Images of Barcelona training on Friday ahead of their Saturday La Liga contest.
Billie Holliday: for the burn and also the way she told stories.
Thelonius Monk: for his earnestness.
Duke Ellington: for his edge and spirituality.
Louis Armstrong: his legacy is undeniable. He is considered as one of the most revolutionary and influential musicians.
Terence Blanchard: very political - a lot of jazz musicians are making protest music right now.
Billie Holliday: for the burn and also the way she told stories.
Thelonius Monk: for his earnestness.
Duke Ellington: for his edge and spirituality.
Louis Armstrong: his legacy is undeniable. He is considered as one of the most revolutionary and influential musicians.
Terence Blanchard: very political - a lot of jazz musicians are making protest music right now.
Billie Holliday: for the burn and also the way she told stories.
Thelonius Monk: for his earnestness.
Duke Ellington: for his edge and spirituality.
Louis Armstrong: his legacy is undeniable. He is considered as one of the most revolutionary and influential musicians.
Terence Blanchard: very political - a lot of jazz musicians are making protest music right now.
Billie Holliday: for the burn and also the way she told stories.
Thelonius Monk: for his earnestness.
Duke Ellington: for his edge and spirituality.
Louis Armstrong: his legacy is undeniable. He is considered as one of the most revolutionary and influential musicians.
Terence Blanchard: very political - a lot of jazz musicians are making protest music right now.
Billie Holliday: for the burn and also the way she told stories.
Thelonius Monk: for his earnestness.
Duke Ellington: for his edge and spirituality.
Louis Armstrong: his legacy is undeniable. He is considered as one of the most revolutionary and influential musicians.
Terence Blanchard: very political - a lot of jazz musicians are making protest music right now.
Billie Holliday: for the burn and also the way she told stories.
Thelonius Monk: for his earnestness.
Duke Ellington: for his edge and spirituality.
Louis Armstrong: his legacy is undeniable. He is considered as one of the most revolutionary and influential musicians.
Terence Blanchard: very political - a lot of jazz musicians are making protest music right now.
Billie Holliday: for the burn and also the way she told stories.
Thelonius Monk: for his earnestness.
Duke Ellington: for his edge and spirituality.
Louis Armstrong: his legacy is undeniable. He is considered as one of the most revolutionary and influential musicians.
Terence Blanchard: very political - a lot of jazz musicians are making protest music right now.
Billie Holliday: for the burn and also the way she told stories.
Thelonius Monk: for his earnestness.
Duke Ellington: for his edge and spirituality.
Louis Armstrong: his legacy is undeniable. He is considered as one of the most revolutionary and influential musicians.
Terence Blanchard: very political - a lot of jazz musicians are making protest music right now.
Billie Holliday: for the burn and also the way she told stories.
Thelonius Monk: for his earnestness.
Duke Ellington: for his edge and spirituality.
Louis Armstrong: his legacy is undeniable. He is considered as one of the most revolutionary and influential musicians.
Terence Blanchard: very political - a lot of jazz musicians are making protest music right now.
Billie Holliday: for the burn and also the way she told stories.
Thelonius Monk: for his earnestness.
Duke Ellington: for his edge and spirituality.
Louis Armstrong: his legacy is undeniable. He is considered as one of the most revolutionary and influential musicians.
Terence Blanchard: very political - a lot of jazz musicians are making protest music right now.
Billie Holliday: for the burn and also the way she told stories.
Thelonius Monk: for his earnestness.
Duke Ellington: for his edge and spirituality.
Louis Armstrong: his legacy is undeniable. He is considered as one of the most revolutionary and influential musicians.
Terence Blanchard: very political - a lot of jazz musicians are making protest music right now.
Billie Holliday: for the burn and also the way she told stories.
Thelonius Monk: for his earnestness.
Duke Ellington: for his edge and spirituality.
Louis Armstrong: his legacy is undeniable. He is considered as one of the most revolutionary and influential musicians.
Terence Blanchard: very political - a lot of jazz musicians are making protest music right now.
Billie Holliday: for the burn and also the way she told stories.
Thelonius Monk: for his earnestness.
Duke Ellington: for his edge and spirituality.
Louis Armstrong: his legacy is undeniable. He is considered as one of the most revolutionary and influential musicians.
Terence Blanchard: very political - a lot of jazz musicians are making protest music right now.
Billie Holliday: for the burn and also the way she told stories.
Thelonius Monk: for his earnestness.
Duke Ellington: for his edge and spirituality.
Louis Armstrong: his legacy is undeniable. He is considered as one of the most revolutionary and influential musicians.
Terence Blanchard: very political - a lot of jazz musicians are making protest music right now.
Billie Holliday: for the burn and also the way she told stories.
Thelonius Monk: for his earnestness.
Duke Ellington: for his edge and spirituality.
Louis Armstrong: his legacy is undeniable. He is considered as one of the most revolutionary and influential musicians.
Terence Blanchard: very political - a lot of jazz musicians are making protest music right now.
Billie Holliday: for the burn and also the way she told stories.
Thelonius Monk: for his earnestness.
Duke Ellington: for his edge and spirituality.
Louis Armstrong: his legacy is undeniable. He is considered as one of the most revolutionary and influential musicians.
Terence Blanchard: very political - a lot of jazz musicians are making protest music right now.
"They see their tomorrows slipping out of their reach. And though it seems to them that everything outside this reality is heaven, yet they do not want to go to that heaven. They stay, because they are afflicted with hope." - Mahmoud Darwish, to attendees of the Palestine Festival of Literature, 2008
His life in brief: Born in a village near Galilee, he lived in exile for most of his life and started writing poetry after high school. He was arrested several times by Israel for what were deemed to be inciteful poems. Most of his work focused on the love and yearning for his homeland, and he was regarded the Palestinian poet of resistance. Over the course of his life, he published more than 30 poetry collections and books of prose, with his work translated into more than 20 languages. Many of his poems were set to music by Arab composers, most significantly Marcel Khalife. Darwish died on August 9, 2008 after undergoing heart surgery in the United States. He was later buried in Ramallah where a shrine was erected in his honour.
