic Rotator Cuff Tendinopathy: A Case Report
Background: Tendinopathy is characterized by tendon thickening, localized pain and chronic degeneration reflective of failed healing. 38% of manual laborers who participate in daily moderate to heavy lifting will experience Rotator Cuff Tendinopathy(RCT). There is a lack of research investigating the PT management of manual laborers who have RCT, but must continue to participate in harmful activities to fulfill occupational responsibilities. Purpose: The purpose of this case report was to describe the PT management of a patient with rotator cuff tendinopathy who, due to work requirements continued to participate in activities detrimental to the health of the supraspinatus and function of the shoulder girdle.https://dune.une.edu/pt_studcrposter/1036/thumbnail.jp
Conductive Graphene–Melamine Sponge Prepared via Microwave Irradiation
A conductive
graphene–melamine sponge (MS) prepared via microwave irradiation
is reported in this paper. Graphene oxide supported on the MS was
prereduced first at 100 °C and then further reduced in a household
microwave oven at over 1000 °C. It was surprising to find that
graphene oxide on the MS was reduced perfectly while the three-dimensional
structure of the MS was kept well after high-temperature reduction
via microwave irradiation. Slight pyrolysis of MS was also found during
5 s microwave irradiation, resulting in nitrogen generation from the
pyrolysis of the MS being doped into graphene, which could benefit
the electric conductivity of the prepared graphene–MS. The
electric conductivity of the prepared graphene–MS is about
0.12–1.0 S/m because of the high reduction degree of graphene
oxide and nitrogen doping. On the other hand, different from the pure
MS, the newly developed conductive graphene–MS possesses superhydrophobic
and superoleophilic properties. Overall, the newly developed conductive
graphene–MS contained 94.3 wt % MS and 5.7 wt % N-doped graphene
and is a cost-effective material with good elasticity, high conductivity,
superhydrophobicity, and superoleophilicity
Conductive Graphene–Melamine Sponge Prepared via Microwave Irradiation
A conductive
graphene–melamine sponge (MS) prepared via microwave irradiation
is reported in this paper. Graphene oxide supported on the MS was
prereduced first at 100 °C and then further reduced in a household
microwave oven at over 1000 °C. It was surprising to find that
graphene oxide on the MS was reduced perfectly while the three-dimensional
structure of the MS was kept well after high-temperature reduction
via microwave irradiation. Slight pyrolysis of MS was also found during
5 s microwave irradiation, resulting in nitrogen generation from the
pyrolysis of the MS being doped into graphene, which could benefit
the electric conductivity of the prepared graphene–MS. The
electric conductivity of the prepared graphene–MS is about
0.12–1.0 S/m because of the high reduction degree of graphene
oxide and nitrogen doping. On the other hand, different from the pure
MS, the newly developed conductive graphene–MS possesses superhydrophobic
and superoleophilic properties. Overall, the newly developed conductive
graphene–MS contained 94.3 wt % MS and 5.7 wt % N-doped graphene
and is a cost-effective material with good elasticity, high conductivity,
superhydrophobicity, and superoleophilicity
Conductive Graphene–Melamine Sponge Prepared via Microwave Irradiation
A conductive
graphene–melamine sponge (MS) prepared via microwave irradiation
is reported in this paper. Graphene oxide supported on the MS was
prereduced first at 100 °C and then further reduced in a household
microwave oven at over 1000 °C. It was surprising to find that
graphene oxide on the MS was reduced perfectly while the three-dimensional
structure of the MS was kept well after high-temperature reduction
via microwave irradiation. Slight pyrolysis of MS was also found during
5 s microwave irradiation, resulting in nitrogen generation from the
pyrolysis of the MS being doped into graphene, which could benefit
the electric conductivity of the prepared graphene–MS. The
electric conductivity of the prepared graphene–MS is about
0.12–1.0 S/m because of the high reduction degree of graphene
oxide and nitrogen doping. On the other hand, different from the pure
MS, the newly developed conductive graphene–MS possesses superhydrophobic
and superoleophilic properties. Overall, the newly developed conductive
graphene–MS contained 94.3 wt % MS and 5.7 wt % N-doped graphene
and is a cost-effective material with good elasticity, high conductivity,
superhydrophobicity, and superoleophilicity