"They see their tomorrows slipping out of their reach. And though it seems to them that everything outside this reality is heaven, yet they do not want to go to that heaven. They stay, because they are afflicted with hope." - Mahmoud Darwish, to attendees of the Palestine Festival of Literature, 2008
His life in brief: Born in a village near Galilee, he lived in exile for most of his life and started writing poetry after high school. He was arrested several times by Israel for what were deemed to be inciteful poems. Most of his work focused on the love and yearning for his homeland, and he was regarded the Palestinian poet of resistance. Over the course of his life, he published more than 30 poetry collections and books of prose, with his work translated into more than 20 languages. Many of his poems were set to music by Arab composers, most significantly Marcel Khalife. Darwish died on August 9, 2008 after undergoing heart surgery in the United States. He was later buried in Ramallah where a shrine was erected in his honour.
"They see their tomorrows slipping out of their reach. And though it seems to them that everything outside this reality is heaven, yet they do not want to go to that heaven. They stay, because they are afflicted with hope." - Mahmoud Darwish, to attendees of the Palestine Festival of Literature, 2008
His life in brief: Born in a village near Galilee, he lived in exile for most of his life and started writing poetry after high school. He was arrested several times by Israel for what were deemed to be inciteful poems. Most of his work focused on the love and yearning for his homeland, and he was regarded the Palestinian poet of resistance. Over the course of his life, he published more than 30 poetry collections and books of prose, with his work translated into more than 20 languages. Many of his poems were set to music by Arab composers, most significantly Marcel Khalife. Darwish died on August 9, 2008 after undergoing heart surgery in the United States. He was later buried in Ramallah where a shrine was erected in his honour.
"They see their tomorrows slipping out of their reach. And though it seems to them that everything outside this reality is heaven, yet they do not want to go to that heaven. They stay, because they are afflicted with hope." - Mahmoud Darwish, to attendees of the Palestine Festival of Literature, 2008
His life in brief: Born in a village near Galilee, he lived in exile for most of his life and started writing poetry after high school. He was arrested several times by Israel for what were deemed to be inciteful poems. Most of his work focused on the love and yearning for his homeland, and he was regarded the Palestinian poet of resistance. Over the course of his life, he published more than 30 poetry collections and books of prose, with his work translated into more than 20 languages. Many of his poems were set to music by Arab composers, most significantly Marcel Khalife. Darwish died on August 9, 2008 after undergoing heart surgery in the United States. He was later buried in Ramallah where a shrine was erected in his honour.
"They see their tomorrows slipping out of their reach. And though it seems to them that everything outside this reality is heaven, yet they do not want to go to that heaven. They stay, because they are afflicted with hope." - Mahmoud Darwish, to attendees of the Palestine Festival of Literature, 2008
His life in brief: Born in a village near Galilee, he lived in exile for most of his life and started writing poetry after high school. He was arrested several times by Israel for what were deemed to be inciteful poems. Most of his work focused on the love and yearning for his homeland, and he was regarded the Palestinian poet of resistance. Over the course of his life, he published more than 30 poetry collections and books of prose, with his work translated into more than 20 languages. Many of his poems were set to music by Arab composers, most significantly Marcel Khalife. Darwish died on August 9, 2008 after undergoing heart surgery in the United States. He was later buried in Ramallah where a shrine was erected in his honour.
"They see their tomorrows slipping out of their reach. And though it seems to them that everything outside this reality is heaven, yet they do not want to go to that heaven. They stay, because they are afflicted with hope." - Mahmoud Darwish, to attendees of the Palestine Festival of Literature, 2008
His life in brief: Born in a village near Galilee, he lived in exile for most of his life and started writing poetry after high school. He was arrested several times by Israel for what were deemed to be inciteful poems. Most of his work focused on the love and yearning for his homeland, and he was regarded the Palestinian poet of resistance. Over the course of his life, he published more than 30 poetry collections and books of prose, with his work translated into more than 20 languages. Many of his poems were set to music by Arab composers, most significantly Marcel Khalife. Darwish died on August 9, 2008 after undergoing heart surgery in the United States. He was later buried in Ramallah where a shrine was erected in his honour.
"They see their tomorrows slipping out of their reach. And though it seems to them that everything outside this reality is heaven, yet they do not want to go to that heaven. They stay, because they are afflicted with hope." - Mahmoud Darwish, to attendees of the Palestine Festival of Literature, 2008
His life in brief: Born in a village near Galilee, he lived in exile for most of his life and started writing poetry after high school. He was arrested several times by Israel for what were deemed to be inciteful poems. Most of his work focused on the love and yearning for his homeland, and he was regarded the Palestinian poet of resistance. Over the course of his life, he published more than 30 poetry collections and books of prose, with his work translated into more than 20 languages. Many of his poems were set to music by Arab composers, most significantly Marcel Khalife. Darwish died on August 9, 2008 after undergoing heart surgery in the United States. He was later buried in Ramallah where a shrine was erected in his honour.
"They see their tomorrows slipping out of their reach. And though it seems to them that everything outside this reality is heaven, yet they do not want to go to that heaven. They stay, because they are afflicted with hope." - Mahmoud Darwish, to attendees of the Palestine Festival of Literature, 2008
His life in brief: Born in a village near Galilee, he lived in exile for most of his life and started writing poetry after high school. He was arrested several times by Israel for what were deemed to be inciteful poems. Most of his work focused on the love and yearning for his homeland, and he was regarded the Palestinian poet of resistance. Over the course of his life, he published more than 30 poetry collections and books of prose, with his work translated into more than 20 languages. Many of his poems were set to music by Arab composers, most significantly Marcel Khalife. Darwish died on August 9, 2008 after undergoing heart surgery in the United States. He was later buried in Ramallah where a shrine was erected in his honour.
"They see their tomorrows slipping out of their reach. And though it seems to them that everything outside this reality is heaven, yet they do not want to go to that heaven. They stay, because they are afflicted with hope." - Mahmoud Darwish, to attendees of the Palestine Festival of Literature, 2008
His life in brief: Born in a village near Galilee, he lived in exile for most of his life and started writing poetry after high school. He was arrested several times by Israel for what were deemed to be inciteful poems. Most of his work focused on the love and yearning for his homeland, and he was regarded the Palestinian poet of resistance. Over the course of his life, he published more than 30 poetry collections and books of prose, with his work translated into more than 20 languages. Many of his poems were set to music by Arab composers, most significantly Marcel Khalife. Darwish died on August 9, 2008 after undergoing heart surgery in the United States. He was later buried in Ramallah where a shrine was erected in his honour.
"They see their tomorrows slipping out of their reach. And though it seems to them that everything outside this reality is heaven, yet they do not want to go to that heaven. They stay, because they are afflicted with hope." - Mahmoud Darwish, to attendees of the Palestine Festival of Literature, 2008
His life in brief: Born in a village near Galilee, he lived in exile for most of his life and started writing poetry after high school. He was arrested several times by Israel for what were deemed to be inciteful poems. Most of his work focused on the love and yearning for his homeland, and he was regarded the Palestinian poet of resistance. Over the course of his life, he published more than 30 poetry collections and books of prose, with his work translated into more than 20 languages. Many of his poems were set to music by Arab composers, most significantly Marcel Khalife. Darwish died on August 9, 2008 after undergoing heart surgery in the United States. He was later buried in Ramallah where a shrine was erected in his honour.
"They see their tomorrows slipping out of their reach. And though it seems to them that everything outside this reality is heaven, yet they do not want to go to that heaven. They stay, because they are afflicted with hope." - Mahmoud Darwish, to attendees of the Palestine Festival of Literature, 2008
His life in brief: Born in a village near Galilee, he lived in exile for most of his life and started writing poetry after high school. He was arrested several times by Israel for what were deemed to be inciteful poems. Most of his work focused on the love and yearning for his homeland, and he was regarded the Palestinian poet of resistance. Over the course of his life, he published more than 30 poetry collections and books of prose, with his work translated into more than 20 languages. Many of his poems were set to music by Arab composers, most significantly Marcel Khalife. Darwish died on August 9, 2008 after undergoing heart surgery in the United States. He was later buried in Ramallah where a shrine was erected in his honour.
"They see their tomorrows slipping out of their reach. And though it seems to them that everything outside this reality is heaven, yet they do not want to go to that heaven. They stay, because they are afflicted with hope." - Mahmoud Darwish, to attendees of the Palestine Festival of Literature, 2008
His life in brief: Born in a village near Galilee, he lived in exile for most of his life and started writing poetry after high school. He was arrested several times by Israel for what were deemed to be inciteful poems. Most of his work focused on the love and yearning for his homeland, and he was regarded the Palestinian poet of resistance. Over the course of his life, he published more than 30 poetry collections and books of prose, with his work translated into more than 20 languages. Many of his poems were set to music by Arab composers, most significantly Marcel Khalife. Darwish died on August 9, 2008 after undergoing heart surgery in the United States. He was later buried in Ramallah where a shrine was erected in his honour.
"They see their tomorrows slipping out of their reach. And though it seems to them that everything outside this reality is heaven, yet they do not want to go to that heaven. They stay, because they are afflicted with hope." - Mahmoud Darwish, to attendees of the Palestine Festival of Literature, 2008
His life in brief: Born in a village near Galilee, he lived in exile for most of his life and started writing poetry after high school. He was arrested several times by Israel for what were deemed to be inciteful poems. Most of his work focused on the love and yearning for his homeland, and he was regarded the Palestinian poet of resistance. Over the course of his life, he published more than 30 poetry collections and books of prose, with his work translated into more than 20 languages. Many of his poems were set to music by Arab composers, most significantly Marcel Khalife. Darwish died on August 9, 2008 after undergoing heart surgery in the United States. He was later buried in Ramallah where a shrine was erected in his honour.
"They see their tomorrows slipping out of their reach. And though it seems to them that everything outside this reality is heaven, yet they do not want to go to that heaven. They stay, because they are afflicted with hope." - Mahmoud Darwish, to attendees of the Palestine Festival of Literature, 2008
His life in brief: Born in a village near Galilee, he lived in exile for most of his life and started writing poetry after high school. He was arrested several times by Israel for what were deemed to be inciteful poems. Most of his work focused on the love and yearning for his homeland, and he was regarded the Palestinian poet of resistance. Over the course of his life, he published more than 30 poetry collections and books of prose, with his work translated into more than 20 languages. Many of his poems were set to music by Arab composers, most significantly Marcel Khalife. Darwish died on August 9, 2008 after undergoing heart surgery in the United States. He was later buried in Ramallah where a shrine was erected in his honour.
"They see their tomorrows slipping out of their reach. And though it seems to them that everything outside this reality is heaven, yet they do not want to go to that heaven. They stay, because they are afflicted with hope." - Mahmoud Darwish, to attendees of the Palestine Festival of Literature, 2008
His life in brief: Born in a village near Galilee, he lived in exile for most of his life and started writing poetry after high school. He was arrested several times by Israel for what were deemed to be inciteful poems. Most of his work focused on the love and yearning for his homeland, and he was regarded the Palestinian poet of resistance. Over the course of his life, he published more than 30 poetry collections and books of prose, with his work translated into more than 20 languages. Many of his poems were set to music by Arab composers, most significantly Marcel Khalife. Darwish died on August 9, 2008 after undergoing heart surgery in the United States. He was later buried in Ramallah where a shrine was erected in his honour.
"They see their tomorrows slipping out of their reach. And though it seems to them that everything outside this reality is heaven, yet they do not want to go to that heaven. They stay, because they are afflicted with hope." - Mahmoud Darwish, to attendees of the Palestine Festival of Literature, 2008
His life in brief: Born in a village near Galilee, he lived in exile for most of his life and started writing poetry after high school. He was arrested several times by Israel for what were deemed to be inciteful poems. Most of his work focused on the love and yearning for his homeland, and he was regarded the Palestinian poet of resistance. Over the course of his life, he published more than 30 poetry collections and books of prose, with his work translated into more than 20 languages. Many of his poems were set to music by Arab composers, most significantly Marcel Khalife. Darwish died on August 9, 2008 after undergoing heart surgery in the United States. He was later buried in Ramallah where a shrine was erected in his honour.
From Conquest to Deportation
Jeronim Perovic, Hurst
From Conquest to Deportation
Jeronim Perovic, Hurst
From Conquest to Deportation
Jeronim Perovic, Hurst
From Conquest to Deportation
Jeronim Perovic, Hurst
From Conquest to Deportation
Jeronim Perovic, Hurst
From Conquest to Deportation
Jeronim Perovic, Hurst
From Conquest to Deportation
Jeronim Perovic, Hurst
From Conquest to Deportation
Jeronim Perovic, Hurst
From Conquest to Deportation
Jeronim Perovic, Hurst
From Conquest to Deportation
Jeronim Perovic, Hurst
From Conquest to Deportation
Jeronim Perovic, Hurst
From Conquest to Deportation
Jeronim Perovic, Hurst
From Conquest to Deportation
Jeronim Perovic, Hurst
From Conquest to Deportation
Jeronim Perovic, Hurst
From Conquest to Deportation
Jeronim Perovic, Hurst
From Conquest to Deportation
Jeronim Perovic, Hurst
26 - New Zealand v England at Auckland, March 1955
30 - South Africa v England at Port Elizabeth, Feb 1896
30 - South Africa v England at Birmingham, June 1924
35 - South Africa v England at Cape Town, April 1899
36 - South Africa v Australia at Melbourne, Feb. 1932
36 - Australia v England at Birmingham, May 1902
36 - India v Australia at Adelaide, Dec. 2020
38 - Ireland v England at Lord's, July 2019
42 - New Zealand v Australia in Wellington, March 1946
42 - Australia v England in Sydney, Feb. 1888
26 - New Zealand v England at Auckland, March 1955
30 - South Africa v England at Port Elizabeth, Feb 1896
30 - South Africa v England at Birmingham, June 1924
35 - South Africa v England at Cape Town, April 1899
36 - South Africa v Australia at Melbourne, Feb. 1932
36 - Australia v England at Birmingham, May 1902
36 - India v Australia at Adelaide, Dec. 2020
38 - Ireland v England at Lord's, July 2019
42 - New Zealand v Australia in Wellington, March 1946
42 - Australia v England in Sydney, Feb. 1888
26 - New Zealand v England at Auckland, March 1955
30 - South Africa v England at Port Elizabeth, Feb 1896
30 - South Africa v England at Birmingham, June 1924
35 - South Africa v England at Cape Town, April 1899
36 - South Africa v Australia at Melbourne, Feb. 1932
36 - Australia v England at Birmingham, May 1902
36 - India v Australia at Adelaide, Dec. 2020
38 - Ireland v England at Lord's, July 2019
42 - New Zealand v Australia in Wellington, March 1946
42 - Australia v England in Sydney, Feb. 1888
26 - New Zealand v England at Auckland, March 1955
30 - South Africa v England at Port Elizabeth, Feb 1896
30 - South Africa v England at Birmingham, June 1924
35 - South Africa v England at Cape Town, April 1899
36 - South Africa v Australia at Melbourne, Feb. 1932
36 - Australia v England at Birmingham, May 1902
36 - India v Australia at Adelaide, Dec. 2020
38 - Ireland v England at Lord's, July 2019
42 - New Zealand v Australia in Wellington, March 1946
42 - Australia v England in Sydney, Feb. 1888
26 - New Zealand v England at Auckland, March 1955
30 - South Africa v England at Port Elizabeth, Feb 1896
30 - South Africa v England at Birmingham, June 1924
35 - South Africa v England at Cape Town, April 1899
36 - South Africa v Australia at Melbourne, Feb. 1932
36 - Australia v England at Birmingham, May 1902
36 - India v Australia at Adelaide, Dec. 2020
38 - Ireland v England at Lord's, July 2019
42 - New Zealand v Australia in Wellington, March 1946
42 - Australia v England in Sydney, Feb. 1888
26 - New Zealand v England at Auckland, March 1955
30 - South Africa v England at Port Elizabeth, Feb 1896
30 - South Africa v England at Birmingham, June 1924
35 - South Africa v England at Cape Town, April 1899
36 - South Africa v Australia at Melbourne, Feb. 1932
36 - Australia v England at Birmingham, May 1902
36 - India v Australia at Adelaide, Dec. 2020
38 - Ireland v England at Lord's, July 2019
42 - New Zealand v Australia in Wellington, March 1946
42 - Australia v England in Sydney, Feb. 1888
26 - New Zealand v England at Auckland, March 1955
30 - South Africa v England at Port Elizabeth, Feb 1896
30 - South Africa v England at Birmingham, June 1924
35 - South Africa v England at Cape Town, April 1899
36 - South Africa v Australia at Melbourne, Feb. 1932
36 - Australia v England at Birmingham, May 1902
36 - India v Australia at Adelaide, Dec. 2020
38 - Ireland v England at Lord's, July 2019
42 - New Zealand v Australia in Wellington, March 1946
42 - Australia v England in Sydney, Feb. 1888
26 - New Zealand v England at Auckland, March 1955
30 - South Africa v England at Port Elizabeth, Feb 1896
30 - South Africa v England at Birmingham, June 1924
35 - South Africa v England at Cape Town, April 1899
36 - South Africa v Australia at Melbourne, Feb. 1932
36 - Australia v England at Birmingham, May 1902
36 - India v Australia at Adelaide, Dec. 2020
38 - Ireland v England at Lord's, July 2019
42 - New Zealand v Australia in Wellington, March 1946
42 - Australia v England in Sydney, Feb. 1888
26 - New Zealand v England at Auckland, March 1955
30 - South Africa v England at Port Elizabeth, Feb 1896
30 - South Africa v England at Birmingham, June 1924
35 - South Africa v England at Cape Town, April 1899
36 - South Africa v Australia at Melbourne, Feb. 1932
36 - Australia v England at Birmingham, May 1902
36 - India v Australia at Adelaide, Dec. 2020
38 - Ireland v England at Lord's, July 2019
42 - New Zealand v Australia in Wellington, March 1946
42 - Australia v England in Sydney, Feb. 1888
26 - New Zealand v England at Auckland, March 1955
30 - South Africa v England at Port Elizabeth, Feb 1896
30 - South Africa v England at Birmingham, June 1924
35 - South Africa v England at Cape Town, April 1899
36 - South Africa v Australia at Melbourne, Feb. 1932
36 - Australia v England at Birmingham, May 1902
36 - India v Australia at Adelaide, Dec. 2020
38 - Ireland v England at Lord's, July 2019
42 - New Zealand v Australia in Wellington, March 1946
42 - Australia v England in Sydney, Feb. 1888
26 - New Zealand v England at Auckland, March 1955
30 - South Africa v England at Port Elizabeth, Feb 1896
30 - South Africa v England at Birmingham, June 1924
35 - South Africa v England at Cape Town, April 1899
36 - South Africa v Australia at Melbourne, Feb. 1932
36 - Australia v England at Birmingham, May 1902
36 - India v Australia at Adelaide, Dec. 2020
38 - Ireland v England at Lord's, July 2019
42 - New Zealand v Australia in Wellington, March 1946
42 - Australia v England in Sydney, Feb. 1888
26 - New Zealand v England at Auckland, March 1955
30 - South Africa v England at Port Elizabeth, Feb 1896
30 - South Africa v England at Birmingham, June 1924
35 - South Africa v England at Cape Town, April 1899
36 - South Africa v Australia at Melbourne, Feb. 1932
36 - Australia v England at Birmingham, May 1902
36 - India v Australia at Adelaide, Dec. 2020
38 - Ireland v England at Lord's, July 2019
42 - New Zealand v Australia in Wellington, March 1946
42 - Australia v England in Sydney, Feb. 1888
26 - New Zealand v England at Auckland, March 1955
30 - South Africa v England at Port Elizabeth, Feb 1896
30 - South Africa v England at Birmingham, June 1924
35 - South Africa v England at Cape Town, April 1899
36 - South Africa v Australia at Melbourne, Feb. 1932
36 - Australia v England at Birmingham, May 1902
36 - India v Australia at Adelaide, Dec. 2020
38 - Ireland v England at Lord's, July 2019
42 - New Zealand v Australia in Wellington, March 1946
42 - Australia v England in Sydney, Feb. 1888
26 - New Zealand v England at Auckland, March 1955
30 - South Africa v England at Port Elizabeth, Feb 1896
30 - South Africa v England at Birmingham, June 1924
35 - South Africa v England at Cape Town, April 1899
36 - South Africa v Australia at Melbourne, Feb. 1932
36 - Australia v England at Birmingham, May 1902
36 - India v Australia at Adelaide, Dec. 2020
38 - Ireland v England at Lord's, July 2019
42 - New Zealand v Australia in Wellington, March 1946
42 - Australia v England in Sydney, Feb. 1888
26 - New Zealand v England at Auckland, March 1955
30 - South Africa v England at Port Elizabeth, Feb 1896
30 - South Africa v England at Birmingham, June 1924
35 - South Africa v England at Cape Town, April 1899
36 - South Africa v Australia at Melbourne, Feb. 1932
36 - Australia v England at Birmingham, May 1902
36 - India v Australia at Adelaide, Dec. 2020
38 - Ireland v England at Lord's, July 2019
42 - New Zealand v Australia in Wellington, March 1946
42 - Australia v England in Sydney, Feb. 1888
26 - New Zealand v England at Auckland, March 1955
30 - South Africa v England at Port Elizabeth, Feb 1896
30 - South Africa v England at Birmingham, June 1924
35 - South Africa v England at Cape Town, April 1899
36 - South Africa v Australia at Melbourne, Feb. 1932
36 - Australia v England at Birmingham, May 1902
36 - India v Australia at Adelaide, Dec. 2020
38 - Ireland v England at Lord's, July 2019
42 - New Zealand v Australia in Wellington, March 1946
42 - Australia v England in Sydney, Feb. 1888
Graphene is a single layer of carbon atoms arranged like honeycomb.
It was discovered in 2004, when Russian-born Manchester scientists Andrei Geim and Kostya Novoselov were "playing about" with sticky tape and graphite - the material used as "lead" in pencils.
Placing the tape on the graphite and peeling it, they managed to rip off thin flakes of carbon. In the beginning they got flakes consisting of many layers of graphene. But as they repeated the process many times, the flakes got thinner.
By separating the graphite fragments repeatedly, they managed to create flakes that were just one atom thick. Their experiment had led to graphene being isolated for the very first time.
At the time, many believed it was impossible for such thin crystalline materials to be stable. But examined under a microscope, the material remained stable, and when tested was found to have incredible properties.
It is many times times stronger than steel, yet incredibly lightweight and flexible. It is electrically and thermally conductive but also transparent. The world's first 2D material, it is one million times thinner than the diameter of a single human hair.
But the 'sticky tape' method would not work on an industrial scale. Since then, scientists have been working on manufacturing graphene, to make use of its incredible properties.
In 2010, Geim and Novoselov were awarded the Nobel Prize for Physics. Their discovery meant physicists could study a new class of two-dimensional materials with unique properties.
Graphene is a single layer of carbon atoms arranged like honeycomb.
It was discovered in 2004, when Russian-born Manchester scientists Andrei Geim and Kostya Novoselov were "playing about" with sticky tape and graphite - the material used as "lead" in pencils.
Placing the tape on the graphite and peeling it, they managed to rip off thin flakes of carbon. In the beginning they got flakes consisting of many layers of graphene. But as they repeated the process many times, the flakes got thinner.
By separating the graphite fragments repeatedly, they managed to create flakes that were just one atom thick. Their experiment had led to graphene being isolated for the very first time.
At the time, many believed it was impossible for such thin crystalline materials to be stable. But examined under a microscope, the material remained stable, and when tested was found to have incredible properties.
It is many times times stronger than steel, yet incredibly lightweight and flexible. It is electrically and thermally conductive but also transparent. The world's first 2D material, it is one million times thinner than the diameter of a single human hair.
But the 'sticky tape' method would not work on an industrial scale. Since then, scientists have been working on manufacturing graphene, to make use of its incredible properties.
In 2010, Geim and Novoselov were awarded the Nobel Prize for Physics. Their discovery meant physicists could study a new class of two-dimensional materials with unique properties.
Graphene is a single layer of carbon atoms arranged like honeycomb.
It was discovered in 2004, when Russian-born Manchester scientists Andrei Geim and Kostya Novoselov were "playing about" with sticky tape and graphite - the material used as "lead" in pencils.
Placing the tape on the graphite and peeling it, they managed to rip off thin flakes of carbon. In the beginning they got flakes consisting of many layers of graphene. But as they repeated the process many times, the flakes got thinner.
By separating the graphite fragments repeatedly, they managed to create flakes that were just one atom thick. Their experiment had led to graphene being isolated for the very first time.
At the time, many believed it was impossible for such thin crystalline materials to be stable. But examined under a microscope, the material remained stable, and when tested was found to have incredible properties.
It is many times times stronger than steel, yet incredibly lightweight and flexible. It is electrically and thermally conductive but also transparent. The world's first 2D material, it is one million times thinner than the diameter of a single human hair.
But the 'sticky tape' method would not work on an industrial scale. Since then, scientists have been working on manufacturing graphene, to make use of its incredible properties.
In 2010, Geim and Novoselov were awarded the Nobel Prize for Physics. Their discovery meant physicists could study a new class of two-dimensional materials with unique properties.
Graphene is a single layer of carbon atoms arranged like honeycomb.
It was discovered in 2004, when Russian-born Manchester scientists Andrei Geim and Kostya Novoselov were "playing about" with sticky tape and graphite - the material used as "lead" in pencils.
Placing the tape on the graphite and peeling it, they managed to rip off thin flakes of carbon. In the beginning they got flakes consisting of many layers of graphene. But as they repeated the process many times, the flakes got thinner.
By separating the graphite fragments repeatedly, they managed to create flakes that were just one atom thick. Their experiment had led to graphene being isolated for the very first time.
At the time, many believed it was impossible for such thin crystalline materials to be stable. But examined under a microscope, the material remained stable, and when tested was found to have incredible properties.
It is many times times stronger than steel, yet incredibly lightweight and flexible. It is electrically and thermally conductive but also transparent. The world's first 2D material, it is one million times thinner than the diameter of a single human hair.
But the 'sticky tape' method would not work on an industrial scale. Since then, scientists have been working on manufacturing graphene, to make use of its incredible properties.
In 2010, Geim and Novoselov were awarded the Nobel Prize for Physics. Their discovery meant physicists could study a new class of two-dimensional materials with unique properties.
Graphene is a single layer of carbon atoms arranged like honeycomb.
It was discovered in 2004, when Russian-born Manchester scientists Andrei Geim and Kostya Novoselov were "playing about" with sticky tape and graphite - the material used as "lead" in pencils.
Placing the tape on the graphite and peeling it, they managed to rip off thin flakes of carbon. In the beginning they got flakes consisting of many layers of graphene. But as they repeated the process many times, the flakes got thinner.
By separating the graphite fragments repeatedly, they managed to create flakes that were just one atom thick. Their experiment had led to graphene being isolated for the very first time.
At the time, many believed it was impossible for such thin crystalline materials to be stable. But examined under a microscope, the material remained stable, and when tested was found to have incredible properties.
It is many times times stronger than steel, yet incredibly lightweight and flexible. It is electrically and thermally conductive but also transparent. The world's first 2D material, it is one million times thinner than the diameter of a single human hair.
But the 'sticky tape' method would not work on an industrial scale. Since then, scientists have been working on manufacturing graphene, to make use of its incredible properties.
In 2010, Geim and Novoselov were awarded the Nobel Prize for Physics. Their discovery meant physicists could study a new class of two-dimensional materials with unique properties.
Graphene is a single layer of carbon atoms arranged like honeycomb.
It was discovered in 2004, when Russian-born Manchester scientists Andrei Geim and Kostya Novoselov were "playing about" with sticky tape and graphite - the material used as "lead" in pencils.
Placing the tape on the graphite and peeling it, they managed to rip off thin flakes of carbon. In the beginning they got flakes consisting of many layers of graphene. But as they repeated the process many times, the flakes got thinner.
By separating the graphite fragments repeatedly, they managed to create flakes that were just one atom thick. Their experiment had led to graphene being isolated for the very first time.
At the time, many believed it was impossible for such thin crystalline materials to be stable. But examined under a microscope, the material remained stable, and when tested was found to have incredible properties.
It is many times times stronger than steel, yet incredibly lightweight and flexible. It is electrically and thermally conductive but also transparent. The world's first 2D material, it is one million times thinner than the diameter of a single human hair.
But the 'sticky tape' method would not work on an industrial scale. Since then, scientists have been working on manufacturing graphene, to make use of its incredible properties.
In 2010, Geim and Novoselov were awarded the Nobel Prize for Physics. Their discovery meant physicists could study a new class of two-dimensional materials with unique properties.
Graphene is a single layer of carbon atoms arranged like honeycomb.
It was discovered in 2004, when Russian-born Manchester scientists Andrei Geim and Kostya Novoselov were "playing about" with sticky tape and graphite - the material used as "lead" in pencils.
Placing the tape on the graphite and peeling it, they managed to rip off thin flakes of carbon. In the beginning they got flakes consisting of many layers of graphene. But as they repeated the process many times, the flakes got thinner.
By separating the graphite fragments repeatedly, they managed to create flakes that were just one atom thick. Their experiment had led to graphene being isolated for the very first time.
At the time, many believed it was impossible for such thin crystalline materials to be stable. But examined under a microscope, the material remained stable, and when tested was found to have incredible properties.
It is many times times stronger than steel, yet incredibly lightweight and flexible. It is electrically and thermally conductive but also transparent. The world's first 2D material, it is one million times thinner than the diameter of a single human hair.
But the 'sticky tape' method would not work on an industrial scale. Since then, scientists have been working on manufacturing graphene, to make use of its incredible properties.
In 2010, Geim and Novoselov were awarded the Nobel Prize for Physics. Their discovery meant physicists could study a new class of two-dimensional materials with unique properties.
Graphene is a single layer of carbon atoms arranged like honeycomb.
It was discovered in 2004, when Russian-born Manchester scientists Andrei Geim and Kostya Novoselov were "playing about" with sticky tape and graphite - the material used as "lead" in pencils.
Placing the tape on the graphite and peeling it, they managed to rip off thin flakes of carbon. In the beginning they got flakes consisting of many layers of graphene. But as they repeated the process many times, the flakes got thinner.
By separating the graphite fragments repeatedly, they managed to create flakes that were just one atom thick. Their experiment had led to graphene being isolated for the very first time.
At the time, many believed it was impossible for such thin crystalline materials to be stable. But examined under a microscope, the material remained stable, and when tested was found to have incredible properties.
It is many times times stronger than steel, yet incredibly lightweight and flexible. It is electrically and thermally conductive but also transparent. The world's first 2D material, it is one million times thinner than the diameter of a single human hair.
But the 'sticky tape' method would not work on an industrial scale. Since then, scientists have been working on manufacturing graphene, to make use of its incredible properties.
In 2010, Geim and Novoselov were awarded the Nobel Prize for Physics. Their discovery meant physicists could study a new class of two-dimensional materials with unique properties.
Graphene is a single layer of carbon atoms arranged like honeycomb.
It was discovered in 2004, when Russian-born Manchester scientists Andrei Geim and Kostya Novoselov were "playing about" with sticky tape and graphite - the material used as "lead" in pencils.
Placing the tape on the graphite and peeling it, they managed to rip off thin flakes of carbon. In the beginning they got flakes consisting of many layers of graphene. But as they repeated the process many times, the flakes got thinner.
By separating the graphite fragments repeatedly, they managed to create flakes that were just one atom thick. Their experiment had led to graphene being isolated for the very first time.
At the time, many believed it was impossible for such thin crystalline materials to be stable. But examined under a microscope, the material remained stable, and when tested was found to have incredible properties.
It is many times times stronger than steel, yet incredibly lightweight and flexible. It is electrically and thermally conductive but also transparent. The world's first 2D material, it is one million times thinner than the diameter of a single human hair.
But the 'sticky tape' method would not work on an industrial scale. Since then, scientists have been working on manufacturing graphene, to make use of its incredible properties.
In 2010, Geim and Novoselov were awarded the Nobel Prize for Physics. Their discovery meant physicists could study a new class of two-dimensional materials with unique properties.
Graphene is a single layer of carbon atoms arranged like honeycomb.
It was discovered in 2004, when Russian-born Manchester scientists Andrei Geim and Kostya Novoselov were "playing about" with sticky tape and graphite - the material used as "lead" in pencils.
Placing the tape on the graphite and peeling it, they managed to rip off thin flakes of carbon. In the beginning they got flakes consisting of many layers of graphene. But as they repeated the process many times, the flakes got thinner.
By separating the graphite fragments repeatedly, they managed to create flakes that were just one atom thick. Their experiment had led to graphene being isolated for the very first time.
At the time, many believed it was impossible for such thin crystalline materials to be stable. But examined under a microscope, the material remained stable, and when tested was found to have incredible properties.
It is many times times stronger than steel, yet incredibly lightweight and flexible. It is electrically and thermally conductive but also transparent. The world's first 2D material, it is one million times thinner than the diameter of a single human hair.
But the 'sticky tape' method would not work on an industrial scale. Since then, scientists have been working on manufacturing graphene, to make use of its incredible properties.
In 2010, Geim and Novoselov were awarded the Nobel Prize for Physics. Their discovery meant physicists could study a new class of two-dimensional materials with unique properties.
Graphene is a single layer of carbon atoms arranged like honeycomb.
It was discovered in 2004, when Russian-born Manchester scientists Andrei Geim and Kostya Novoselov were "playing about" with sticky tape and graphite - the material used as "lead" in pencils.
Placing the tape on the graphite and peeling it, they managed to rip off thin flakes of carbon. In the beginning they got flakes consisting of many layers of graphene. But as they repeated the process many times, the flakes got thinner.
By separating the graphite fragments repeatedly, they managed to create flakes that were just one atom thick. Their experiment had led to graphene being isolated for the very first time.
At the time, many believed it was impossible for such thin crystalline materials to be stable. But examined under a microscope, the material remained stable, and when tested was found to have incredible properties.
It is many times times stronger than steel, yet incredibly lightweight and flexible. It is electrically and thermally conductive but also transparent. The world's first 2D material, it is one million times thinner than the diameter of a single human hair.
But the 'sticky tape' method would not work on an industrial scale. Since then, scientists have been working on manufacturing graphene, to make use of its incredible properties.
In 2010, Geim and Novoselov were awarded the Nobel Prize for Physics. Their discovery meant physicists could study a new class of two-dimensional materials with unique properties.
Graphene is a single layer of carbon atoms arranged like honeycomb.
It was discovered in 2004, when Russian-born Manchester scientists Andrei Geim and Kostya Novoselov were "playing about" with sticky tape and graphite - the material used as "lead" in pencils.
Placing the tape on the graphite and peeling it, they managed to rip off thin flakes of carbon. In the beginning they got flakes consisting of many layers of graphene. But as they repeated the process many times, the flakes got thinner.
By separating the graphite fragments repeatedly, they managed to create flakes that were just one atom thick. Their experiment had led to graphene being isolated for the very first time.
At the time, many believed it was impossible for such thin crystalline materials to be stable. But examined under a microscope, the material remained stable, and when tested was found to have incredible properties.
It is many times times stronger than steel, yet incredibly lightweight and flexible. It is electrically and thermally conductive but also transparent. The world's first 2D material, it is one million times thinner than the diameter of a single human hair.
But the 'sticky tape' method would not work on an industrial scale. Since then, scientists have been working on manufacturing graphene, to make use of its incredible properties.
In 2010, Geim and Novoselov were awarded the Nobel Prize for Physics. Their discovery meant physicists could study a new class of two-dimensional materials with unique properties.
Graphene is a single layer of carbon atoms arranged like honeycomb.
It was discovered in 2004, when Russian-born Manchester scientists Andrei Geim and Kostya Novoselov were "playing about" with sticky tape and graphite - the material used as "lead" in pencils.
Placing the tape on the graphite and peeling it, they managed to rip off thin flakes of carbon. In the beginning they got flakes consisting of many layers of graphene. But as they repeated the process many times, the flakes got thinner.
By separating the graphite fragments repeatedly, they managed to create flakes that were just one atom thick. Their experiment had led to graphene being isolated for the very first time.
At the time, many believed it was impossible for such thin crystalline materials to be stable. But examined under a microscope, the material remained stable, and when tested was found to have incredible properties.
It is many times times stronger than steel, yet incredibly lightweight and flexible. It is electrically and thermally conductive but also transparent. The world's first 2D material, it is one million times thinner than the diameter of a single human hair.
But the 'sticky tape' method would not work on an industrial scale. Since then, scientists have been working on manufacturing graphene, to make use of its incredible properties.
In 2010, Geim and Novoselov were awarded the Nobel Prize for Physics. Their discovery meant physicists could study a new class of two-dimensional materials with unique properties.
Graphene is a single layer of carbon atoms arranged like honeycomb.
It was discovered in 2004, when Russian-born Manchester scientists Andrei Geim and Kostya Novoselov were "playing about" with sticky tape and graphite - the material used as "lead" in pencils.
Placing the tape on the graphite and peeling it, they managed to rip off thin flakes of carbon. In the beginning they got flakes consisting of many layers of graphene. But as they repeated the process many times, the flakes got thinner.
By separating the graphite fragments repeatedly, they managed to create flakes that were just one atom thick. Their experiment had led to graphene being isolated for the very first time.
At the time, many believed it was impossible for such thin crystalline materials to be stable. But examined under a microscope, the material remained stable, and when tested was found to have incredible properties.
It is many times times stronger than steel, yet incredibly lightweight and flexible. It is electrically and thermally conductive but also transparent. The world's first 2D material, it is one million times thinner than the diameter of a single human hair.
But the 'sticky tape' method would not work on an industrial scale. Since then, scientists have been working on manufacturing graphene, to make use of its incredible properties.
In 2010, Geim and Novoselov were awarded the Nobel Prize for Physics. Their discovery meant physicists could study a new class of two-dimensional materials with unique properties.
Graphene is a single layer of carbon atoms arranged like honeycomb.
It was discovered in 2004, when Russian-born Manchester scientists Andrei Geim and Kostya Novoselov were "playing about" with sticky tape and graphite - the material used as "lead" in pencils.
Placing the tape on the graphite and peeling it, they managed to rip off thin flakes of carbon. In the beginning they got flakes consisting of many layers of graphene. But as they repeated the process many times, the flakes got thinner.
By separating the graphite fragments repeatedly, they managed to create flakes that were just one atom thick. Their experiment had led to graphene being isolated for the very first time.
At the time, many believed it was impossible for such thin crystalline materials to be stable. But examined under a microscope, the material remained stable, and when tested was found to have incredible properties.
It is many times times stronger than steel, yet incredibly lightweight and flexible. It is electrically and thermally conductive but also transparent. The world's first 2D material, it is one million times thinner than the diameter of a single human hair.
But the 'sticky tape' method would not work on an industrial scale. Since then, scientists have been working on manufacturing graphene, to make use of its incredible properties.
In 2010, Geim and Novoselov were awarded the Nobel Prize for Physics. Their discovery meant physicists could study a new class of two-dimensional materials with unique properties.
Graphene is a single layer of carbon atoms arranged like honeycomb.
It was discovered in 2004, when Russian-born Manchester scientists Andrei Geim and Kostya Novoselov were "playing about" with sticky tape and graphite - the material used as "lead" in pencils.
Placing the tape on the graphite and peeling it, they managed to rip off thin flakes of carbon. In the beginning they got flakes consisting of many layers of graphene. But as they repeated the process many times, the flakes got thinner.
By separating the graphite fragments repeatedly, they managed to create flakes that were just one atom thick. Their experiment had led to graphene being isolated for the very first time.
At the time, many believed it was impossible for such thin crystalline materials to be stable. But examined under a microscope, the material remained stable, and when tested was found to have incredible properties.
It is many times times stronger than steel, yet incredibly lightweight and flexible. It is electrically and thermally conductive but also transparent. The world's first 2D material, it is one million times thinner than the diameter of a single human hair.
But the 'sticky tape' method would not work on an industrial scale. Since then, scientists have been working on manufacturing graphene, to make use of its incredible properties.
In 2010, Geim and Novoselov were awarded the Nobel Prize for Physics. Their discovery meant physicists could study a new class of two-dimensional materials with unique properties.